EX-96.2 10 ea186711ex96-2_pyrophyte.htm TECHNICAL REPORT SUMMARY FOR DEN PROPERTY

Exhibit 96.2

 

     
     
  TECHNICAL REPORT SUMMARY  
  DEN PROPERTY  
  MANITOBA, CANADA  
     
     
  Submitted to:  
  Sio Silica Corporation  
     
     
  Report Date: Effective Date:
  October 8, 2023 October 6, 2023
     
     
  Stantec Consulting Ltd.  
  200, 325 – 25 Street SE  
  Calgary, Alberta T2P 7H8  
  Tel: (403) 716-8000  
     
     
  Author(s):  
  Ivan Minev, P. Geol.  
  Keith Wilson, P. Eng.  
  Derek Loveday, P. Geol.  
     
     
  Project No. 129500488  

 

 

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Important Notice

 

This notice is an integral component of the Sio Silica Corporation DEN Property Technical Report Summary (“Technical Report Summary” or “Report”) and should be read in its entirety and must accompany every copy made of the Technical Report Summary. The Technical Report Summary has been prepared in accordance with the requirements of the U.S. Securities and Exchange Commission (SEC) S-K 1300 Regulations.

 

The Technical Report Summary has been prepared for Sio Silica Corporation (Sio Silica) by Stantec Consulting Ltd. (Stantec). The Technical Report Summary is based on information and data supplied to Stantec by Sio Silica. The quality of information, conclusions, and estimates contained herein are consistent with the level of effort involved in the services of Stantec, based on: i) information available at the time of preparation of the Report, and ii) the assumptions, conditions, and qualifications set forth in this Report.

 

Each portion of the Technical Report Summary is intended for use by Sio Silica subject to the terms and conditions of its contract (December 5, 2022) with Stantec. Except for the purposes legislated under United States securities law, any other uses of the Technical Report Summary, by any third party, is at that party’s sole risk.

 

The results of the Technical Report Summary represent forward-looking information. The forward-looking information includes pricing assumptions, sales forecasts, projected capital and operating costs, mine life and production rates, and other assumptions. Readers are cautioned that actual results may vary from those presented. The factors and assumptions used to develop the forward-looking information, and the risks that could cause the actual results to differ materially are presented in the body of this Report.

 

Stantec has used their experience and industry expertise to produce the estimates in the Technical Report Summary. Where Stantec has made these estimates, they are subject to qualifications and assumptions, and it should also be noted that all estimates contained in the Technical Report Summary may be prone to fluctuations with time and changing industry circumstances

 

This report was prepared by Stantec Consulting Ltd. (Stantec), a third-party firm comprising mining experts in accordance with § 229.1302(b)(1). Sio Silica has determined that Stantec meets the qualifications specified under the definition of qualified person in § 229.1300. References to the Qualified Person or QP in this report are references to Stantec and not to any individual employed at Stantec.

 

 

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Table of Contents

 

1 EXECUTIVE SUMMARY 1-1
2 INTRODUCTION 2-1
3 PROPERTY DESCRIPTION 3-1
  3.1 Description and Location 3-1
  3.2 Mining Claims 3-1
  3.3 Underlying Agreements, Royalties and Encumbrances 3-11
  3.4 Environmental Liabilities 3-13
  3.5 Required Permits 3-13
  3.6 Other Significant Factors and Risks 3-13
4 ACCESSIBILITY, CLIMATE, LOCAL RESOURCES, INFRASTRUCTURE AND PHYSIOGRAPHY 4-1
  4.1 Topography, Elevation and Vegetation 4-1
  4.2 Property Access and Proximity to Population Centers 4-1
  4.3 Climate 4-1
  4.4 Infrastructure 4-2
5 HISTORY 5-1
  5.1 1967 Norlica Minerals Company Ltd. Feasibility Study 5-1
  5.2 2004 to 2007 North Star Diamonds 5-4
  5.3 Historical Technical Reports 5-4
6 GEOLOGIC SETTING, MINERALIZATION AND DEPOSIT 6-1
  6.1 Regional Stratigraphy 6-1
  6.2 Structural Geology 6-2
  6.3 Property Geology 6-2
    6.3.1 Quaternary Sediments 6-13
    6.3.2 Red River Formation 6-13
    6.3.3 Winnipeg Formation 6-14
    6.3.4 Granitoid 6-14
  6.4 Deposit Types 6-14
  6.5 Mineralization 6-15
7 EXPLORATION 7-1
  7.1 Groundwater Information Network and Friesen Drilling Historical Data 7-1
  7.2 Sio Silica 2018 Drilling Campaign Summary 7-1
  7.3 Sio Silica 2021 - 2022 Drill Campaign summary 7-4
8 SAMPLE PREPARATION, ANALYSES AND SECURITY 8-1
  8.1 Sampling Method and approach 8-1
  8.2 2018 Field Programs Sample Integrity 8-1
  8.3 Laboratory Credentials, Testing Methodology, and Results 8-2
    8.3.1 AGAT Credentials and Testing Methodology 8-2
    8.3.2 Sio Silica Internal Facility Credentials and Processing Methodology 8-2
    8.3.3 Liquids Matter Whole Rock Analysis 8-4

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

9 DATA VERIFICATION 9-1
  9.1 Site Visit and alignment on Field Procedures and Sampling Protocol 9-1
  9.2 Sample Chain-of-Custody and Laboratory Results 9-1
    9.2.1 Chain-of-Custody 9-1
    9.2.2 Laboratory Results 9-2
10 MINERAL PROCESSING AND METALLURGICAL TESTING 10-1
11 MINERAL RESOURCE ESTIMATES 11-1
  11.1 Computer Model Construction 11-1
    11.1.1 Topographic and Lithological Horizons 11-1
    11.1.2 Assay Data Compositing and Interpolation 11-2
  11.2 Resource Estimation Approach 11-2
  11.3 Mineral Resource Classification 11-5
  11.4 Geotechnical Analysis 11-5
  11.5 Assessment of Reasonable Prospect for Eventual Economic Extraction 11-6
  11.6 Estimation of Sand Volume 11-9
  11.7 Mineral Resource Estimation 11-9
12 MINERAL RESERVE ESTIMATES 12-1
  12.1 Development Plan 12-1
13 MINING METHODS 13-1
  13.1 Overview 13-1
  13.2 Geotechnical Analysis 13-1
  13.3 Extraction Concept 13-3
  13.4 Surface Development and Reclamation 13-3
  13.5 Slurry Transportation 13-4
14 PROCESS AND RECOVERY METHODS 14-1
  14.1 Well pad screening circuit 14-1
  14.2 Wet Plant 14-2
  14.3 Dry Screening plant 14-10
  14.4 Storage and loadout 14-10
  14.5 Plant Design and Construction 14-10
  14.6 Rail design and construction 14-10
15 INFRASTRUCTURE 15-1
  15.1 Rail 15-1
  15.2 Power 15-1
  15.3 Access 15-1
  15.4 Gas Line 15-1
  15.5 Maintenance facility 15-1
  15.6 Offices 15-2
  15.7 Operations trailer 15-2
  15.8 Process water Well 15-2

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

16 MARKET STUDIES 16-1
  16.1 Introduction 16-1
  16.2 MARKETS/ DEMAND 16-1
  16.3 COMPETITION 16-1
  16.4 CONTRACTS and POTENTIAL OFFTAKERS 16-2
17 ENVIRONMENTAL STUDIES, PERMITTING AND PLANS, NEGOTIATIONS OR AGREEMENTS WITH LOCAL INDIVIDUALS OR GROUPS 17-1
18 CAPITAL AND OPERATING COSTS 18-2
  18.1 Cost Summary 18-2
  18.2 Project Capital Costs 18-2
    18.2.1 Capital Cost Summary 18-2
    18.2.2 Contingency 18-3
    18.2.3 Sustaining Costs 18-3
  18.3 Project Operating Costs 18-3
    18.3.1 Land Leasing 18-4
    18.3.2 Land Preparation and Reclamation 18-4
    18.3.3 Well Production 18-4
    18.3.4 Wet process, Dry Process, and Loadout 18-4
    18.3.5 Support Equipment 18-5
    18.3.6 Rail & Port 18-5
    18.3.7 Manpower 18-5
    18.3.8 General and Administrative Costs 18-6
    18.3.9 Operating cost Summary 18-6
19 ECONOMIC ANALYSIS 19-1
  19.1 Assumptions 19-1
  19.2 DEN Property Life 19-2
  19.3 Project Payback 19-2
  19.4 Royalties and Income Tax 19-2
  19.5 Economic Performance 19-3
  19.6 Sensitivity Analysis 19-6
20 ADJACENT PROPERTIES 20-1
21 OTHER RELEVANT DATA AND INFORMATION 21-1
22 INTERPRETATION AND CONCLUSIONS 22-1
  22.1 Product Pricing And Cost Escalation 22-1
  22.2 Timing Of Project Development 22-1
  22.3 Development Of Extraction Process 22-1
  22.4 Confirmation Of Geotechnical Testing And Analysis 22-1
23 RECOMMENDATIONS 23-1
  23.1 Phase 1: Geotechnical Testing and Analysis 23-1
24 REFERENCES 24-1
25 RELIANCE ON INFORMATION PROVIDED BY THE REGISTRANT 25-1

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

LIST OF TABLES

 

Table 1.1 Summary of Analyses Completed by Year and Laboratory 1-5
Table 1.2 Summary of In-Place Carman Sand as of February, 2023 1-9
Table 1.3 Sand Extraction Recommendations 1-11
Table 1.4 In-Place Mineral Resource Summary 1-12
Table 1.5 Capital Cost Summary – (C$), no Contingency 1-15
Table 1.6 Life of mine Operating Cost Summary, C$ 1-16
Table 1.7 Project Economics (C$) 1-17
Table 1.8 Key Project Metrics 1-18
Table 1.9 Cash Flow Summary 1-19
Table 1.10 Cost Estimate – Geotechnical Analysis 1-3
Table 1.11 Engineering Bridging Studies 1-3
Table 3.1 Active DEN Property Claims 3-4
Table 4.1 Mean Climate Data for Nearby Weather Stations 4-2
Table 5.1 Norlica Minerals Company Ltd. Drilling Summary 5-1
Table 5.2 Norlica Laboratory Results of Chemical Quantitative Analyses 5-2
Table 5.3 North Star Diamonds Cancelled Mining Claims 5-4
Table 5.4 Historic In-Place Mineral Resource Summary, as of May 8, 2019 5-5
Table 6.1 Property Lithology 6-13
Table 7.1 2018 Drilling Campaign Summary 7-3
Table 7.2 2021 - 2022 Drilling Campaign Summary 7-4
Table 8.1 Summary of Analyses Completed by Year and Laboratory 8-2
Table 8.2 Samples PSD Tested at Sio Silica Facilities 8-3
Table 8.3 Samples Processed at Sio Silica Facilities 8-4
Table 8.4 Liquids Matter ICP-OES Summary Test Results 8-6
Table 8.5 Liquids Matter ICP-OES Point A 40/70 Test Results 8-7
Table 8.6 Liquids Matter ICP-OES Point B 40/70 Test Results 8-8
Table 8.7 Liquids Matter ICP-OES Point A-1 70/140 Test Results 8-9
Table 8.8 Liquids Matter ICP-OES Point B-1 70/140 Test Results 8-10
Table 9.1 2018 AGAT Sample Chain-of-Custody 9-2
Table 11.1 Summary of In-Place Carman Sand 11-9
Table 11.2 Sand Extraction Recommendations 11-10
Table 11.3 In-Place Mineral Resource Summary 11-11
Table 14.1 Key Process Equipment – Well Pad and Dewatering Plant 14-2
Table 14.2 Key Process Equipment – Wet Plant 14-3
Table 14.3 Key Process Equipment – Dry Plant 14-10
Table 18.1 Capital Cost Summary – (C$), no Contingency 18-3
Table 18.2 Manpower Roster and Costs 18-6
Table 18.3 Life of mine Operating Cost Summary, C$ 18-7
Table 19.1 Project Economics (C$) 19-3
Table 19.2 Key Project Metrics 19-4
Table 19.3 Cash Flow Summary 19-5
Table 19.4 After Tax NPV Sensitivity to Sale Price 19-7
Table 23.1 Cost Estimate – Geotechnical Analysis 23-1
Table 23.2 Engineering Bridging Studies 23-2

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

LIST OF FIGURES

 

Figure 1-1 Property Location Map 1-2
Figure 1-2 Mining Claims Map 1-3
Figure 1-3 Resource Distribution Map 1-7
Figure 1-4 Resource Classification Map 1-8
Figure 3-1 Property Location Map 3-2
Figure 3-2 Mining Claims Map 3-3
Figure 4-1 Infrastructure Map 4-3
Figure 6-1 Regional Geology Map 6-3
Figure 6-2 Carbonate Thickness Map 6-4
Figure 6-3 Sand Thickness Map 6-5
Figure 6-4 Overburden Thickness Map 6-6
Figure 6-5 Structure Map Top of Carbonate 6-7
Figure 6-6 Structure Map Top of Carman Sand 6-8
Figure 6-7 Cross Section A-A’ 6-9
Figure 6-8 Cross Section B-B’ 6-10
Figure 6-9 Cross Section C-C’ 6-11
Figure 6-10 Cross Section D-D’ 6-12
Figure 7-1 Drill Hole Location Map 7-3
Figure 8-1 SiO2 Content for 40/70 Fraction Distribution Map 8-5
Figure 8-2 SiO2 Content for 70/140 Fraction Distribution Map 8-6
Figure 8-3 Iron Content for 40/70 Fraction Distribution Map 8-7
Figure 8-4 Iron Content for 70/140 Fraction Distribution Map 8-8
Figure 9-1 2017 Duplicate Sample Comparison Loring vs. Stim-Lab 9-13
Figure 9-2 2018-2019 Duplicate Sample Comparison AGAT vs. Loring Lab 9-14
Figure 9-3 Sample Comparison Sio Silica vs. AGAT 9-15
Figure 11-1 40/70 Fraction Distribution Map 11-3
Figure 11-2 70/140 Fraction Distribution Map 11-4
Figure 11-3 Resource Distribution Map 11-7
Figure 11-4 Resource Classification Map 11-8
Figure 13-1 24 Year Extraction Plan 13-5
Figure 14-1 Wellpad Extraction Flowsheet 14-4
Figure 14-2 Extraction Dewatering Flowsheet 14-5
Figure 14-3 Overland Transport Dewatering Flowsheet 14-6
Figure 14-4 Wet Plant 14-7
Figure 14-5 Dry Plant 14-8
Figure 14-6 Product Handling 14-9

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

SIGNATURE PAGE

 

This report titled “Technical Report Summary, Den Property, Manitoba, Canada” with an effective date of October 6, 2023 was prepared by:

 

Stantec Consulting Ltd. (signed) Stantec Consulting Ltd.
Dated at Calgary, Alberta  
October 8, 2023  

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

1EXECUTIVE SUMMARY

 

Introduction

 

On Dec 5, 2022, Sio Silica Corporation (Sio Silica) contracted Stantec Consulting Ltd. (Stantec) to prepare a Technical Report Summary regarding the Initial Assessment (IA) of the DEN Property. The Technical Report Summary was prepared in accordance with the requirements of the U.S. Securities and Exchange Commission (SEC) reporting of material mining assets under regulation S-K 1300.

 

This Technical Report Summary focuses on the quantification of the resource as a source of high purity silica sand. High purity silica sand may be used in a wide range of industrial applications, including electronics, medical research, metals and alloys, specialty glass, and renewable energy.

 

Description and Location

 

The centre of the Property is located approximately 60 km southeast of the city of Winnipeg, Manitoba within the Rural Municipalities of Ste. Anne, Hanover and La Broquerie. The Property is accessed from Winnipeg by the Trans-Canada Highway, and PR 210 for the northern section of the Property, and Provincial Highway 12 for the southern section of the Property. The general property location is shown on Figure 1.1.

 

The Property encompasses 63,750 hectares (157,530 acres) and is shown on NTS Map Sheet 62. The main block of the Property expands from 654,900E to 693,250E, and 5,459,450N to 5,502,750N, and the centre of the Property is at 49.451287°N and -96.513671°E (UTM 14 U 680,199E and 5,480,597N), as shown on Figure 1-2.

 

Mineral Claims

 

The Property, which consists of 278 claims, are all in surveyed territory. The Property is held by CanWhite, which is now Sio Silica. The locations of the claims are shown on Figure 1.2.

 

Infrastructure

 

Winnipeg is the largest major city near the Property. Winnipeg, as of 2021, has a population of 749,607 residents in the metropolitan area (Statistics Canada, 2023), and provides all required major services to advance the project. The city of Winnipeg, located on the TransCanada Highway, is the home of the James Armstrong Richardson International Airport that has numerous domestic and international flights, and is a major North American rail transportation hub with a 20,000-acre facility that services Canadian National Railway, Canadian Pacific Railway, BNSF Railway and the locally maintained and operated Greater Winnipeg Water District Railway (Railway Association of Canada, 2017; Winnipeg, 2017).

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

History

 

Prior to Sio Silica securing the current DEN Property, the area to the north was staked and drilled to assess the viability of the sand for use as a natural proppant. Norlica Minerals Company Ltd. (Norlica) conducted an exploration program and feasibility study in 1967. North Star Diamonds had previously staked an area on the western edge of the current Property.

 

In 2019 Stantec completed a Technical Report prepared in accordance with the requirements of National Instrument 43-101 Standards of Disclosure for Mineral Projects (NI 43-101) for the DEN Property. In 2023, Stantec completed a Technical Report Summary prepared in accordance with the requirements of U.S. Securities and Exchange Commission (SEC) reporting of material mining assets under regulation S-K 1300.

 

Property Geology

 

Prior to 2017, most of the drilling in the area was limited to water wells that were drilled on behalf of third parties. The units described below are primarily based on reliable holes that were drilled in the Project area by Sio Silica. In general, the stratigraphy of the Property is consistent; the major units are Quaternary sediments, carbonate and shale intervals of the Red River Formation, unconsolidated sand, sandstone, and shale of the Winnipeg Formation, and Archean-age granitoid basement. The upper unconsolidated sand interval of the Winnipeg Formation, which is known as the Carman Sand Member, is the target interval to be exploited. The average Carman Sand Member depth within the property limit is 54 m and the average thickness is 26 m.

 

Mineralization

 

The stratigraphic target is the unconsolidated silica sand from the Carman Sand Member. The high purity of the sand makes it suitable for variety of usages and markets. The primary objective of the program was to delineate the quality of the sand and assess the extractable sand volumes.

 

Deposit Types

 

The Carman Sand Member is dominantly an unconsolidated laterally extensive unit across the Property, as validated through numerous drilling campaigns conducted by Sio Silica. Unconsolidated sand type deposits typically require no processing beyond cleaning and size sorting. The deposit appears to have limited geological variability and limited structural complexity.

 

Sio Silica Drilling Campaigns

 

A drilling campaign was initiated in September 2018. During this campaign, 15 holes were drilled on the DEN Property. Of the 15 holes drilled, 14 were Dual Rotary (DR) / Reverse Circulation (RC) holes that were drilled to identify formation tops and to constrain sand samples, and one was a diamond drill hole (DEN 216-1) to evaluate the geotechnical properties of the carbonate interval.

 

Twenty drill holes were completed between 2021 and 2022. The majority were drilled as exploration holes. Three drill holes (Den-117-1, Den-120-1 and Den-204-1) were cored but none intersected the bottom of the Carman Sand Member. Two of the drill holes (Den-120-1 and Den-169-1) were drilled close to the edge of the Carman Sand Member and the sand was not intersected. Eight of the twenty wells were able to intersect the bottom of the Carman Sand Member.

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Sample Preparation, Analyses and Security

 

Table 1.1 shows a summary of the number and type of analyses by year and laboratory. AGAT, Liquids Matter and Loring are independent laboratories.

 

Table 1.1

Summary of Analyses Completed by Year and Laboratory

 

Laboratory   Year   No. Samples   Analyses Type
AGAT   2018   198   Sieve Analysis
Loring   2018   5   Sieve Analysis

Sio Silica

  2018*   8   Sieve Analysis
  2021-2022   33   40/70 and 70/140 size fraction clean and magnetic separator

Liquids Matter

 

2021-2022

 

80

  ICP Whole Rock on 40/70 and 70/140 size fraction

 

The Liquids Matter ICP-OES test results show that the magnetic separator used by Sio Silica was successful in increasing sand purity from a mean of 99.89% SiO2 to 99.92% SiO2 for the 40/70 size fraction, and 99.84% SiO2 to 99.92% SiO2 for the 70/140 size fraction.

 

Data Verification

 

A Stantec professional geologist assisted with and oversaw the portion of the program involving collection of the field data, sample collection, and the implementation of chain-of-custody documentation during sample shipment. The Stantec professional geologist conducted a site visit to the Property on September 25 and 26, 2018 to align with the Sio Silica field crew on program procedures, as well as to instruct the drilling crew on the required rate of drilling to facilitate sample collection.

 

On June 10, 2022, the QP visited the Sio Silica’s laboratory in Calgary, Alberta, and the Liquids Matter facility in Calgary, Alberta. It is the QP’s opinion that both the Sio Silica and Liquids Matter laboratories have laboratory equipment, procedures, processes and personnel that are adequate for the performed analytical work. Provided analytical data were compared against the laboratory reports. The results from the different laboratories are compared to ensure consistency and accuracy of the analytical data.

 

On January 25, 2023, the QP conducted a site visit on the Property. All the drill hole sites were rehabilitated. The drill hole location of one monitoring well was validated. The sample storage facility was also visited.

 

Mineral Resource Estimates

 

Estimated resources are classified according to the confidence level that can be placed in each estimate. The classification template used in this study is based on the three-dimensional distance to the nearest drill hole that penetrates the top and the bottom of the Carman Sand, as well as the distance to the nearest sample that contains sand quality analytical data. The Carman Sand interval in the Property was classed as Indicated using a 1,600 m radial distance from the nearest drill hole intersection with available sand quality data and classed as Inferred using a 3,200 m radial distance from the nearest drill hole intersection with or without available sand quality data. Only drill holes listed in Section 7.2 and Section 7.3 were used for resource classification. Due to the reduced reliability of the water-wells described in Section 7.1, this data was only used to define the contacts of the lithological units. Figure 1.3 shows the resource distribution map and Figure 1.4 shows the resource classification map. The resource estimate covers an area of approximately 29,600 ha.

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Estimation of Sand Volume

 

The modeled volumes and weight of the Carman Sand within the resource area are shown in Table 1.2.

 

Table 1.2

Summary of In-Place Carman Sand as of February, 2023

 

   In-Place Carman Sand Member in
Mineable Lease Area
 
DEN Property  40/70 mesh
fraction
   70/140 mesh
fraction
 
Estimated Sand Volume (Mm3)   4,910    2,532 
Total Estimated Sand Volume (Mm3)   7,442 
Estimated Sand Weight (Mt)   7,365    3,798 
Total Estimated Sand Weight (Mt)   11,163 

  

Mineral Resource Estimates

 

The Mineral Resource estimate for the Project has been prepared in accordance with the SEC S- K 1300 regulations. The QP believes the DEN Property demonstrates a reasonable prospect for eventual economic extraction.

 

Preliminary geotechnical analysis for the DEN property has resulted in the extraction recommendations as summarized in Table 1.3. The extraction holes are planned to be drilled in a pod or cluster of up to thirteen holes in one extraction pad area. The current planning basis is to extract between 1 K and 33 K tonnes of sand from an extraction cluster, depending on the thickness of the overlying limestone and diamicton material, before relocating to the next extraction pad.

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 1.3

Sand Extraction Recommendations

 

Competent
Limestone
Thickness (m)
  Quaternary
Material Thickness (m)
  Extractable Sand
Volume (m3)
    Extractable Sand
Mass (t)
    Distance Between
Well Clusters (m)
(Center to Center)
 
>50   0-65     36,156       54,235       127  
>50   >65     34,674       52,012       126  
45-50   0-55     33,224       49,836       125  
45-50   55-65     29,061       43,591       122  
45-50   >65     27,736       41,603       121  
40-45   0-45     29,061       43,591       122  
40-45   45-55     26,442       39,663       120  
40-45   55-65     23,949       35,924       118  
40-45   >65     21,582       32,373       116  
35-40   0-45     22,750       34,125       117  
35-40   45-55     20,446       30,669       115  
35-40   55-65     17,225       25,837       112  
35-40   >65     16,214       24,321       111  
30-35   0-45     15,235       22,852       110  
30-35   45-55     13,370       20,056       108  
30-35   55-65     11,632       17,447       106  
30-35   >65     10,809       16,214       105  
25-30   0-25     15,235       22,852       110  
25-30   25-35     12,485       18,728       107  
25-30   35-45     10,018       15,028       104  
25-30   45-55     8,531       12,796       102  
25-30   55-65     7,169       10,754       100  
25-30   >65     6,535       9,803       99  
20-25   0-25     9,259       13,888       103  
20-25   25-35     7,169       10,754       100  
20-25   35-45     5,362       8,043       97  
20-25   45-55     4,822       7,234       96  
20-25   55-65     3,838       5,757       94  
20-25   >65     3,392       5,089       93  
15-20   0-25     4,314       6,472       95  
15-20   25-35     2,979       4,468       92  
15-20   35-45     2,245       3,368       90  
15-20   45-55     1,925       2,888       89  
15-20   55-65     1,379       2,069       87  
15-20   >65     1,379       2,069       87  

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

The mineral resource shown in Table 1.4 is reported as in-place tonnages. The calculated volumes were converted to tonnage by the application of representative average in-place bulk density value of 1.5 g/cm3.

 

Table 1.4

In-Place Mineral Resource Summary

 

 

Mineral Resources

(Mt)

 
DEN Property  40/70 mesh
fraction
   70/140 mesh
fraction
   Total 
Measured   0.0    0.0    0.0 
Indicated   55.8    32.6    88.4 
Total Measured and Indicated            88.4 
                
Inferred   169.8    82.9    252.7 
Total Inferred            252.7 

  

It should be noted that the drill hole information shows very consistent Carman Sand thickness, averaging 26 m. The laboratory results show low variability on the sand quality. The SiO2 content ranges between 99.51% to 99.96%, averaging 99.89% after washing and drying. The average SiO2 content after magnetic separation is 99.92%. Analogical results are observed on the Fe analysis. The Fe content ranges between 34.53 ppm and 397.0 ppm with 143.6 ppm average after washing and drying. The average Fe content after magnetic separation is 86.1 ppm, ranging between 27.1 ppm and 266.7 ppm.

 

The accuracy of resource estimates is, in part, a function of the quality and quantity of available data and of engineering and geological interpretation and judgment. Given the data available at the time that this Technical Report Summary was prepared, the estimates presented herein are considered reasonable. However, this estimate should be accepted with the understanding that additional data and analysis available after the date of the estimates, may necessitate revision. These revisions may be material. There is no guarantee that all or any part of the estimated resources will be recoverable.

 

Mineral Reserve Estimation

 

This Technical Report does not include an estimate of reserves. The level of engineering does not support the preparation of a Pre-Feasibility Study; therefore, in accordance with the requirements of S-K 1300, the reported resources cannot be classified as reserves.

 

This section of the report includes estimates of recoverable sand tonnage for the DEN Property based on preliminary extraction plans, production schedules and processing plant and materials handling plans. These estimates are only intended for the purpose of completion of the cash flow forecasts presented in Section 19. These recoverable estimates are not, and should not be construed to be, estimates of reserves for the DEN Property. They do not comply with the Classification of Reserves as required under S-K 1300. It should be noted that there is no certainty that the resource estimate will be realized.

 

  1-10

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Development Plan

 

The 25-year development plan, that is discussed in more detail in Section 13, results in the sale of 2.72 Mt of clean (saleable) sand each year, totaling 65.4 Mt over the life of the project. Stantec notes that the 25-year development plan only addresses a portion of the DEN Property resource. The remaining resource is available for development in further planning efforts.

 

This estimate of clean (saleable) silica sand is considered to be inclusive of the in-place mineral resource estimate detailed in Section 11. These production estimates are contained within the in- place mineral resource summary and cannot be added to the totals to result in additional resources tonnes.

 

The DEN Property will be developed using an underground extraction technique that involves drilling through the quaternary sediments, carbonate unit and shale, into the underlying sand. The extraction holes will be cased to the top of the sand and an extraction casing is then lowered into the sand. Air is injected into the extraction casing, approximately 3 m - 5 m above the bottom of the casing. Field tests conducted at the neighboring BRU property have shown that the air injection process results in a slurry of sand, water, and air that rises to the surface. The solids content of the slurry ranges from 90% to 20% during the extraction trials. The average solids content is approximately 50%.

 

Sio Silica plans to commence extraction operations in the 2nd Quarter of Year 0, processing operations in the 3rd Quarter of Year 0 with the first product sales planned for the 1st Quarter of Year 1. The extraction and processing operations are planned to take place for eight months a year, April to November, while sales will take place year-round. The sales will commence with 2.72 Mt of saleable product planned in Year 1 and extending out the remainder of the 25-year plan. For the purposes of this Technical Report Summary, Year 0 is defined as 2026.

 

Geotechnical Analysis

 

Stantec completed a preliminary geotechnical analysis of the sand extraction techniques impact on subsurface conditions. The results of the analysis are used to provide recommendations for borehole spacing which are intended to limit surface subsidence to an acceptable level.

 

The preliminary analysis indicates that:

 

Subsurface sand extraction should be limited to areas where the carbonate unit is more than 15 m in thickness.

 

The analysis here assumes an overburden thickness of up to 25 m. Overburden thicker than this range should be reviewed case by case to assess potential for subsidence to occur following extraction.

 

The distance from the edge of one extraction void to the edge of the next extraction void should not be less than 60 m.

 

  1-11

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

The extraction layout was developed with these geotechnical criteria in mind. The author(s) would like to note that these geotechnical parameters and the resulting geotechnical analysis are based on geotechnical work completed for the Limestone caprock and assuming that the controlling failure mode is shear failure. Additional testing is recommended to support further analysis on the sandstone void space evolution, and the joint system in the limestone (to investigate for the possible presence of vertical jointing and if found, to assess its impact on stability). As stated above, evidence from testing in 2018/2019 suggests that the sandstone angle of repose is steeper than previously assumed, and related adjustments of the extraction plan which would lead to a more refined extraction layout might be required. In addition, more complex void shapes in the sandstone may be occurring with both steep and shallow side slopes.

 

As a result of the minimum 15 m cut off for the thickness of the limestone to support overburden loading after sand extraction, and the additional potential for strength analysis on the sandstone layer, further geotechnical investigation, testing and analysis will be required. The purpose of this additional assessment is to confirm the Limestone thickness in advance of mining operations, to test the (to date untested) presence of Limestone vertical fractures and the sandstone unit extraction void space and to confirm that other failure modes are not controlling the extraction void maximum size.

 

Recovery Methods

 

The processing component of the DEN silica operation is guided by a modular and multi-stage recovery process. The four general areas are:

 

A modular well pad screening and dewatering plant for slurry preparation;

 

A dewatering circuit or ‘wet plant’ for raw sand separation;

 

A dry screening plant for final sizing and beneficiation; and

 

The storage and loadout system.

 

Based on preliminary analyses and modeling, extraction, handling and drying losses are estimated at seven (7) percent.

 

Markets and Contracts

 

Sio Silica is intending on producing high-quality premium silica sand for end use in the technology markets. The 99.99% SiO2 and low iron content (<100ppm Fe) are typically marketed to manufacturers of solar glass, smart glass for computing and mobile device applications, and semiconductors, among other uses, and receive a premium compared to 95% SiO2 purity. A confidential marketing study was completed by a third party, on behalf of Sio Silica, focused on the premium silica market.

 

The global market for silica sand is approximately 350 million tonnes per annum, with approximately three quarters of that total in North America (112 million tonnes) and Asia Pacific (154 million tonnes), as of 2021. Of this global market, the high purity market consists of approximately 13 million tonnes per annum.

 

  1-12

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

The North American market for high purity, low iron silica has been in the 1 million tonne per annum range historically through 2021 and is anticipated to grow to 2 to 3 million tonnes per annum by 2025, principally driven by the photovoltaic market and technology applications.

 

Supply of high purity quartz to the Asian market has traditionally been supplied via Vietnam and Cambodia. Both countries have scaled back exports to China to strengthen their local manufacturing, resulting in a supply shortage in the rest of Asia and therefore higher delivered prices.

 

The anticipated growth in the high purity silica market has provided motivation to other potential sources of supply in Australia, according to the marketing report. It is anticipated that the supply from these to-be-developed proposed mines will require additional beneficiation, adding costs to the mine gate pricing. The timing and tonnage of this new supply and the level of the beneficiation, and associated costs, is uncertain. Australian mining companies are expected to be the primary exporter to China; however, it is unclear how much will materialize, according to the marketing study. In the future scenario, Australian mining companies may potentially have lower delivered costs compared to other international peers for solar glass applications, but will require beneficiation for smart glass applications, resulting in a higher delivered price.

 

There are only two mines in the US today capable of providing low iron silica sand (99.9% SiO2, <100 ppm) totaling approximately 1 million tonnes per annum of supply.

 

According to the marketing study, typical contracts are two-to-three-year renewable contracts indexed to inflation, and identified with a specific purity, quality, and quantity. In a similar fashion, there are typically penalties for not meeting these criteria. Sio Silica has provided Stantec with three documents related to their negotiations with potential customers for the silica sand produced from the DEN Property.

 

Agreement #1

 

The first document is a proposed sales and purchase agreement contract between Sio Silica and Company 1, that Sio Silica has indicated should be finalized in the fourth quarter of 2023. The document states a sales price of US$180 per MT FOB loading port for 500,000 MT per annum. When exchange rates and port and rail costs are considered, it equates to a mine gate price of CDN$149 per MT.

 

The initial term of this proposed agreement is from January 1, 2024 to December 21, 2026. Thereafter term of the agreement will be automatically renewed for an unlimited number of one (1) year terms unless terminated by either the buyer or the seller.

 

Agreement #2

 

The second document is a Memorandum of Understanding between Sio Silica and Company 2 and dated September 15, 2022. The document states a sales price of US$250 per MT FOB loading port for 800,000 MT per annum. When exchange rates and port and rail costs are considered, it equates to a mine gate price of CDN$240 per MT.

 

Both the buyer and the seller agree to use their best efforts to enter into a binding Sales Agreement in the first quarter of 2024.

 

  1-13

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Agreement #3

 

The third document is an engagement agreement between Sio Silica and Company 3 and dated November 1, 2022. The document states a sales price of US$200 per short ton FOB Mine Gate for 1,200,000 short tons per annum. The agreement also stipulates a service fee equal to 15% of the gross amount of the purchase price paid. When conversion to metric tonnes and the 15% fee are considered, it equates to a mine gate price of CDN$243.60 per MT.

 

The term of this agreement is unlimited unless terminated by either the buyer or the seller.

 

Product Pricing

 

Stantec used a weighted tonnage per annum price from all three agreements for the initial years of the analysis. A weighted tonnage per annum price for the last two agreements was used from 2030 until the end of the project life.

 

Product Quality

 

The first two agreements specify that the quality parameters for the delivered sand shall be a silicon dioxide (SiO2) percentage greater than or equal to 99.9% and Fe2O3 content less than or equal to 100 ppm.

 

It is the opinion of Stantec that given the results of the sand analysis discussed in Section 8, the sand pricing discussed above is applicable to the DEN Property resource and as such has been used in this Study.

 

Stantec does note, however, that confirmed sales agreements or contracts for the full levels of silica sand production that form the basis of this Study have yet to be finalized.

 

Environmental Studies, Permitting and Social or Community Impact

 

Sio Silica has engaged AECOM to provide consulting support through the regulatory approval process. The regulatory approval process for the adjoining BRU property has advanced significantly. Although the regulatory process for the DEN Property has not yet commenced, Stantec envisions that it will be materially similar to the BRU process. For further details please refer to the Technical Report Summary BRU Property Manitoba, Canada.

 

Capital and Operating Costs

 

The DEN project capital encompasses equipment beginning at extraction well pad, including well rigs, the overland slurry line initial pump stations, booster pump and through to the wet and dry plant, as well as the silos, rail, and supporting infrastructure. Table 1.5, below, outlines the capital estimate by area. It should be noted that no contingency is applied in the table.

 

  1-14

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Table 1.5

Capital Cost Summary – (C$), no Contingency

 

Area  Summary
Cost, (C$)
 
Extraction  $43.5M
Wet Plant  $73.8M
Dry Plant  $85.4M
Rail and TLO  $36.3M
Overland Slurry Pipeline Controls  $6.2M
Infrastructure  $15.9M
Engineering, Project Management & Permitting  $2.5M
Total  $263.6M

 

A 7% contingency has been applied to most capital cost items to account for any unforeseen or otherwise unanticipated cost elements that could be associated with development and operation of the project. Contingency for the project totals $17.2M. A contingency was not applied to rail costs as these costs were supplied with contingency included.

 

The project team also developed the operating costs using construction lengths, land requirements, operating units, and process or dryer unit preliminary power and gas consumption. Areas of operating costs breakouts include:

 

Land leasing

 

Land prep and reclaim

 

Well Production

 

Slurry Transport

 

Wet Process

 

Support Equipment

 

Dry Process

 

Loadout

 

Rail Costs

 

Manpower

 

General and Administration

 

The total operating cost summary is shown in Table 1.6. In year 1, each extraction site utilizes dedicated supervision leading to higher initial costs. Extraction operation costs are reduced in later years as operations supervision is planned to be centralized. Slurry transport costs are lower in early years due to shorter slurry pumping distances. Dry processing costs are calculated based on the change from trucked propane in Year 1 while the gas line is developed. From Year 2 production onward, operating costs reflect that the installation of a natural gas pipeline and the use of natural gas as opposed to propane.

 

  1-15

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 1.6

Life of mine Operating Cost Summary, C$

 

  

Year 1

C$/tonne

  

Year 2 onward

C$/tonne

 
Extraction  $12.53   $8.62 
Slurry Transport  $1.74   $2.90 
Wet Processing  $5.07   $5.07 
Dry Processing  $11.99   $8.63 
Site Labor  $1.28   $1.28 
Insurance  $0.38   $0.38 
Total OPEX  $32.99   $26.88 

 

Economic Analyses

 

Sio Silica prepared the economic analyses for the DEN operation and provided the model to Stantec. Stantec reviewed the model to assess and determined it to be appropriate for the purposes of the IA. Section 19 outlines the specific inputs and assumptions for the analyses. The results of the Study base case economic analysis are shown in Table 1.7 Project Economics. The economic performance of the project is positive up to the highest analyzed discount rate of 16%.

 

Table 1.7

Project Economics (C$)

 

Discount Rate   After Tax 
(%)   IRR   NPV 
6    99%  $3,849,723,000 
8    99%  $3,132,092,000 
10    99%  $2,588,786,000 
12    99%  $2,169,955,000 
14    99%  $1,841,529,000 
16    99%  $1,579,856,000 

 

Stantec has not completed a rigorous analysis in order to select the project discount rate. However, Stantec notes that current normalized risk-free rate and equity risk premium, composed of 3.5% and 5.7% respectively which shows that the approximate cost of equity capital to be 9.2%. This rate does not account for project risks, industry risk, size and maturity of the operation to name a few. As such the appropriate discount rate for this study is likely in the range of 10-13%. Ultimately investors in the DEN Property will need to conduct their own discount rate analysis.

 

The key project metrics and cash flow summary are summarized in Tables 1.8 and 1.9.

 

  1-16

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Table 1.8

Key Project Metrics

 

Economic Analysis  DEN 
Net Present Value (NPV), After-Tax  $2,588,786,000 
Internal Rate of Return (IRR), After-Tax   99%
Pay-Back Period (Years based on After-Tax)   1.00 
      
Capital Costs     
Initial Capital (M)   280.75 
Expansion Capital (M)   N/A 
      
Operating Costs at Full Production     
Extraction ($/MT )   8.62 
Slurry Transport ($/MT)   2.90 
Wet Processing ($/MT)   5.07 
Dry Processing and Loadout ($/MT)   8.63 
Site Labor and Insurance ($/MT)   1.66 
Total Operating Cost ($/MT)   26.88 
      
Production Data     
Life of Mine (Years)   25 
Annual Clean Saleable Tonnes Produced (MT)   2,724,000 
Total Clean Saleable Tonnes Produced (MT)   65,376,000 

 

  1-17

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 1.9

Cash Flow Summary

 

Period  Year 0   Year 1   Year 2   Year 3   Year 4   Year 5   Year 6   Year 7   Year 8   Year 9   Year 10   Year 11   Year 12 
Raw Sand Production (Tonnes)   -    1,831,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000 
                                                                  
Sales Volumes (Tonnes)   -    -    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000 
                                                                  
Minegate Pricing ($/Tonne)   223.53    223.53    223.53    223.53    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55 
                                                                  
Minegate Revenue (M$)   -    -    609    609    661    661    661    661    661    661    661    661    661 
                                                                  
Royalties (M$)™   -    -    24    10    11    11    11    11    11    11    11    11    11 
Mining Tax (M$)   -    -    86    89    98    98    98    98    98    98    98    98    98 
Net Revenue (M$)   -    -    499    510    553    553    553    553    553    553    553    553    553 
                                                                  
Extraction Operating Costs (M$)   -    28    44    37    37    37    37    37    37    37    37    37    37 
Wet Processing Operating Costs (M$)   -    3    14    14    14    14    14    14    14    14    14    14    14 
Dry Processing and Loadout Operating Costs (M$)   -    -    33    24    24    24    24    24    24    24    24    24    24 
Total Operating Costs (M$)   -    31    91    74    74    74    74    74    74    74    74    74    74 
                                                                  
Manitoba Operations G&A (M$)   -    -    -    -    -    -    -    -    -    -    -    -    - 
Head office G&A (M$)   2    2    2    2    2    2    2    2    2    2    2    2    2 
Total G&A (M$)   2    2    2    2    2    2    2    2    2    2    2    2    2 
                                                                  
Cash Interest Expense (M$)   3    21    21    2    -    -    -    -    -    -    -    -    - 
Cash Income Tax (M$)   (1)   (14)   69    103    118    121    123    124    125    126    127    127    128 
Total Cash-flow (M$)   (4)   (39)   317    330    359    356    354    353    352    351    350    350    349 
Cumulative Cash-Flow (M$)   (4)   (43)   273    604    963    1,319    1,673    2,026    2,377    2,728    3,078    3,427    3,777 
                                                                  
Phase 1 Capital Expenditures (M$)   21    260    -    -    -    -    -    -    -    -    -    -    - 
Expansion Capital Expenditures (M$)   -    -    -    -    -    -    -    -    -    -    -    -    - 
Total Capital Expenditures (M$)   21    260    -    -    -    -    -    -    -    -    -    -    - 

 

  1-18

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Period  Year 13   Year 14   Year 15   Year 16   Year 17   Year 18   Year 19   Year 20   Year 21   Year 22   Year 23   Year 24   Year 25   Total 
Raw Sand Production (Tonnes)   2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    72,127,000 
                                                                       
Sales Volumes (Tonnes)   2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    65,376,000 
                                                                       
Minegate Pricing ($/Tonne)   242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55      
                                                                       
Minegate Revenue (M$)   661    661    661    661    661    661    661    661    661    661    661    661    661    15,753 
                                                                       
Royalties (M$)   11    11    11    11    11    11    11    11    11    11    11    11    11    265 
Mining Tax (M$)   98    98    98    98    98    98    98    98    98    98    98    98    98    2,327 
Net Revenue (M$)   553    552    552    552    552    552    552    552    552    552    552    552    552    13,161 
                                                                       
Extraction Operating Costs (M$)   37    37    37    37    37    37    37    37    37    37    37    37    37    912 
Wet Processing Operating Costs (M$)   14    14    14    14    14    14    14    14    14    14    14    14    14    335 
Dry Processing and Loadout Operating Costs (M$)   24    24    24    24    24    24    24    24    24    24    24    24    24    573 
Total Operating Costs (M$)   74    74    74    74    74    74    74    74    74    74    74    74    74    1,821 
                                                                       
Manitoba Operations G&A (M$)   -    -    -    -    -    -    -    -    -    -    -    -    -    - 
Head office G&A (M$)   2    2    2    2    2    2    2    2    2    2    2    2    2    47 
Total G&A (M$)   2    2    2    2    2    2    2    2    2    2    2    2    2    47 
                                                                       
Cash Interest Expense (M$)   -    -    -    -    -    -    -    -    -    -    -              47 
Cash Income Tax (M$)   128    128    128    128    128    128    128    129    129    129    129    129    129    2,945 
Total Cash-flow (M$)   349    348    348    348    348    348    348    348    348    348    348    348    348    8,302 
Cumulative Cash-Flow (M$)   4,126    4,474    4,822    5,170    5,518    5,866    6,214    6,562    6,910    7,258    7,606    7,953    8,301    - 
                                                                       
Phase 1 Capital Expenditures (M$)   -    -    -    -    -    -    -    -    -    -    -    -    -    281 
Expansion Capital Expenditures (M$)   -    -    -    -    -    -    -    -    -    -    -    -    -    - 
Total Capital Expenditures (M$)   -    -    -    -    -    -    -    -    -    -    -    -    -    281 

 

  1-19

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Interpretation and Conclusions

 

This Study indicates a positive economic outcome related to the potential development of a silica sand extraction and processing operation for the DEN Property. The extraction plan addressed only a portion of the In-Situ Mineral Resource previously classified, as the entire DEN resource was not required for the 25-year development plan.

 

Stantec has identified the following risks that could potentially affect the projected economic viability of the DEN Property development.

 

Product Pricing and Cost Escalation

 

As indicated in Section 19 of this Study, the project economics are sensitive to the assumed pricing for silica sand and estimated project costs. A 30% reduction in product pricing combined with a 30% increase in project costs, after a 7% contingency (initial project capital) has been applied, and results in positive economics.

 

Stantec has reviewed Sio Silica’s cost estimate and believes it captures reasonable Capex and Opex costs for the project as it is currently planned. However, the cost estimate is based on budgetary quotes provided by third party vendors and Sio Silica’s partners and assumes the project advances as per the current schedule.

 

Stantec understands that Sio Silica intends to proceed with the project development in 2026, partially based on the results of this Study. As such, the risks associated with cost escalation are not insignificant.

 

Timing of Project Development

 

Certain process and infrastructure components may be subject to longer lead times. These include rotary dryers, gas pipeline installation, and high voltage substations. The full capacity of the DEN operation and the resultant project economics are dependent on these components.

 

Development of Extraction Process

 

The current extraction process is based on the results from 14 drill holes completed on the BRU Property from 2017 to 2021. Stantec has no reason to believe that the planned extraction process will not be successful. However, Stantec does note the risks to the project should the planned extraction rates be unachievable or unsustainable over the life and geographic extent of the Project.

 

Confirmation of Geotechnical Testing and Analysis

 

As discussed in Section 11.4, Stantec geotechnical engineers completed a preliminary geotechnical analysis related to extraction of the sand resource on the adjacent BRU Property. A similar program has not yet occurred for the DEN Property. Stantec used the BRU results and DEN geological interpretation and completed a high-level preliminary analysis of the DEN conditions and these results were used to inform the current resource estimate.

 

  1-20

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

The conclusions of the previous BRU analysis are summarized below:

 

Based upon current information and assessments, Shear and Bending are the most probable failure modes with the potential to affect long-term stability. Unravelling, Caving, and Chimneying are not controlling failure modes for the BRU property due to the nature of the limestone caprock.

 

The Bending failure mode is controlling the long-term stability of the post extraction cavity for the expected range of caprock and overburden thickness and material properties and the extraction depth in the sand. The stability analysis and extraction borehole spacing design were completed to achieve a factor of safety of 2.0, which is considered to be an acceptably conservative FOS for the project.

 

The cavity after extraction is expected to further expand with time resulting in loose sand infilling the extracted void leaving a larger unsupported caprock span. Based on the assumption that the areas with factor of safety larger than 2 are stable in the long-term, approximately 5 m of additional raveling of the post extraction cavity walls is expected (by end of the design life of 100 years). Therefore, the unsupported caprock span will increase by 10 m with time after extraction.

 

Based upon the results of geotechnical assessment and with the understanding that Sio Silica will follow guidance provided by Stantec including continuing to assess the geotechnical characteristics and performance of the sand deposit and overlying materials during the project life and to adjust design accordingly, no large-scale surface subsidence is expected to occur as a result of sand extraction.

 

There is a potential that further geotechnical assessments may impact the current resource estimate, either positively or negatively. In particular, there remains uncertainty regarding the possible presence of vertical fractures in Limestone caprock, which to date has not been investigated or assessed. The presence of continuous vertical fractures in Limestone caprock above extraction voids has the potential to lead to caprock collapse which may propagate to the surface and produce settlement. In addition, there remains uncertainty regarding the long term performance of the extraction voids which may have complex void shapes and have the potential to propagate over larger than currently estimated distances.

 

Recommendations

 

Phase 1: Geotechnical and Resource Investigation and Analysis

 

Based on Sio Silica’s current development and production plans, all resources identified in the areas where the first 5 years of production will occur should be classified as Measured. Additional drill holes may be required to increase confidence in the resource estimates within these areas.

 

  1-21

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Stantec geotechnical engineers completed a preliminary geotechnical analysis of the impact of extraction of the sand on the BRU Property. The recommendations from this analysis, which also apply to the DEN Property, are summarized below:

 

Design and execute a site investigation and assess the results to confirm expected geotechnical performance. This investigation may include the following components:

 

oData Collection:

 

§Geotechnical borehole drilling, logging, photography, and sampling with vertical and inclined boreholes and SPT or CPT if needed – to characterize extents and properties of sandstone, caprock and overburden.

 

§Acoustic and Optical Televiewer Survey of Geotechnical Boreholes – to characterize caprock structure.

 

§Side Scan Sonar Survey – to monitor sand cavity shape and behavior.

 

§Laboratory testing of selected samples of sandstone, caprock and overburden as required – to characterize properties of sandstone, caprock and overburden.

 

§Installation and monitoring of Vibrating Wire Piezometers, Vertical Extensometers and Surface Monuments and Total Station or GPS Survey – to monitor changes in caprock and surface subsidence.

 

oData Analysis:
   
§Stability and settlement analysis to identify and assess for changes in assumptions related to vertical jointing (if found) in Limestone caprock, extraction void shape or other design assumptions.

 

Develop and implement a Trigger Action Response Plan as follows:

 

§Collected data review - to establish baseline values.

 

§Trigger value range identification - low/moderate/high – green/yellow/red

 

§Monitoring results verification and comparison against trigger values.

 

Review the impact of potential vibration sources, such as rail traffic, to determine potential offsets from extraction areas.

 

Table 1.10 shows the anticipated cost to complete the geotechnical analysis.

 

Table 1.10

Cost Estimate – Geotechnical Analysis

 

Task  Estimated Cost (C$) 
Geotechnical Analysis   500,000 

 

Phase 2: Engineering Bridging Studies

 

Stantec recommends that Sio Silica continues to more accurately define the CAPEX and OPEX estimate for the DEN Property and to secure relationships with contractors, vendors, and suppliers.

 

Table 1.11 provides cost estimates for these studies.

 

Table 1.11

Engineering Bridging Studies

 

Task  Estimated Cost (C$) 
Engineering Bridging Studies   550,000 

 

  1-22

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

2INTRODUCTION

 

On Dec 5, 2022, Sio Silica Corporation (Sio Silica) contracted Stantec Consulting Ltd (Stantec) to prepare a Technical Report Summary regarding the Initial Assessment (IA) for the DEN Property. The Technical Report Summary was prepared in accordance with the requirements of the U.S. Securities and Exchange Commission (SEC) reporting of material mining assets under regulation S-K 1300.

 

The author(s) note that this Study is preliminary in nature, that it includes inferred mineral resources that are considered too speculative geologically to have the economic considerations applied to them that would enable them to be categorized as mineral reserves, and there is no certainty that the resource estimates will be realized.

 

The accuracy of resource estimates is, in part, a function of the quality and quantity of available data and of engineering and geological interpretation and judgment. Given the data available at the time this report was prepared, the estimates presented herein are considered reasonable. However, they should be accepted with the understanding that additional data and analysis available subsequent to the date of the estimates may necessitate revision. These revisions may be material. There is no guarantee that all or any part of the estimated resources will be recoverable.

 

  2-1

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

3PROPERTY DESCRIPTION

 

3.1Description and Location

 

The centre of the Property is located approximately 60 km southeast of the city of Winnipeg, Manitoba within the Rural Municipalities of Ste. Anne, Hanover and La Broquerie. The Property is accessed from Winnipeg by the Trans-Canada Highway, and PR 210 for the northern section of the Property, and Provincial Highway 12 for the southern section of the Property. The general property location is shown on Figure 3-1.

 

The Property encompasses 63,750 hectares (157,530 acres) and is shown on NTS Map Sheet 62. The main block of the Property expands from 654,900E to 693,250E, and 5,459,450N to 5,502,750N, and the centre of the Property is at 49.451287°N and -96.513671°E (UTM 14 U 680,199E and 5,480,597N), as shown on Figure 3-2.

 

3.2Mining Claims

 

The Property, which consists of 278 claims, are all in surveyed territory. The Property is held by CanWhite, which is now Sio Silica. Table 3.1 provides a summary of the active claims. The locations of the claims are shown on Figure 3.2.

 

To maintain the claims in good standing, Sio Silica must fulfill the requirements of Manitoba Regulation 64/92, which includes the following obligations (Manitoba, 1992b):

 

The claim holder must spend $12.50 per hectare/year from year two to year 10, and then $25 per hectare/year from year 11 and for each year thereafter.

 

An annual assessment report detailing exploration activities and expenditures must be filed within the reporting period. The first assessment report must be filed within 60 days of the second anniversary of claim approval, with subsequent reports submitted annually.

 

  3-1

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  3-2

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

  3-3

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 3.1

Active DEN Property Claims

 

Claim
Name
  Disposition
Number
  Claim
Type
  Expiry
Date
  Area
(ha)
DEN 1   SV14008   Mining   11/2/2023   128
DEN 2   SV14005   Mining   11/2/2023   256
DEN 3   SV14006   Mining   11/2/2023   256
DEN 4   SV14004   Mining   11/2/2023   256
DEN 5   SV14007   Mining   11/2/2023   133
DEN 6   SV14009   Mining   11/2/2023   134
DEN 7   SV14010   Mining   11/2/2023   256
DEN 8   SV14015   Mining   11/2/2023   207
DEN 9   SV14011   Mining   11/2/2023   256
DEN 10   SV14012   Mining   11/2/2023   256
DEN 11   SV14013   Mining   11/2/2023   68
DEN 12   SV14014   Mining   11/2/2023   192
DEN 13   SV14016   Mining   11/2/2023   132
DEN 14   SV14017   Mining   11/2/2023   138
DEN 15   SV14018   Mining   11/2/2023   256
DEN 16   SV14019   Mining   11/2/2023   276
DEN 17   SV14020   Mining   11/2/2023   143
DEN 18   SV14021   Mining   11/2/2023   276
DEN 19   SV14022   Mining   11/2/2023   276
DEN 20   SV14023   Mining   11/2/2023   276
DEN 21   SV14024   Mining   11/2/2023   276
DEN 22   SV14025   Mining   11/2/2023   276
DEN 23   SV14026   Mining   11/2/2023   276
DEN 24   SV14027   Mining   11/2/2023   276
DEN 25   SV14028   Mining   11/2/2023   75
DEN 26   SV14029   Mining   11/2/2023   276
DEN 27   SV14030   Mining   11/2/2023   256
DEN 28   SV14031   Mining   11/2/2023   276
DEN 30   SV14033   Mining   11/2/2023   276
DEN 31   SV14034   Mining   11/2/2023   276
DEN 32   SV14035   Mining   11/2/2023   276
DEN 33   SV14036   Mining   11/2/2023   276
DEN 34   SV14037   Mining   11/2/2023   276
DEN 36   SV14039   Mining   11/2/2023   138
DEN 37   SV14040   Mining   11/2/2023   276

 

  3-4

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 3.1 (Cont’d)

 

Claim
Name
  Disposition
Number
  Claim
Type
  Expiry
Date
  Area
(ha)
DEN 38   SV14041   Mining   11/2/2023   276
DEN 39   SV14042   Mining   11/2/2023   276
DEN 41   SV14043   Mining   11/2/2023   276
DEN 42   SV14044   Mining   11/2/2023   276
DEN 43   SV14045   Mining   11/2/2023   276
DEN 44   SV14046   Mining   11/2/2023   276
DEN 45   SV14047   Mining   11/2/2023   276
DEN 46   SV12454   Mining   11/29/2023   269
DEN 47   SV14048   Mining   11/2/2023   276
DEN 48   SV14049   Mining   11/2/2023   256
DEN 49   SV14050   Mining   11/2/2023   276
DEN 50   SV14051   Mining   11/2/2023   276
DEN 51   SV14052   Mining   11/2/2023   276
DEN 52   SV14053   Mining   11/2/2023   276
DEN 53   SV14054   Mining   11/2/2023   276
DEN 54   SV14055   Mining   11/2/2023   276
DEN 55   SV12463   Mining   11/29/2023   267
DEN 56   SV12464   Mining   11/29/2023   273
DEN 57   SV12465   Mining   11/29/2023   267
DEN 58   SV12466   Mining   11/29/2023   262
DEN 59   SV14056   Mining   11/2/2023   276
DEN 60   SV14057   Mining   11/2/2023   276
DEN 61   SV14058   Mining   11/2/2023   276
DEN 62   SV14059   Mining   11/2/2023   276
DEN 63   SV14060   Mining   11/2/2023   276
DEN 64   SV14061   Mining   11/2/2023   276
DEN 65   SV14062   Mining   11/2/2023   276
DEN 66   SV14063   Mining   11/2/2023   276
DEN 67   SV12475   Mining   11/29/2023   271
DEN 68   SV12476   Mining   11/29/2023   268
DEN 69   SV12477   Mining   11/29/2023   267
DEN 70   SV12478   Mining   11/29/2023   69
DEN 71   SV14064   Mining   11/2/2023   276
DEN 72   SV14065   Mining   11/2/2023   276
DEN 73   SV14066   Mining   11/2/2023   276
DEN 74   SV14067   Mining   11/2/2023   276

 

  3-5

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 3.1 (Cont’d)

 

Claim
Name
  Disposition
Number
  Claim
Type
  Expiry
Date
  Area
(ha)
DEN 75   SV14068   Mining   11/2/2023   207
DEN 76   SV14069   Mining   11/2/2023   256
DEN 77   SV14070   Mining   11/2/2023   256
DEN 78   SV12486   Mining   11/29/2023   273
DEN 79   SV12487   Mining   11/29/2023   270
DEN 80   SV12488   Mining   11/29/2023   203
DEN 81   SV14071   Mining   11/2/2023   132
DEN 82   SV14072   Mining   11/2/2023   136
DEN 83   SV12491   Mining   11/29/2023   134
DEN 84   SV12492   Mining   11/29/2023   269
DEN 85   SV14073   Mining   11/2/2023   276
DEN 86   SV14074   Mining   11/2/2023   256
DEN 87   SV14075   Mining   11/2/2023   256
DEN 88   SV14076   Mining   11/2/2023   256
DEN 89   SV14077   Mining   11/2/2023   256
DEN 90   SV14078   Mining   11/2/2023   256
DEN 91   SV14079   Mining   11/2/2023   276
DEN 92   SV14080   Mining   11/2/2023   256
DEN 93   SV14081   Mining   11/2/2023   256
DEN 94   SV14082   Mining   11/2/2023   256
DEN 95   SV14083   Mining   11/2/2023   276
DEN 96   SV14084   Mining   11/2/2023   256
DEN 97   SV14183   Mining   7/17/2024   276
DEN 101   SV12509   Mining   11/29/2023   64
DEN 102   SV12510   Mining   11/29/2023   268
DEN 103   SV12511   Mining   11/29/2023   276
DEN 104   SV14085   Mining   11/2/2023   256
DEN 105   SV14086   Mining   11/2/2023   256
DEN 106   SV12514   Mining   11/29/2023   274
DEN 107   SV12515   Mining   11/29/2023   264
DEN 108   SV12516   Mining   11/29/2023   278
DEN 109   SV12517   Mining   11/29/2023   268
DEN 110   SV12518   Mining   11/29/2023   265
DEN 111   SV12519   Mining   11/29/2023   272
DEN 112   SV12520   Mining   11/29/2023   266
DEN 113   SV12521   Mining   11/29/2023   275

 

  3-6

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 3.1 (Cont’d)

 

Claim
Name
  Disposition
Number
  Claim
Type
  Expiry
Date
  Area
(ha)
DEN 114   SV12522   Mining   11/29/2023   273
DEN 115   SV12523   Mining   11/29/2023   279
DEN 116   SV12524   Mining   11/29/2023   262
DEN 117   SV12525   Mining   11/29/2023   270
DEN 118   SV12526   Mining   11/29/2023   235
DEN 119   SV12527   Mining   11/29/2023   261
DEN 120   SV12528   Mining   11/29/2023   265
DEN 121   SV12529   Mining   11/29/2023   269
DEN 122   SV12530   Mining   11/29/2023   266
DEN 123   SV12531   Mining   11/29/2023   269
DEN 124   SV12532   Mining   11/29/2023   268
DEN 125   SV12533   Mining   11/29/2023   274
DEN 126   SV12534   Mining   11/29/2023   270
DEN 127   SV12535   Mining   11/29/2023   273
DEN 128   SV12536   Mining   11/29/2023   271
DEN 129   SV12537   Mining   11/29/2023   253
DEN 130   SV12538   Mining   11/29/2023   273
DEN 131   SV12540   Mining   11/29/2023   262
DEN 132   SV12539   Mining   11/29/2023   273
DEN 133   SV12541   Mining   11/29/2023   265
DEN 134   SV12542   Mining   11/29/2023   264
DEN 135   SV12543   Mining   11/29/2023   269
DEN 136   SV12544   Mining   11/29/2023   277
DEN 137   SV12545   Mining   11/29/2023   261
DEN 138   SV12546   Mining   11/29/2023   272
DEN 139   SV12547   Mining   11/29/2023   270
DEN 140   SV12548   Mining   11/29/2023   268
DEN 141   SV12549   Mining   11/29/2023   264
DEN 142   SV12550   Mining   11/29/2023   257
DEN 143   SV12551   Mining   11/29/2023   265
DEN 144   SV12552   Mining   11/29/2023   234
DEN 145   SV12286   Mining   11/28/2023   267
DEN 146   SV12287   Mining   11/28/2023   268
DEN 147   SV12288   Mining   11/28/2023   271
DEN 148   SV12289   Mining   11/28/2023   266
DEN 149   SV12290   Mining   11/28/2023   267

 

  3-7

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 3.1 (Cont’d)

 

Claim
Name
  Disposition
Number
  Claim
Type
  Expiry
Date
  Area
(ha)
DEN 150   SV12291   Mining   11/28/2023   267
DEN 151   SV12292   Mining   11/28/2023   266
DEN 152   SV12293   Mining   11/28/2023   269
DEN 153   SV12294   Mining   11/28/2023   138
DEN 154   SV12295   Mining   11/28/2023   267
DEN 155   SV12296   Mining   11/28/2023   271
DEN 156   SV12297   Mining   11/28/2023   268
DEN 157   SV12299   Mining   11/28/2023   266
DEN 158   SV12300   Mining   11/28/2023   268
DEN 159   SV12301   Mining   11/28/2023   68
DEN 160   SV12302   Mining   11/28/2023   270
DEN 161   SV12303   Mining   11/28/2023   263
DEN 162   SV12304   Mining   11/28/2023   270
DEN 163   SV12305   Mining   11/28/2023   65
DEN 179   SV12321   Mining   11/28/2023   275
DEN 180   SV12322   Mining   11/28/2023   272
DEN 181   SV12323   Mining   11/28/2023   272
DEN 183   SV12355   Mining   11/28/2023   268
DEN 184   SV12356   Mining   11/28/2023   268
DEN 185   SV12357   Mining   11/28/2023   269
DEN 186   SV12358   Mining   11/28/2023   269
DEN 187   SV12359   Mining   11/28/2023   272
DEN 188   SV12360   Mining   11/28/2023   267
DEN 189   SV12361   Mining   11/28/2023   272
DEN 190   SV12362   Mining   11/28/2023   268
DEN 191   SV12363   Mining   11/28/2023   264
DEN 192   SV12364   Mining   11/28/2023   270
DEN 193   SV12365   Mining   11/28/2023   271
DEN 194   SV12366   Mining   11/28/2023   268
DEN 195   SV12367   Mining   11/28/2023   276
DEN 196   SV12368   Mining   11/28/2023   271
DEN 197   SV12369   Mining   11/28/2023   260
DEN 198   SV12370   Mining   11/28/2023   272
DEN 199   SV12371   Mining   11/28/2023   266
DEN 201   SV12373   Mining   11/28/2023   130
DEN 202   SV12374   Mining   11/28/2023   134

 

  3-8

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 3.1 (Cont’d)

 

Claim
Name
  Disposition
Number
  Claim
Type
  Expiry
Date
  Area
(ha)
DEN 203   SV12375   Mining   11/28/2023   269
DEN 204   SV12376   Mining   11/28/2023   269
DEN 205   SV12377   Mining   11/28/2023   268
DEN 206   SV12378   Mining   11/28/2023   272
DEN 207   SV12379   Mining   11/28/2023   266
DEN 208   SV12380   Mining   11/28/2023   205
DEN 209   SV12381   Mining   11/28/2023   263
DEN 212   SV12384   Mining   11/28/2023   268
DEN 213   SV12385   Mining   11/28/2023   270
DEN 214   SV12386   Mining   11/28/2023   134
DEN 215   SV12387   Mining   11/28/2023   268
DEN 216   SV12388   Mining   11/28/2023   235
DEN 217   SV12389   Mining   11/28/2023   204
DEN 218   SV12390   Mining   11/28/2023   136
DEN 219   SV12391   Mining   11/28/2023   131
DEN 220   SV12392   Mining   11/28/2023   250
DEN 221   SV12393   Mining   11/28/2023   232
DEN 223   SV12395   Mining   11/28/2023   132
DEN 224   SV12396   Mining   11/28/2023   177
DEN 225   SV12397   Mining   11/28/2023   202
DEN 226   SV12398   Mining   11/28/2023   269
DEN 227   SV12399   Mining   11/28/2023   67
DEN 228   SV12400   Mining   11/28/2023   134
DEN 229   SV12401   Mining   11/28/2023   272
DEN 230   SV12402   Mining   11/28/2023   151
DEN 231   SV12403   Mining   11/28/2023   271
DEN 233   SV12405   Mining   11/28/2023   221
DEN 234   SV12406   Mining   11/28/2023   55
DEN 235   SV12407   Mining   11/28/2023   115
DEN 236   SV12408   Mining   11/28/2023   180
DEN 237   SV12409   Mining   11/28/2023   71
DEN 238   SV12410   Mining   11/28/2023   211
DEN 239   SV12411   Mining   11/28/2023   272
DEN 240   SV12412   Mining   11/28/2023   271
DEN 241   SV12413   Mining   11/28/2023   187
DEN 242   SV12414   Mining   11/28/2023   269

 

  3-9

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 3.1 (Cont’d)

 

Claim
Name
  Disposition
Number
  Claim
Type
  Expiry
Date
  Area
(ha)
DEN 243   SV12415   Mining   11/28/2023   275
DEN 244   SV12416   Mining   11/28/2023   270
DEN 245   SV12417   Mining   11/28/2023   251
DEN 246   SV12710   Mining   12/16/2023   260
DEN 268   SV12711   Mining   12/16/2023   205
DEN 269   SV13512   Mining   9/17/2023   202
DEN 270   SV13513   Mining   9/17/2023   70
DEN 271   SV13514   Mining   9/17/2023   269
DEN 272   SV13515   Mining   9/17/2023   136
DEN 273   SV13516   Mining   9/17/2023   131
DEN 274   SV13517   Mining   9/17/2023   250
DEN 275   SV13518   Mining   9/18/2023   65
DEN 276   SV13519   Mining   9/18/2023   48
DEN 277   SV13520   Mining   9/18/2023   69
DEN 278   SV13521   Mining   9/18/2023   66
DEN 279   SV13522   Mining   9/18/2023   201
DEN 280   SV13523   Mining   9/18/2023   266
DEN 281   SV13524   Mining   9/18/2023   65
DEN 282   SV13525   Mining   9/18/2023   132
DEN 283   SV13526   Mining   9/18/2023   16
DEN 284   SV13527   Mining   9/18/2023   32
DEN 285   SV13528   Mining   9/18/2023   274
DEN 286   SV13529   Mining   9/18/2023   265
DEN 287   SV14362   Mining   Pending   70
DEN 288   SV14363   Mining   Pending   65
DEN 289   SV14364   Mining   Pending   65
DEN 290   SV14108   Mining   12/12/2023   276
DEN 291   SV14109   Mining   12/12/2023   276
DEN 292   SV14110   Mining   12/12/2023   138
DEN293   SV13915   Mining   6/1/2023   256
DEN294   SV13916   Mining   6/1/2023   256
DEN295   SV13917   Mining   6/1/2023   256
DEN296   SV13918   Mining   6/1/2023   256
DEN297   SV13919   Mining   6/1/2023   256
DEN298   SV13920   Mining   6/1/2023   256
DEN299   SV13921   Mining   6/1/2023   256

 

  3-10

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 3.1 (Cont’d)

 

Claim
Name
  Disposition
Number
  Claim
Type
  Expiry
Date
  Area
(ha)
DEN300   SV13922   Mining   6/1/2023   256
DEN301   SV13923   Mining   6/1/2023   256
DEN302   SV13924   Mining   6/1/2023   256
DEN303   SV13926   Mining   6/1/2023   256
DEN304   SV13925   Mining   6/1/2023   256
DEN 305   SV13927   Mining   6/1/2023   256
DEN306   SV13928   Mining   6/1/2023   256
DEN307   SV13929   Mining   6/1/2023   256
DEN308   SV13930   Mining   6/1/2023   256
DEN309   SV13931   Mining   6/1/2023   136
DEN310   SV13932   Mining   6/1/2023   256
DEN311   SV13933   Mining   6/1/2023   140
DEN312   SV14196   Mining   7/31/2024   75
DEN313   SV13961   Mining   6/25/2023   194
DEN314   SV13962   Mining   6/25/2023   258
DEN315   SV13963   Mining   6/25/2023   65
DEN316   SV13964   Mining   6/25/2023   175
DEN317   SV13965   Mining   6/25/2023   64
DEN318   SV13967   Mining   6/25/2023   256
DEN 319   SV13974   Mining   6/25/2023   64
DEN275A   SV13975   Mining   6/25/2023   192
DEN 276A   SV13976   Mining   6/25/2023   166
DEN277A   SV13977   Mining   6/25/2023   190
DEN278A   SV13985   Mining   6/25/2023   189
DEN282A   SV13978   Mining   6/25/2023   66
DEN 287A   SV14276   Mining   8/21/2024   69
DEN 288A   SV14277   Mining   8/21/2024   53
Total Area   63,743

 

3.3Underlying Agreements, Royalties and Encumbrances

 

The information presented in this section was provided by Sio Silica personnel and has not been externally validated by independent legal counsel.

 

November 1, 2016 Production Royalty Agreement

 

On November 1, 2016, a production royalty agreement was signed between 1993505 Alberta Ltd. (Owner) and 1993502 Alberta Ltd. (Holder). The terms of this royalty agreement were that the Owner (now Sio Silica) is to grant, convey, and agree to pay the Holder a production royalty in respect of the Property equal to the greater of:

 

a)two (2%) percent of the Actual Proceeds commencing on the date on which Commercial Production is achieved; or

 

b)$1.00 per ton of Product extracted from the Property.

 

  3-11

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

The Production Royalty Agreement provides for an Advance Minimum Royalty payment as follows: 1) $50,000 on November 1, 2016, for the first year; 2) $75,000 on November 1, 2017 for the second year; and 3) $100,000 on November 1st of each subsequent year for the duration of the agreement.

 

Actual Proceeds is defined in the agreement as: i) in the case of Product sold or otherwise disposed of by Owner FOB Owner’s mine gate, the actual proceeds received by the Owner from such sale or other disposition of Product; or ii) in the case of Product sold or otherwise disposed of by Owner FOB a location other than Owner’s mine gate, the actual proceeds received by the Owner from such sale or other disposition of Product less reasonable operating costs incurred by Owner to transport the Product to such other sale location.

 

Commercial Production, as defined in the agreement, means and is deemed to be achieved, for the Property, on the first day of the month in which production of Product exceeds 10,000 tons.

 

April 6, 2018 Assignment, Novation, and Amending Agreements

 

The November 1, 2016, Production Agreement was replaced by four amended agreements. The 2% Actual Proceeds based on Commercial Production and the $1.00 per ton of Product extracted from the Property were divided into varying proportions in these agreements. In these agreements, the definition of Commercial Production was changed to mean “the first day of the month in which the Owner sells an amount of Product equal to, or greater than, 15,000 tons, subject to the Owner also selling an amount of Product in each of the three immediately following months equal to, or greater than, 15,000 tons, and the mine mill and processing facility is in the condition necessary for it to be capable of operating in a matter intended by management with the ability to sustain ongoing production.”

 

Royalty Rights buyback from the Founders

 

In July 2020, there was a transfer of certain founder’s royalty rights amongst the four founders that hold the royalty. On April 5, 2021, Sio Silica used its right of first refusal to purchase a portion of the founders’ royalties from the original holders. Sio Silica paid a total of $775,000 that included buyback of royalties for both the BRU and DEN properties. The remaining royalties equate to 1.34% of the Actual Proceeds commencing on the date on which Commercial Production is achieved or 67.19 cents per ton of Product extracted from the Property. The remaining Advance Minimum Royalty payment is $25,000 per year.

 

  3-12

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

3.4Environmental Liabilities

 

Stantec is not aware of any known environmental liabilities that will affect access, title or the right or ability to perform work on the Property.

 

3.5Required Permits

 

On June 19, 2018, Sio Silica received direction from the Resource Development Division, Mines and Geological Survey of Manitoba that the Carman Sand Member is a Crown mineral and is under the purview of The Mines and Minerals Act.

 

The BRU Property Technical Report Summary, completed by Stantec in October 2023 discusses the permitting requirements for the BRU Property in detail. Stantec understands that the DEN Property would be subject to similar requirements. The following is a summary of those requirements:

 

Provincial

 

oEnvironment Act Proposal Vivian Sand Extraction Project (EAP) to Environment, Climate and Parks

 

oEnvironment Act Proposal Vivian Sand Facility Project (EAP) to Environment, Climate and Parks

 

oPublic Engagement Meetings – Vivian Sand Extraction Project and Vivian Sand Facility Project

 

oDraft Sand Extraction Closure Plan to Mining, Oil and Gas as a condition of issuance of Environment Act Licence

 

oTechnical Advisory Committee (TAC) and Public Review and Response to both Facility and Extraction Projects

 

oIssuance of Environment Act Licence (EAL) for Vivian Sand Facility Project and Extraction Project (Bru Facility project EAL granted December 16, 2021.)

 

Municipal

 

oConditional Use approval or other equivalent such as a bylaw amendment to provide for Permitted Use. Issuance of Development Permit

 

oIssuance of Building Permit(s)

 

3.6Other Significant Factors and Risks

 

Stantec is not aware of any other significant factors and risks that may affect access, title or the right or ability to perform work on the Property.

 

  3-13

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

4ACCESSIBILITY, CLIMATE, LOCAL RESOURCES, INFRASTRUCTURE AND PHYSIOGRAPHY

 

4.1Topography, Elevation and Vegetation

 

The Property is located in the Boreal Plain Ecozone with the western edge of the Property in the Prairie Ecozone and the eastern edge in the Boreal Shield Ecozone. The Boreal Plain Ecozone is characterized by relatively flat lying to gently rolling plains and terraces formed by morainal diamicton deposits with lower areas composed of glaciolacustrine deposits (Smith et al., 1998).

 

The Property is within the Interlake Plain Ecoregion and the Steinbach Ecodistrict. The mean elevation of the Ecodistrict is 297 masl. The landforms in the Ecodistrict range from smooth, flat lying glaciolacustrine plain to gently undulating, water-worked glacial diamicton and glaciofluvial diamictons. Much of the diamicton in the Ecodistrict consists of extremely calcareous, cobbly and gravelly loamy diamicton underlain by sandy glaciolacustrine veneers. The western edge of the Property is in the Lake Manitoba Ecoregion. The Lake Manitoba Ecoregion is a flat lying to gently sloping, clayey glaciolacustine plain with a mean elevation of 236 masl. The Lake of the Woods Boreal Shield Ecoregion has a variable topography ranging from a flat lying to depressional glaciolacustrine plain with peatlands to a gently undulating water-worked glacial diamicton and fluvioglacial outwash plain (Smith et al., 1998).

 

The land use in the area is mixed rural and residential. Settlements include Steinbach and St. Anne. In lowland areas with good drainage, crops such as wheat, oil seeds and hay are grown. In areas where the soil is too stony to cultivate, the land is used for pasture and hay (Smith et al., 1998).

 

4.2Property Access and Proximity to Population Centers

 

The centre of the Property is located approximately 60 km southeast of the city of Winnipeg, Manitoba within the Rural Municipalities of Ste. Anne, Hanover and La Broquerie. The Property is accessed from Winnipeg by the Trans Canada Highway, and PR 210 for the northern section of the Property, and Provincial Highway 12 for the southern section of the Property.

 

4.3Climate

 

There are four weather stations near the Property, which include Ostenfeld, Winnipeg International Airport, Steinbach and Beausejour. The weather station at Ostenfeld, Manitoba is the closest in proximity to the Property and is located at 49°49' N and 96°29' W.

 

The region typically has long cold winters and short, warm summers. The coldest months are December and January. The Environment Canada climate data (Canadian Climate Normals 1981-2010 Station Data) from Ostenfeld records the average daily temperatures in December and January as -13.4oC and -16.7oC, respectively. The warmest months are July and August with daily average temperatures of 18.9oC and 18.0oC, respectively. The average precipitation varies from 104 mm in July and August to 17.3 mm in February (Environment Canada, 2023).

 

  4-1

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 4.1 summarizes the Mean Climate data for the nearby weather stations (Environment Canada, 2023).

 

Table 4.1

Mean Climate Data for Nearby Weather Stations

 

 

 

  Weather Station
Parameter 

 

Ostenfeld

  Winnipeg International Airport  Steinbach 

 

Beausejour

Location (Longitude, Latitude)  49°49' N
96°29' W
  49°55'N
97°14'W
  49°32' N
96°46' W
  50°02' N
96°28' W
Annual Mean Daily Temperature (oC)  2.7  3.0  2.8  2.8
Annual Mean Daily Maximum Temperature (oC)  8.5  8.7  8.7  8.6
Annual Mean Daily Minimum Temperature (oC)  -3.1  -2.7  -3.1  -3.1
Annual Total Rainfall (mm)  512.2  418.9  473.4  452.4
Annual Total Snowfall (mm)  122.7  113.7  107.1  117.8
Total Precipitation (mm)  634.9  521.1  580.5  570.3

 

4.4Infrastructure

 

Winnipeg is the largest major city near the Property. Winnipeg, as of 2021, has a population of 749,607 residents in the metropolitan area (Statistics Canada, 2023), and provides all required major services to advance the project. The city of Winnipeg, located on the TransCanada Highway, is the home of the James Armstrong Richardson International Airport that has numerous domestic and international flights, and is a major North American rail transportation hub with a 20,000-acre facility that services Canadian National Railway, Canadian Pacific Railway, BNSF Railway and the locally maintained and operated Greater Winnipeg Water District Railway (Railway Association of Canada, 2017; Winnipeg, 2017).

 

The city of Steinbach, which is located 58 km south-east of Winnipeg, has a population of approximately 17,806, as of 2021. Steinbach is primarily an agricultural community and has many services and commercial businesses, which includes Friesen Drillers Ltd. (Friesen) that has over 125 years of drilling, hydrogeological, and geological knowledge of the area.

 

Surface and subsurface infrastructure is well developed near the Property. Manitoba Hydro has proposed the final preferred route of the Manitoba-Minnesota Transmission Project through portions of the Property. High voltage transmission lines transect the Property. An operating Canadian National Railway line intersects the Property as shown on Figure 4.1. Rail lines provide access to western and southern markets.

 

  4-2

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

 

  4-3

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

5HISTORY

 

Prior to Sio Silica securing the current DEN Property, the area to the north was staked and drilled to assess the viability of the sand for use as a natural proppant. Norlica Minerals Company Ltd. (Norlica) conducted an exploration program and feasibility study in 1967. North Star Diamonds had previously staked an area on the western edge of the current Property. In 2019 Stantec completed a Technical Report prepared in accordance with the requirements of National Instrument 43-101 Standards of Disclosure for Mineral Projects (NI 43-101) for the DEN Property.

 

5.11967 Norlica Minerals Company Ltd. Feasibility Study

 

Norlica retained Underwood McLennan & Associates Ltd (Underwood) to conduct a feasibility study of recovery and utilization of the Ste. Anne Silica Sand Deposits (1967). Norlica obtained surface and mineral permits and Underwood conducted a sand exploration program that consisted of five test holes in January 1967. A summary of the test hole information is found in Table 5.1.

 

Table 5.1

Norlica Minerals Company Ltd. Drilling Summary

 

Hole ID   Easting   Northing   Hole Depth (m)   Drill Year
TH-1   676680.8   5495030   80.01   1967
TH-2   677157.1   5494289   75.2856   1967
TH-3   677093.6   5495739   78.486   1967
TH-4   676448   5495718   78.486   1967
TH-5   676215.2   5494310   85.344   1967

 

The sand was sampled and sent to three independent testing laboratories, which included National Testing Laboratories (NTL) in Winnipeg, Coast Eldridge, Engineers & Chemists Ltd. in Vancouver and J.T. Donald & Co. Ltd in Montreal. A quantitative analysis of the sand for Fe2O3, Al2O3, CaO, MgO, TiO2, Cr, Co, and SiO2 was completed. Typically, very low iron content occurred in the samples; with exception of samples that contained shale contamination. The amount of Al2O3 averaged 0.40%. The CaO content was typically low, with exception of hole TH- 3 where >2% occurred in Sample A. Table 5.2 summarizes the contents of the impurities.

 

A production pump test was performed on TH-4. The production pump test found that the sandstone was cemented more than anticipated, but the shallow top layer of the sandstone was less rigid, and the flow of sand was encountered. A downhole photographic study was performed to confirm the findings of the production test. At the time of this study, it was determined that the conditions were not economically feasible for extraction of silica sand (Underwood, 1967).

 

Sieve analyses was performed on the sand and was sent to Underwood McLellan & Associates Soil Laboratory. A statistical analysis was performed and found that an average of 94% of grains passed through the 40 mesh and is retained on the 80 mesh (Underwood, 1967).

 

  5-1

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

A calculation of the available quantities of silica sand in Township 7 Range EPM found an average thickness of 21 yards or 19.20 m and a total volume of 40,000,000 cubic yards or 30,582,194.3 m3 (Underwood, 1967).

 

Table 5.2

Norlica Laboratory Results of Chemical Quantitative Analyses

 

Hole ID  Sample ID 

Fe2O3

%

 

Al2O3

%

 

CaO

%

 

MgO

%

 

TiO2

%

 

Cr

%

 

Co

%

 

 

Laboratory

TH-1  A  0.05  0.14  0.14  0.01  0.01  0.00  0.00  TNL
TH-1  B  0.04  0.31  0.16  0.00  0.01  0.00  0.00  TNL
TH-1  C  0.04  0.41  0.08  0.08  0.01  0.00  0.00  TNL
TH-1  D  0.04  0.38  0.04  0.11  0.01  0.00  0.00  TNL
TH-1  E  0.04  0.38  0.04  0.00  0.01  0.00  0.00  TNL
TH-2  A  0.04  0.62  0.01  0.01  0.02  0.00  0.00  Coast Eldridge
TH-2  A  0.05  0.43  0.07  -0.01  0.01  0.00  0.00  TNL
TH-2  A  0.05  0.33  0.01  0.01  0.04  0.00  0.00  J.T. Donald
TH-2  B  0.04  0.65  0.01  0.01  0.02  0.00  0.00  Coast Eldridge
TH-2  B  0.04  0.43  0.08  0.01  0.01  0.00  0.00  TNL
TH-2  B  0.21  0.29  0.04  0.01  0.04  0.00  0.00  J.T. Donald
TH-2  C  0.05  0.68  -0.01  0.02  0.02  0.00  0.00  Coast Eldridge
TH-2  C  0.03  0.35  0.04  -0.01  0.01  0.00  0.00  TNL
TH-2  C  0.04  0.00  0.08  0.02  0.02  0.00  0.00  J.T. Donald
TH-3  A  0.47  0.97  2.07  0.81  0.01  0.00  0.00  Coast Eldridge
TH-3  A  0.43  0.72  2.23  0.15  0.01  0.00  0.00  TNL
TH-3  A  0.52  0.64  2.13  0.44  0.03  0.00  0.00  J.T. Donald
TH-3  B  0.20  0.61  0.56  0.75  0.03  0.00  0.00  Coast Eldridge
TH-3  B  0.18  0.38  0.66  0.01  0.01  0.00  0.00  TNL
TH-3  B  0.21  0.22  0.52  0.11  0.03  0.00  0.00  J.T. Donald
TH-3  C  0.07  0.51  -0.01  0.02  0.01  0.00  0.00  Coast Eldridge
TH-3  C  0.05  0.44  0.06  0.04  0.01  0.00  0.00  TNL
TH-3  C  0.07  0.31  0.03  0.01  0.02  0.00  0.00  J.T. Donald
TH-3  D  0.09  0.59  0.35  0.05  0.02  0.00  0.00  Coast Eldridge
TH-3  D  0.04  0.46  0.17  0.01  0.01  0.00  0.00  TNL
TH-3  D  0.08  0.34  0.18  0.05  0.03  0.00  0.00  J.T. Donald
TH-3  E  0.10  0.22  -0.01  0.02  0.01  0.00  0.00  Coast Eldridge
TH-3  E  0.04  0.46  0.11  0.01  0.01  0.00  0.00  TNL
TH-3  E  0.07  0.21  0.02  0.02  0.02  0.00  0.00  J.T. Donald

 

  5-2

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Table 5.2 (Cont’d)

 

Hole ID  Sample
ID
  Fe2
O3 %
  Al2O3
%
  CaO
%
  MgO
%
  TiO2
%
  Cr
%
  Co
%
  Laboratory
TH-4  A  0.03  1.02  -0.01  0.00  0.02  0.00  0.00  Coast Eldridge
TH-4  A  0.04  0.35  0.03  0.02  0.00  0.00  0.00  TNL
TH-4  A  0.05  0.29  -0.01  -0.01  0.02  0.00  0.00  J.T. Donald
TH-4  A  0.03  1.02  -0.01  0.00  0.02  0.00  0.00  Coast Eldridge
TH-4  A  0.04  0.35  0.03  0.02  0.00  0.00  0.00  TNL
TH-4  A  0.05  0.29  -0.01  -0.01  0.02  0.00  0.00  J.T. Donald
TH-4  B  0.04  0.82  -0.01  0.00  0.02  0.00  0.00  Coast Eldridge
TH-4  B  0.04  0.36  0.03  0.02  0.00  0.00  0.00  TNL
TH-4  B  0.08  0.24  -0.01  -0.01  0.03  0.00  0.00  J.T. Donald
TH-4  C  0.04  0.76  -0.01  0.01  0.02  0.00  0.00  Coast Eldridge
TH-4  C  0.04  0.40  0.04  0.02  0.00  0.00  0.00  TNL
TH-4  C  0.04  0.26  -0.01  -0.01  0.03  0.00  0.00  J.T. Donald
TH-4  D  0.06  0.74  -0.01  0.01  0.01  0.00  0.00  Coast Eldridge
TH-4  D  0.07  0.38  0.05  0.02  0.00  0.00  0.00  TNL
TH-4  D  0.08  0.24  -0.01  -0.01  0.02  0.00  0.00  J.T. Donald
TH-4  E  0.05  0.80  -0.01  0.01  0.02  0.00  0.00  Coast Eldridge
TH-4  E  0.07  0.25  0.03  0.02  0.00  0.00  0.00  TNL
TH-4  E  0.09  0.24  -0.01  -0.01  0.02  0.00  0.00  J.T. Donald
TH-5  A  0.09  0.52  0.21  0.04  0.02  0.00  0.00  Coast Eldridge
TH-5  A  0.06  0.62  0.22  0.11  0.01  0.00  0.00  TNL
TH-5  A  0.12  0.48  0.30  0.06  0.04  0.00  0.00  J.T. Donald
TH-5  B  0.15  0.78  0.67  0.06  0.02  0.00  0.00  Coast Eldridge
TH-5  B  0.04  0.61  0.25  0.06  0.01  0.00  0.00  TNL
TH-5  B  0.14  0.56  0.70  0.20  0.04  0.00  0.00  J.T. Donald
TH-5  C  0.07  0.31  -0.01  0.01  0.02  0.00  0.00  Coast Eldridge
TH-5  C  0.03  0.48  0.09  0.01  0.01  0.00  0.00  TNL
TH-5  C  0.02  0.32  0.09  0.04  0.02  0.00  0.00  J.T. Donald
TH-5  D  0.11  0.58  -0.01  0.02  0.02  0.00  0.00  Coast Eldridge
TH-5  D  0.08  0.47  0.05  0.03  0.01  0.00  0.00  TNL
TH-5  D  0.18  0.31  0.04  0.03  0.03  0.00  0.00  J.T. Donald

 

Source: Underwood, 1967

 

  5-3

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

5.22004 to 2007 North Star Diamonds

 

North Star Diamonds staked 16 claims for diamond exploration in November 2004. These claims were cancelled in January 2007. No assessment reports were found on the property. Table 5.3 is a summary of the cancelled mineral claims.

 

Table 5.3

North Star Diamonds Cancelled Mining Claims

 

Claim Name  Disposition
Number
  Lease Type  Map Number  Issue Date  Expiry Date  Area (ha) 
KIANA 3  SV10537  Mining Claim  62H07NW  2004-11-04  2007-01-03   272 
KIANA 5  SV10538  Mining Claim  62H07NW  2004-11-04  2007-01-03   137 
KIANA 8  SV10539  Mining Claim  62H07NW  2004-11-04  2007-01-03   272 
KIANA 9  SV10540  Mining Claim  62H07NW  2004-11-04  2007-01-03   278 
KIANA 11  SV10541  Mining Claim  62H07NE  2004-11-04  2007-01-03   272 
KIANA 12  SV10542  Mining Claim  62H07NE,
62H07NW
  2004-11-04  2007-01-03   140 
KIANA 15  SV10543  Mining Claim  62H07NE  2004-11-04  2007-01-03   278 
KIANA 16  SV10544  Mining Claim  62H07NE  2004-11-04  2007-01-03   140 
KIANA 17  SV10545  Mining Claim  62H07NE  2004-11-04  2007-01-03   203 
KIANA 18  SV10546  Mining Claim  62H07NE  2004-11-04  2007-01-03   208 
KIANA 19  SV10547  Mining Claim  62H07NE  2004-11-04  2007-01-03   269 
KIANA 21  SV10548  Mining Claim  62H07NE  2004-11-04  2007-01-03   274 
KIANA 22  SV10549  Mining Claim  62H07NE  2004-11-04  2007-01-03   65 
KIANA23  SV10550  Mining Claim  62H07NE  2004-11-04  2007-01-03   208 
KIANA 24  SV10551  Mining Claim  62H07NE  2004-11-04  2007-01-03   275 
KIANA 29  SV10556  Mining Claim  62H07NE  2004-11-08  2007-01-07   68 
               Total Area   3,359 

 

5.3Historical Technical Reports

 

In 2019 Stantec completed a Technical Report for the DEN Property.

 

During the period from 2019 to 2021, Sio Silica transitioned to positioning the DEN Property as a potential source of high purity silica sand for industrial purposes as opposed to a natural sand proppant. As previously mentioned, the high purity silica sand may be used in a wide range of industrial applications including electronics, medical research, metals and alloys, specialty glass, and renewable energy.

 

The 2019 Technical Report disclosed mineral resource estimates as shown in Table 5.4.

 

  5-4

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Table 5.4

Historic In-Place Mineral Resource Summary, as of May 8, 2019

 

 

  Mineral Resources (Mt) 
DEN Property  40/70 mesh Fraction   70/140 mesh fraction 
Inferred   235    117 
Total Inferred   351 

 

A comparison between the 2019/2021 resource estimates indicates an overall resource reduction. The primary reason for the resource reduction is the application of new geotechnical information and analyses used when estimating the extractable sand volumes. The QP believes that applying this new geotechnical information and analysis, and the resultant extractable sand volumes are more representative of actual conditions. This analyses and the resulting resource estimate are discussed further in Section 11.

 

The resource reduction is partially offset by the addition of new mineral claims and new drill holes, which significantly increased the resource footprint.

 

  5-5

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

6GEOLOGIC SETTING, MINERALIZATION AND DEPOSIT

 

6.1Regional Stratigraphy

 

The Winnipeg Formation was deposited in the Ordovician and is interpreted to be an erosionally isolated element of the North American cratonic platform succession that was deposited across the Transcontinental Arch (Bezys and Conley, 1998; Ozadetz and Haidl, 1989). The lowermost part of the Winnipeg Formation was deposited in a deltaic environment during a major transgression event (Bezys and Conley, 1998; Le Fever et al, 1987). With continued sea level rise, the deltaic deposits were overlain by marine shales and dolomitic limestone (Bezys and Conley, 1998).

 

The Winnipeg Formation, which is in southwestern Manitoba and at the base of the Williston Basin strata, is composed of interbedded sands and shales (Lapenskie, 2016). These Middle Ordovician sediments were deposited in shallow marine seas. The shales are generally light olive-grey in colour, kaolinitic, with variable sand and silt content (Bezys and Conley, 1998). The sand units, the thickest of which is the Carman Sand Member, are typically mature, well rounded, quartz dominant, and poorly-to-nonconsolidated. The Carman Sand Member is a discrete, east- west trending bar-like sand body within the upper half of the Winnipeg Formation in southern Manitoba. The Carman Sand Member is continuous and relatively uniform throughout the region, extending approximately 240 km from west of the Sandilands Provincial Forest located at Range 8 East, to Pelican Lake that is located at Range 16 West. The corridor of the Carman Sand Member varies in width from less than 25 km to greater than 95 km (Bezys and Conley, 1998). The maximum reported thickness is 31 m (Natural Resources Canada, 2009). The Carman Sand Member occurs at depths less than 100 m along the subcrop belt, and dips towards to the west where it can be found at depths of greater than 800 m (Natural Resources Canada, 2004). The maximum Carman Sand Member depth within the property limit is 85-90 m. The Carman Sand Member is truncated to the east by the basin edge as shown on Figure 6-1.

 

In the southwest corner of Manitoba, a thin wedge of the Deadwood Formation, which was deposited in the Cambrian Period, underlies the Winnipeg Formation (Bezys and Conley, 1998). According to Butler et al. (1955) the Deadwood Formation, in South Dakota, “consists of a basal conglomerate and buff sandstone 9 m thick, overlain by grey-green, thin bedded shale with limestone interbeds 79 m thick and topped with red-brown, very glauconitic quartz sandstone, usually thin-bedded, with random partings of green shale and Scolithos borings 40 m thick, for a total thickness of 128 m”. The Deadwood Formation that occurs in Manitoba is measured to be up to 30 m in thickness (Natural Resources Canada, 2004). Where the Deadwood Formation is not present, the Winnipeg Formation overlays the Precambrian basement.

 

  6-1

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Conformably overlying the Winnipeg Formation is the Ordovician aged Red River Formation, which is composed of limestones and dolomites (Bezys and Conley, 1998). The thickness of the Red River Formation is up to 215 m; however, along the northeastern erosional edge the formation thickness decreases to 50 m (Natural Resources Canada, 2015). The Red River Formation outcrops in central Manitoba, where it has been subdivided into the Dog Head Member, Cat Head Member, Selkirk Member and the Fort Garry Member. The Dog Head Member is primarily a basal fossiliferous, mottled limestone that is overlain by the cherty dolomite of the Cat Head Member. Overlying the Cat Head Member is the Selkirk Member, which is composed of a second sequence of fossiliferous, mottled, dolomitic limestones. The Cat Head Member becomes more calcareous in the south end of the outcrop belt where it becomes indistinguishable from the Dog Head and Selkirk Members. The Fort Garry Member, which directly overlies the Selkirk Member, consists of finely crystalline and micritic, variable argillaceous dolomites, with a medial zone of shaly dolomite breccias (Natural Resources Canada, 2015).

 

Above the Red River Formation is the Quaternary diamicton, which ranges in composition from silty to rocky, and is calcareous (Matile and Keller, 2004).

 

6.2Structural Geology

 

The Ordovician strata in southwestern Manitoba generally trends east-west to slightly north-east. The Winnipeg Formation thins irregularly from approximately 68 m in thickness in southwestern Manitoba to zero at the formation’s northern limit. The thinning of the Winnipeg Formation coincides with irregular lithofacies changes, as lithologies change from being shale dominant in the southern area to sand dominant in the northern area. The lithofacies changes may result in differential compaction (Bezys and Conley, 1998).

 

6.3Property Geology

 

Prior to 2017, most of the drilling in the area was limited to water wells that were drilled on behalf of third parties. The units described below are primarily based on reliable holes that were drilled in the Project area by Sio Silica. In general, the stratigraphy of the Property is consistent; the major units are Quaternary sediments, carbonate and shale intervals of the Red River Formation, unconsolidated sand, sandstone, and shale of the Winnipeg Formation, and Archean-age granitoid basement. The upper unconsolidated sand interval of the Winnipeg Formation, which is known as the Carman Sand Member, is the target interval to be exploited.

 

Unit thickness maps are shown on Figure 6-2 and Figure 6-3 for the Red River carbonate unit and the Carman Sand Member, respectively. The diamicton (also referred as overburden) thickness map, which includes all materials above the limestone unit, is shown on Fig 6-4. Structure contour maps of the top of the carbonate and Carman Sand Member are shown on Figure 6-5 and 6-6, respectively. North-south and east-west cross-sections are shown on Figures 6-7 to 6-10. Table 6.1 shows the units encountered on the Property.

 

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Table 6.1

Property Lithology

 

Eon   Era   Period   Geologic Unit   Member   Lithology
    Cenozoic   Quaternary           Diamicton
            Red River Formation   Selkirk, Cat Head, Dog Head members   Carbonate
Phanerozoic                 Shale
  Paleozoic   Ordovician       Carman Sand Member   Sand
            Winnipeg Formation   Equiv. Ice Box Member   Shale
              Black Island Member   Sand
Archean                   Granitoid

 

6.3.1Quaternary Sediments

 

The Pleistocene-aged diamicton is heterolithic, varies in material size distribution from silty to rocky, and typically has a calcareous component. In the Project area, the diamicton ranges from 5 m to 75 m in thickness.

 

6.3.2Red River Formation

 

Carbonate (Selkirk, Cat Head, Dog Head members)

 

The carbonate unit, which is upper Ordovician in age, is in the lower Red River Formation. In Southern Manitoba, this unit is comprised of the Dog Head, Cat Head, and Selkirk members (Natural Resources Canada, 2015). The unit varies in composition from limestone to dolostone, contains bedding-parallel fractures, may contain some bedding-perpendicular (vertical) fractures and is vuggy in areas. Commonly, the bottom 1 m to 5 m interval contains shale interbeds within the carbonate unit. of an argillaceous carbonate unit occurs directly above the shale interval. Based on the drill holes data, the carbonate unit total thickness ranges from 0 m to 35 m in the Project area.

 

Shale (Selkirk, Cat Head, Dog Head members)

 

A shale unit occurs directly beneath the carbonate unit. This shale unit forms the base of the Red River Formation and is proposed to be part of the Dog Head Member. This shale unit is highly fractured and friable. The colour of the shale varies through the interval, including brick red, greyish green, and bluish grey colourations. This shale interval, based on reliable historic drill holes as well as the 2017 and 2018 drill campaigns, varies in thickness from 0 m to 11 m.

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

6.3.3Winnipeg Formation

 

Sand (Carman Sand Member)

 

The unit encountered directly beneath the base of the Red River Formation is the Carman Sand Member (Natural Resources Canada, 2009a,b). The Carman Sand Member is in the upper section of the Winnipeg Formation. The Carman Sand Member is sand or poorly consolidated sandstone, which is well sorted, well-rounded, and typically has a fine to medium grain size. The Carman Sand Member in the Property was measured to have thicknesses between 20 m and 33 m. A basal cemented sandstone unit that typically ranges in thickness from 0.3 m to 0.5 m, was encountered in some of the drill holes.

 

Shale (Ice Box Member Equivalent)

 

A shale unit occurs directly beneath the Carman Sand Member. This unit is proposed to be equivalent to the Ice Box Member, which occurs as the middle unit in the Winnipeg Formation in North Dakota and Saskatchewan (Natural Resources Canada, 2004). The colouration of this shale unit varies significantly, including emerald green and dark brown colouration. The drilling through this unit was slow, indicating that this shale unit is more competent than previously encountered shale intervals. The thickness of this shale interval in the Project area, based on reliable drill holes that penetrated the entire unit, varies from 1 m to 25 m in thickness.

 

Sand (Black Island Member Equivalent)

 

An unconsolidated sand unit below the shale interval is proposed to be equivalent to the Black Island Member (Natural Resources Canada, 2009c). On the Property, is approximately 1 m thick, and is fine-grained, well sorted, and well-rounded. Commonly a cemented sandstone unit occurs either above or below this unconsolidated sand unit. This sandstone interval, where encountered, typically ranges in thickness from 0.3 m to 0.6 m.

 

6.3.4Granitoid

 

Granitoid basement, which is Archean in age, is altered and in areas contains disseminated pyrite.

 

6.4Deposit Types

 

The Carman Sand Member is dominantly an unconsolidated laterally extensive unit across the Property, as validated through numerous drilling campaigns. Unconsolidated sand type deposits usually require no processing beyond cleaning and size sorting. The deposit appears to have limited geological variability and limited structural complexity.

 

The geological model that is being applied is similar to other aggregate materials that are laterally extensive and discussed in detail in Section 11.1

 

6.5Mineralization

 

The target interval is the unconsolidated silica sand from the Carman Sand Member. The high purity of the sand makes it suitable for variety of usages and markets. The primary objective of the program was to delineate the quality of the sand and assess the extractable sand volumes.

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

7EXPLORATION

 

As mentioned earlier, prior to Sio Silica securing the Property, the area within the DEN claims had not been drilled for silica sands. Publicly available drill hole information for the area, is associated with water-well drilling. The publicly available information for drill holes is summarized in Section 7.1.

 

Sio Silica collected lithological information from 34 holes on the DEN property. The information for these drill holes is summarized in Section 7.2 and 7.3.

 

7.1Groundwater Information Network and Friesen Drilling Historical Data

 

Several water wells were drilled in and around the Property. Information for 3,590 water-wells within the proximity of the property was extracted from the Groundwater Information Network (GIN) database (GIN, 2019). The extracted well data includes lithology and collar information. The lithology information was reviewed, and 984 wells were identified as wells with unreliable data and were excluded from the modelling database.

 

In addition to the GIN data, information for 4 water-wells from Friesen was provided to Stantec by Sio Silica on March 13, 2019.

 

The total number of wells from GIN and Friesen used in the modelling database is 2,610 and their location is shown on Figure 7-1.

 

7.2Sio Silica 2018 Drilling Campaign Summary

 

A drilling campaign was initiated in September 2018. During this campaign, 15 holes were drilled on the DEN Property. Of the 15 holes drilled, 14 were Dual Rotary (DR) / Reverse Circulation (RC) holes that were drilled to identify formation tops and to constrain sand samples, and one was a diamond drill hole (DEN 216-1) to evaluate the geotechnical properties of the carbonate interval.

 

Table 7.1 shows a summary of the holes drilled by Sio Silica during the 2018 Drilling Campaign and Figure 7-1 shows the location of the drill holes.

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 7.1

2018 Drilling Campaign Summary

 

Hole
Name
  Type   Core
Size
  Collar
Inclination
  Spud
Date
  Datum   Zone   Easting   Northing   Elevation
(MASL)
  Hole
Depth
(m)
  Primary
Sampled
Interval
(m)
DEN-57-1   DR/RC   N/A   -90   24-Sep-18   NAD83   14   669259   5473506   291   126.49   99.06 - 124.05
DEN -84-1   DR/RC   N/A   -90   23-Nov-18   NAD83   14   669149   5483394   279   49.38   91.14 - 92.66
DEN-109-1   DR/RC   N/A   -90   27-Nov-18   NAD83   14   677550   5468705   303   75.29   77.42 - 104.85
DEN-115-1   DR/RC   N/A   -90   23-Oct-18   NAD83   14   674217   5471313   298   121.62   94.18 - 121.31
DEN-130-1   DR/RC   N/A   -90   17-Oct-18   NAD83   14   674026   5476181   294   118.87   91.14 - 117.04
DEN-134-1   DR/RC   N/A   -90   21-Nov-18   NAD83   14   679682   5474851   302   85.04   81.69 - 109.42
DEN-143-1   DR/RC   N/A   -90   29-Oct-18   NAD83   14   678176   5478941   297   101.80   77.72 - 100.28
DEN-166-1   DR/RC   N/A   -90   20-Nov-18   NAD83   14   686332   5463497   310   89.92   not sampled
DEN-178-1   DR/RC   N/A   -90   28-Nov-18   NAD83   14   680991   5468206   308   67.06   69.80 - 91.14
DEN-189-1   DR/RC   N/A   -90   12-Nov-18   NAD83   14   683094   5474886   304   72.85   74.37 - 75.90
DEN-209-1   DR/RC   N/A   -90   22-Nov-18   NAD83   14   688072   5483034   296   42.98   59.13 - 72.85
DEN-216-1   DR/RC   N/A   -90   30-Nov-18   NAD83   14   681912   5484439   290   63.09   66.75 - 94.18
  DR/DDH   HQ   -90   12-Nov-18   NAD83   14   681848   5484381       64.62   Geotechnical core logged
DEN-223-1   DR/RC   N/A   -90   7-Nov-18   NAD83   14   687202   5487867   297   77.42   59.44 - 75.90
DEN-243-1   DR/RC   N/A   -90   1-Oct-18   NAD83   14   686353   5493625   298   83.82   59.44 - 81.99

 

Note: DR = Dual Rotary; RC = Reverse Circulation; DDH = Diamond Drill Hole

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

7.3Sio Silica 2021 - 2022 Drill Campaign summary

 

Twenty drill holes were completed between 2021 and 2022. Drill hole depths varied from 62 m to 122 m; all holes were drilled vertically. The majority of the holes were drilled as exploration holes. Three drill holes (Den-117-1, Den-120-1 and Den-204-1) were cored but none of them were able to intersect the bottom of the Carman Sand Member. Two of the drill holes (Den-120-1 and Den-169-1) were drilled close to the edge of the Carman Sand Member and the sand was not intersected. Eight of the twenty wells were able to intersect the bottom of the Carman Sand Member. The location of the drill holes, listed in Table 7.2, is shown on Figure 7-1.

 

Table 7.2

2021 - 2022 Drilling Campaign Summary

 

Hole Name   Type   Datum   Zone   Easting   Northing   Elevation
(MASL)
  Hole
Depth
(m)
Den-117-1   Core   NAD83   14   671,009.6   5,470,371.2   294   109.73
Den-120-1   Core   NAD83   14   677,322.2   5,473,066.6   298   86.11
Den-128-1   5”   NAD83   14   671,780.3   5,474,434.3   291   121.92
Den-147-1   RC   NAD83   14   675,775.5   5,481,129.7   292   117.04
Den-150-1   RC   NAD83   14   671,417.6   5,480,002.0   287   121.92
Den-169-1   Dry Well   NAD83   14   683,345.7   5,463,491.3   309   120.40
Den-181-1   5”   NAD83   14   685,687.3   5,470,076.7   309   103.63
Den-186-1   5”   NAD83   14   680,759.7   5,473,222.5   305   106.98
Den-193-1   5”   NAD83   14   683,970.9   5,476,438.7   303   79.25
Den-204-1   Core   NAD83   14   682,945.2   5,480,007.5   299   67.06
Den-208-1   5”   NAD83   14   686,200.6   5,483,233.6   293   67.06
Den-226-1   5”   NAD83   14   683,166.6   5,486,507.2   282   67.06
Den-233-1   5”   NAD83   14   687,436.3   5,490,716.6   299   82.91
Den-240-1   5”   NAD83   14   685,776.9   5,491,402.0   298   72.24
Den-245-1   RC   NAD83   14   682,339.3   5,493,980.0   283   73.15
Den-269-1   RC   NAD83   14   676,397.3   5,486,820.3   288   97.54
Den-304-1   RC   NAD83   14   684,483.3   5,497,767.2   289   62.18
Den-304-2   Monitoring   NAD83   14   684,491.1   5,497,730.6   289   66.45
Den-318-1   5”   NAD83   14   672,988.6   5,493,982.7   268   78.64
Den-319-1   RC   NAD83   14   680,312.5   5,494,189.5   276   83.82

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

8Sample Preparation, Analyses and Security

 

8.1Sampling Method and approach

 

Most drill hole samples collected by Sio Silica have been subject to sieve analysis for particle size distribution (PSD) analysis. In 2018, there were 198 samples collected at five-foot intervals from 15 drill holes that are sent to AGAT laboratory in Calgary, Alberta for sieve analyses. Five of the duplicate samples were tested by Loring laboratory in Calgary, Alberta. In 2021-2022 program, 33 composite samples were collected and were subject to sieve analysis at Sio Silica’s internal facilities. Additional details are presented in the following subsections.

 

To complete PSD sieve analyses, a selected sieve stack is to be made up of no less than seven sieves of decreasing mesh size and is to include a pan and cover. This sieve stack is to be checked against a master sieve stack. A representative split sample of 100 g ± 20 g is to be selected; the material weight is to be recorded to within 0.1 g. The sample is to be placed at the top of the sieve stack with the lid and pan and is to be placed in the test sieve shaker for 10 minutes ± 5 seconds. Following this procedure, the material is to be weighed on each sieve and the resulting mass of each sieve is to be deducted from the weight for each fraction. The final cumulative mass is to be within 0.5% of the initial sample mass.

 

Total of 80 composited sample from 20 drill holes were prepared in Sio Silica laboratory and sent Liquids Matter laboratory for Whole Rock Analysis. Additional details are presented in Sub- section 8.3.3.

 

8.22018 Field Programs Sample Integrity

 

2018 Program

 

Sample collection was completed from the Carman Sand Member, typically at five-foot intervals, except for the top and bottom interval at the contacts with the upper and lower shale units. Sample collection from 13 drill holes involved: 1) Collection of the sand from the RC cyclone; amalgamation of the sand a five-gallon pail; 2) Use of a soil auger to core through the sand in the five-gallon pail and collection of 1 and 2 kg samples; and 3) Completion of chain-of-custody documentation and transportation of the 1 kg sand sample to AGAT laboratory in Calgary for sieve analyses. In 2023, composited samples for each hole were prepared in Sio Silica’s laboratory for further ICP testing at the Liquids Matter laboratory in Calgary.

 

2021 and 2022 Programs

 

The 2018 program demonstrated vertical sand quality homogeneity of the Carman Sand Member. As a result, during 2021-2022 program, thirty-three composited samples of the Carman Sand Member were collected from eleven holes (3 samples per hole). The depth of the beginning of the sampled intervals ranged from 53.0 m to 95.7 m and the depth of the end of the sample interval ranged from 73.2 m to 121.0 m. As some of the drill holes didn’t intersect the bottom of the Carman Sand Member, the length of the sample intervals ranged from 3.0 m to 34.7 m. All samples were subject to PSD sieve analysis at Sio Silica’s internal facilities in Calgary, and then sent for ICP testing at the Liquids Matter laboratory.

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

8.3Laboratory Credentials, Testing Methodology, and Results

 

Table 8.1 shows a summary of the number and type of analyses by year and laboratory. The following sections summarize the work completed by each laboratory.

 

Table 8.1

Summary of Analyses Completed by Year and Laboratory

 

Laboratory   Year   No. Samples   Analyses Type
AGAT   2018   198   Sieve Analysis
Loring   2018   5   Sieve Analysis
Sio Silica   2018*   8   Sieve Analysis
  2021-2022   33   40/70 and 70/140 size fraction clean and magnetic separator
Liquids Matter   2021-2022   80   ICP Whole Rock on 40/70 and 70/140 size fraction

 

8.3.1AGAT Credentials and Testing Methodology

 

AGAT completed sample preparation and sieve analysis for all samples collected during the 2018 drilling program. AGAT is an independent laboratory with ISO 9001:2015 (Certificate No. 0100019).

 

In 2018, AGAT completed sieve analyses on 198 samples. AGAT inventoried, dried and processed the samples through a riffle splitter to obtain a representative sample size of approximately 100 g, as required for the sieve analyses. AGAT determined that the samples contained clay-size material, but typically very low clay material based on mineralogical assessment. As such, AGAT determined that the material could be dry sieved using a sonic shaker, as outlined in Section 7.3.1 of the API Recommended Practice 40.

 

8.3.2Sio Silica Internal Facility Credentials and Processing Methodology

 

Starting in 2020, personnel from Sio Silica developed an internal methodology to do bench scale test procedures for further purification of raw sand samples from the DEN Property at select sand size ranges, notably 40/70 and 70/140. The purpose of the sample processing was to generate a bench scale market ready sand product. In total 13 representative composite samples from within the Carman Sand Member were processed as shown in Table 8.2. All samples were subject to PSD tests in the Sio Silica laboratory.

 

The Sio Silica internal laboratory where these procedures were implemented is not an accredited facility and is not independent. Section 9 discusses the accuracy and consistency of the Sio Silica laboratory results.

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 8.2

Samples PSD Tested at Sio Silica Facilities

 

      Carman Sand Member Interval (m) 
Field Program Year  Hole ID  From   To 
2018  Den-57-1   99.06    124.05 
2018  Den-130-1   91.14    117.04 
2021-2022  Den-319-1   58.52    82.91 
2021-2022  Den-318-1   64.62    78.64 
2021-2022  Den-304-1   59.13    62.18 
2021-2022  Den-269-1   74.37    95.10 
2021-2022  Den-245-1   53.04    73.15 
2021-2022  Den-240-1   58.52    72.24 
2021-2022  Den-226-1   55.17    67.06 
2021-2022  Den-193-1   69.80    79.25 
2021-2022  Den-150-1   93.57    121.01 
2021-2022  Den-147-1   82.30    117.04 
2021-2022  Den-128-1   95.71    119.79 
   Count   13    13 
   Minimum   53.04    62.18 
   Maximum   99.06    124.05 
   Mean   73.46    93.03 

 

The sample processing procedure as summarised from Sio Silica’s laboratory procedures internal document is described as follows:

 

1.Ensure sample is completely dry, use oven if necessary.

 

2.Composite samples from individual well (~50-100g per sample totaling ~1.2kg. Sample number assigned and recorded in database.

 

3.Sieve samples at fractions 40/70 and 70/140 at an amplitude of 1.30mm for 15 minutes

 

a.Sieve #’s: 30, 40, 50, 60, 70, 80, 100, 140, Pan

 

4.Re-sieve the 40/70 and 70/140 sample separately at an amplitude of 1.30mm for 5 minutes.

 

a.40/70 sample Sieve #’s: 40, 70, Pan

 

b.70/140 sample Sieve #’s: 70, 140, Pan

 

5.Water wash 40/70 sample using No. 70 and No. 325 wet sieve.

 

6.Water wash 70/140 sample using the No. 325 wet sieve until water (tap water) runs clear and there are no visible fines suspended in solution.

 

7.Transfer samples from steps 4 and 5 to anchor glass baking dishes to dry in oven at 375°F for ~1 hour. Lab Testing Point A (40/70 fraction) and A-1 (70/140 fraction) are taken.

 

8.Run each sample through the Eriez Dry High Intensity Rare Earth Roll Magnetic Separator three times. Lab Testing point B (40/70 fraction) and B-1 (70/140 fraction) are taken.

 

Available equipment for drying includes a Quincy Lab 30GC 2.0 ft3 gravity convection oven capable of 450 F. Sieves are ASTM E11 standard and a Retsch AS 300 control sieve shaker is used that complies with ISO 9001 requirements.

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

From the original 13 composite sand samples, 52 ICP test point samples were produced as outlined:

 

Point A: 13 samples at 40/70 fraction – sieved, water washed, and dried.

 

Point A-1: 13 samples at 70/140 fraction – sieved, water washed, and dried.

 

Point B: 13 samples at 40/70 fraction – Sieved, water washed, dried, and ran through dry magnetic separator.

 

Point B-1: 13 samples at 70/140 fraction – Sieved, water washed, dried, and ran through dry magnetic separator.

 

These 52 samples were then sent to Liquids Matter laboratory for whole rock analysis.

 

Seven additional composited samples from the 2018 program were also processed in the Sio Silica laboratory and 28 ICP test point samples were prepared, using the same sample preparation approach as described above, and sent to Liquids Matter laboratory for whole rock analysis. Table 8.3 shows the additional 7 samples.

 

Table 8.3

Samples Processed at Sio Silica Facilities

 

      Carman Sand Member Interval (m) 
Field Program Year  Hole ID  From   To 
2018  Den-109-1   77.42    104.85 
2018  Den-115-1   94.18    121.31 
2018  Den-134-1   80.16    110.03 
2018  Den-143-1   77.11    100.89 
2018  Den-189-1   74.07    100.28 
2018  Den-216-1   66.14    94.18 
2018  Den-84-1   89.92    106.38 
   Count   7    7 
   Minimum   66.14    94.18 
   Maximum   94.18    121.31 
   Mean   79.86    105.42 

 

8.3.3Liquids Matter Whole Rock Analysis

 

Liquids Matter is an independent accredited laboratory located in Calgary, Alberta, that was used by Sio Silica to complete whole rock analysis on 80 sized and cleaned samples. The whole rock analysis was completed using Inductively coupled plasma - optical emission spectrometry (ICP- OES). A summary of the ICP-OES test results comparing 40/70 and 70/140 size fractions before (Point A, A-1) and after magnetic separation (Point B, B-1) are shown in Table 8.4. All ICP-OES ion test results for all four sample types (Point A, B, A-1 and A-2) are presented in oxide form and are shown in Table 8.5 through Table 8.8. The ICP-OES test results show that the magnetic separator by Sio Silica was successful in increasing sand purity from a mean of 99.89% SiO2 to 99.92% SiO2 for the 40/70 size fraction, and 99.84% SiO2 to 99.92% SiO2 for the 70/140 size fraction. It should be noted that the sample collected from drill hole DEN-318-1 shows anomalous results and has been interpreted as a contaminated sample and excluded from the interpolated data set used in sand quality evaluation.

 

The spatial distribution of SiO2, Fe and Al content measurements, received from Liquids Matter after magnetic separation (Step/Point B), are shown in Figure 8-1 to Figure 8-6 for the 40/70 and 70/140 size fractions. The results from Den-245-1 were closely reviewed and flagged as abnormal with possible sample contamination. The ICP results from Den-245-1 samples were excluded from the data interpolation. The percentage of each size fraction in each sample site, listed in Table 8.3, is shown in the contour overlay at 3% intervals.

 

 

  8-4

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 8.4

Liquids Matter ICP-OES Summary Test Results

 

   Point A 40/70 Fraction   Point B 40/70 Fraction   Point A-1 70/140 Fraction   Point B-1 70/140 Fraction 
Parameter  wash and dry   wash, dry and magnetic separation   wash and dry   wash, dry and magnetic separation 
     SiO2    Total Oxides     FeO2     SiO2    Total Oxides     FeO2     SiO2    Total Oxides     FeO2     SiO2    Total Oxides     FeO2 
    (%)    (%)    (ppm)    (%)    (%)    (ppm)    (%)    (%)    (ppm)    (%)    (%)    (ppm) 
Count   20    20    20    20    20    20    20    20    20    20    20    20 
Minimum   99.51    0.041    34.53    99.69    0.035    27.1    99.89    0.054    58.3    99.64    0.040    34.4 
Maximum   99.96    0.486    397.0    99.97    0.309    266.7    99.95    1.114    917.5    99.96    0.357    398.8 
Mean   99.89    0.106    143.6    99.92    0.076    86.1    99.84    0.163    234.1    99.92    0.081    97.4 
Std. Deviation   0.10    0.097    99.51    0.06    0.060    57.8    0.23    0.228    205.5    0.07    0.069    84.7 

 

  8-5

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 8.5

Liquids Matter ICP-OES Point A 40/70 Test Results

 

Sample  Hole  SiO2   S   Mg   Ni   Ba   Mn   Fe   Cr   Al   Ca   Cu   Ti   Sr   Y   Ce   Li   K   Na 
ID  ID  (%)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm) 
22164  Den-57-1   99.96    42.45    21.94    0.21    ND    0.96    86.43    1.38    153.26    61.74    0.31    2.25    0.72    ND    ND    0.55    20.08    11.84 
22168  Den-84-1   99.92    40.16    37.51    0.47    ND    0.49    291.74    1.74    192.69    188.57    2.80    4.67    0.82    0.04    2.23    ND    33.82    20.84 
22172  Den-109-1   99.93    101.17    30.42    0.15    ND    0.76    138.47    1.27    189.25    109.61    0.38    2.26    0.89    0.04    4.31    0.09    26.68    26.68 
22176  Den-115-1   99.94    25.19    31.37    0.15    ND    0.47    156.62    1.89    222.97    135.52    0.51    5.16    1.27    0.02    3.09    0.10    32.43    15.83 
22180  Den-130-1   99.94    52.27    37.11    0.19    ND    0.88    86.03    1.41    170.87    243.46    0.34    4.04    2.73    0.03    3.16    0.08    23.02    15.58 
22184  Den-134-1   99.92    41.41    91.64    0.28    ND    0.96    95.03    1.54    214.65    299.01    0.53    8.68    4.13    0.05    2.90    0.07    40.88    22.48 
22188  Den-143-1   99.95    34.38    24.27    0.13    ND    0.20    34.53    1.25    224.22    92.72    1.46    3.83    3.70    0.03    2.23    0.33    22.35    20.76 
22196  Den-189-1   99.95    27.20    28.24    0.31    ND    0.25    42.84    1.53    188.70    109.05    0.41    2.86    2.39    0.03    1.84    ND    26.72    19.02 
22204  Den-216-1   99.92    21.86    27.71    0.16    0.30    0.47    75.33    1.16    455.45    86.83    3.55    7.17    3.21    0.06    4.75    0.82    33.73    25.55 
22216  Den-304-1   99.88    8.56    67.16    0.23    0.68    1.01    112.55    1.28    625.04    219.89    0.24    11.06    2.99    0.08    2.37    0.89    87.46    27.30 
22220  Den-147-1   99.93    ND    32.26    0.37    0.76    1.41    134.19    1.79    296.17    145.26    0.64    7.19    4.28    0.04    1.81    ND    25.36    15.46 
22224  Den-150-1   99.95    ND    30.10    0.20    0.37    0.44    88.39    1.26    189.39    73.90    2.59    4.01    1.53    0.03    1.85    ND    22.39    19.62 
22228  Den-269-1   99.88    ND    34.61    0.30    1.16    1.65    136.59    1.34    574.89    384.62    0.95    8.48    2.50    0.06    2.93    0.78    21.56    13.44 
22232  Den-319-1   99.83    ND    80.87    0.48    0.83    2.04    306.76    1.87    791.71    415.28    1.10    6.79    2.49    0.07    2.65    1.64    39.79    27.76 
22236  Den-128-1   99.87    36.49    81.52    0.43    0.82    1.50    296.85    1.73    282.76    476.22    0.86    5.13    1.76    0.06    2.90    ND    46.02    7.39 
22240  Den-193-1   99.95    ND    35.29    0.17    0.83    0.45    59.59    1.58    222.35    97.55    0.29    6.21    3.47    0.07    4.03    ND    23.90    11.48 
22244  Den-226-1   99.89    78.62    25.04    0.77    0.89    0.68    129.66    2.06    713.74    119.63    0.45    5.37    2.82    0.11    2.85    1.60    25.43    11.57 
22248  Den-240-1   99.84    0.58    45.53    0.50    0.93    1.37    124.97    1.56    969.40    298.86    0.64    6.75    2.56    0.15    3.07    2.78    28.40    29.68 
22252  Den-245-1   99.91    ND    21.53    0.32    0.48    0.54    77.88    1.09    689.34    65.03    0.41    4.60    1.72    0.04    1.78    1.89    9.02    3.03 
22256  Den-318-1*   99.51    385.28    256.46    0.56    0.86    3.72    396.97    2.83    1017.23    2690.51    4.08    11.29    2.71    0.17    2.69    2.70    47.68    13.54 
Count  n/a   20    14    20    20    12    20    20    20    20    20    20    20    20    19    19    14    20    20 
Min  n/a   99.51    0.58    21.53    0.13    0.30    0.20    34.53    1.09    153.26    61.74    0.24    2.25    0.72    0.02    1.78    0.07    9.02    3.03 
Max  n/a   99.96    385.28    256.46    0.77    1.16    3.72    396.97    2.83    1017.23    2690.51    4.08    11.29    4.28    0.17    4.75    2.78    87.46    29.68 
Mean  n/a   99.89    63.97    52.03    0.32    0.74    1.01    143.57    1.58    419.20    315.66    1.13    5.89    2.43    0.06    2.81    1.02    31.84    17.94 
Std Deviation  n/a   0.10    96.02    52.62    0.17    0.25    0.81    99.51    0.40    286.56    572.71    1.16    2.58    1.06    0.04    0.84    0.95    16.11    7.28 

 

Note: ND = Not Detected. Limits of detection are the following: S: 0.038 ppm; Ba: 0.001 ppm; Y: 0.000 ppm; Ce: 0.050 ppm; Li: 0.003; Na: 0.094. Summary statistics include only analyses above the limit of detection. The reported impurities are in oxide form.

 

*NOTE: Drill hole DEN-318 sample is interpreted as contaminated and has been excluded from the interpolated data set used in sand quality evaluation.

 

  8-6

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 8.6

Liquids Matter ICP-OES Point B 40/70 Test Results

 

Sample  Hole  SiO2   S   Mg   Ni   Ba   Mn   Fe   Cr   Al   Ca   Cu   Ti   Sr   Y   Ce   Li   K   Na 
ID  ID  (%)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm) 
22166  Den-57-1   99.97    17.45    21.66    0.19    ND    0.46    52.68    1.18    129.47    98.15    3.22    1.89    0.69    0.03    4.01    0.33    17.37    ND 
22170  Den-84-1   99.94    1.97    27.66    0.41    0.46    0.47    266.72    1.72    181.13    126.99    3.18    4.58    0.87    0.03    1.90    ND    26.47    ND 
22174  Den-109-1   99.95    81.22    24.32    0.20    ND    0.41    97.40    1.19    166.07    55.21    0.24    1.80    0.84    0.03    3.95    0.28    19.78    10.47 
22178  Den-115-1   99.95    20.03    21.64    0.15    ND    0.26    149.20    1.82    184.64    45.88    0.08    3.18    1.00    0.03    3.06    0.31    24.32    ND 
22182  Den-130-1   99.96    21.56    23.26    0.16    ND    0.36    45.14    1.50    187.73    94.21    0.24    3.20    3.17    0.05    3.17    0.30    20.21    ND 
22186  Den-134-1   99.95    16.82    47.34    0.30    ND    0.28    50.20    1.75    250.99    125.53    0.36    4.51    5.25    0.04    3.89    0.31    37.35    5.28 
22190  Den-143-1   99.96    16.85    22.99    0.16    ND    0.19    27.10    1.42    239.11    71.51    1.40    3.99    4.25    0.03    1.97    0.37    22.04    4.67 
22198  Den-189-1   99.94    22.78    35.63    0.33    ND    0.22    45.72    1.97    318.85    84.04    0.40    5.09    3.35    0.05    3.45    0.35    29.85    5.06 
22206  Den-216-1   99.93    19.53    25.07    0.23    0.16    0.30    55.79    1.26    450.83    40.90    3.42    4.49    2.82    0.06    3.54    0.89    25.37    14.52 
22218  Den-304-1   99.91    ND    62.47    0.19    0.72    0.50    84.11    1.11    537.79    105.50    0.23    4.99    2.82    0.07    2.45    0.76    72.82    4.67 
22222  Den-147-1   99.95    ND    27.58    0.29    0.72    0.37    51.76    1.52    250.92    102.40    0.53    4.77    4.18    0.04    1.56    ND    19.43    ND 
22226  Den-150-1   99.96    ND    29.23    0.24    0.30    0.36    70.06    1.31    208.15    47.77    2.41    5.02    1.74    0.04    2.46    ND    17.67    ND 
22230  Den-269-1   99.93    ND    31.78    0.25    0.92    0.82    100.10    1.11    407.94    144.89    0.99    4.93    2.50    0.06    2.56    0.38    15.13    ND 
22234  Den-319-1   99.90    ND    51.08    0.23    0.74    0.62    176.45    1.23    515.48    215.46    1.22    3.58    2.41    0.05    1.96    0.60    29.85    ND 
22238  Den-128-1   99.93    15.84    41.92    0.28    0.92    0.69    91.56    1.23    232.76    310.86    0.90    3.28    1.56    0.05    2.71    ND    35.24    ND 
22242  Den-193-1   99.96    ND    36.11    0.17    0.80    0.23    37.68    1.69    247.96    71.74    0.28    6.35    3.80    0.07    4.32    ND    21.61    3.11 
22246  Den-226-1   99.89    40.44    28.17    0.72    0.89    0.60    84.46    2.07    753.09    120.11    0.56    4.82    3.01    0.10    2.58    1.63    22.46    1.70 
22250  Den-240-1   99.90    ND    35.46    0.22    0.79    0.87    68.32    1.29    711.55    184.84    0.80    4.34    2.46    0.09    2.33    1.55    19.36    ND 
22254  Den-245-1   99.91    ND    22.43    0.34    0.54    0.25    38.25    1.15    812.78    41.35    0.20    4.80    1.95    0.05    2.03    2.39    6.25    ND 
22258  Den-318-1   99.69    52.74    69.22    0.37    0.74    1.58    129.79    2.23    1011.76    1746.97    0.79    4.94    2.52    0.11    2.39    2.77    45.45    ND 
Count  n/a   20    12    20    20    13    20    20    20    20    20    20    20    20    20    20    15    20    8 
Min  n/a   99.69    1.97    21.64    0.15    0.16    0.19    27.10    1.11    129.47    40.90    0.08    1.80    0.69    0.03    1.56    0.28    6.25    1.70 
Max  n/a   99.97    81.22    69.22    0.72    0.92    1.58    266.72    2.23    1011.76    1746.97    3.42    6.35    5.25    0.11    4.32    2.77    72.82    14.52 
Mean  n/a   99.92    27.27    34.25    0.27    0.67    0.49    86.13    1.49    389.95    191.71    1.07    4.23    2.56    0.05    2.81    0.88    26.40    6.19 
Std Deviation  n/a   0.06    21.28    13.73    0.13    0.24    0.32    57.83    0.34    254.57    372.02    1.09    1.11    1.25    0.02    0.81    0.82    13.90    4.21 

 

Note: ND = Not Detected. Limits of detection are the following: S: 0.038 ppm; Ba: 0.001 ppm; Y: 0.000 ppm; Ce: 0.050 ppm; Li: 0.003; Na: 0.094. Summary statistics include only analyses above the limit of detection. The reported impurities are in oxide form.

 

  8-7

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 8.7

Liquids Matter ICP-OES Point A-1 70/140 Test Results

 

Sample  Hole  SiO2   S   Mg   Ni   Ba   Mn   Fe   Cr   Al   Ca   Cu   Ti   Sr   Y   Ce   Li   K   Na 
ID  ID  (%)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm) 
22165  Den-57-1   99.93    28.38    31.43    0.27    ND    1.82    133.81    2.20    278.28    101.77    0.54    31.05    1.35    0.04    5.67    0.39    29.35    20.72 
22169  Den-84-1   99.87    76.49    51.78    0.82    0.04    1.92    593.35    2.40    242.73    200.38    1.31    43.27    1.03    0.07    2.01    ND    48.78    13.85 
22173  Den-109-1   99.91    65.00    43.94    0.29    ND    1.15    121.95    1.65    333.42    209.08    0.38    17.74    1.40    0.05    4.67    0.37    43.07    24.14 
22177  Den-115-1   99.87    40.03    41.23    0.30    ND    4.14    375.00    3.47    288.17    289.07    0.49    114.51    1.90    0.06    3.64    0.05    40.11    45.47 
22181  Den-130-1   99.85    75.17    41.15    0.44    2.05    13.66    384.07    5.59    236.04    219.46    1.31    430.12    4.05    0.21    5.06    0.07    30.11    26.23 
22185  Den-134-1   99.86    43.90    149.82    0.46    1.69    2.30    155.66    2.19    356.27    502.53    1.40    44.24    6.47    0.09    5.17    0.17    50.45    18.82 
22189  Den-143-1   99.94    30.97    29.85    0.21    ND    1.17    71.64    1.74    274.45    82.15    0.89    36.33    4.61    0.07    2.68    0.30    27.27    15.57 
22197  Den-189-1   99.93    29.19    41.31    0.38    0.16    0.82    97.51    1.92    304.03    122.60    0.14    20.22    3.17    0.06    2.91    0.28    42.46    23.91 
22205  Den-216-1   99.95    14.90    21.81    0.13    0.39    0.61    58.26    1.00    302.11    73.54    0.62    14.18    2.97    0.06    3.97    0.45    23.51    17.41 
22217  Den-304-1   99.85    6.34    80.83    0.28    0.90    4.41    203.97    2.01    629.32    324.31    0.27    111.75    3.18    0.11    2.32    0.79    106.68    13.60 
22221  Den-147-1   99.93    ND    30.86    0.34    0.90    1.82    124.52    1.58    250.54    157.33    0.57    32.52    4.00    0.05    1.26    ND    23.52    8.97 
22225  Den-150-1   99.92    ND    38.42    0.34    0.60    3.56    201.16    1.94    270.31    97.66    0.62    106.08    2.07    0.05    2.55    ND    26.33    10.70 
22229  Den-269-1   99.85    0.60    39.76    0.39    1.32    3.34    208.47    1.76    532.62    584.88    0.76    39.93    3.14    0.09    3.34    0.72    24.46    11.66 
22233  Den-319-1   99.85    ND    45.94    0.54    0.81    1.29    208.63    1.87    1043.83    152.51    0.46    22.32    2.61    0.08    3.20    2.62    29.23    10.39 
22237  Den-128-1   99.90    11.44    69.23    0.37    0.91    1.44    170.61    1.54    300.89    391.48    0.66    11.52    1.38    0.07    2.66    ND    50.02    8.93 
22241  Den-193-1   99.92    ND    44.11    0.30    1.07    3.33    140.58    2.31    265.67    141.78    0.59    108.17    3.29    0.10    3.69    ND    26.67    6.03 
22245  Den-226-1   99.86    57.70    31.17    1.04    1.20    1.64    174.24    2.88    875.73    172.34    0.78    30.24    3.07    0.17    3.61    2.23    24.33    10.16 
22249  Den-240-1   99.78    3.84    60.54    0.68    1.25    4.32    267.67    2.44    1334.48    350.10    0.48    105.15    3.04    0.22    4.09    4.22    27.68    21.70 
22253  Den-245-1   99.87    ND    24.59    0.51    0.63    0.90    72.59    1.55    1057.70    83.99    0.45    21.85    2.26    0.06    2.91    3.30    11.01    5.61 
22257  Den-318-1   98.89    829.66    1223.02    0.73    2.34    15.22    917.52    5.67    1325.98    6545.81    3.12    119.90    4.02    0.39    4.56    2.82    66.52    27.33 
Count  n/a   20    15    20    20    16    20    20    20    20    20    20    20    20    20    20    15    20    20 
Min  n/a   98.89    0.60    21.81    0.13    0.04    0.61    58.26    1.00    236.04    73.54    0.14    11.52    1.03    0.04    1.26    0.05    11.01    5.61 
Max  n/a   99.95    829.66    1223.02    1.04    2.34    15.22    917.52    5.67    1334.48    6545.81    3.12    430.12    6.47    0.39    5.67    4.22    106.68    45.47 
Mean  n/a   99.84    87.57    107.04    0.44    1.02    3.44    234.06    2.39    525.13    540.14    0.79    73.06    2.95    0.11    3.50    1.25    37.58    17.06 
Std Deviation  n/a   0.23    206.83    264.15    0.22    0.63    3.96    205.46    1.23    380.30    1420.82    0.64    92.90    1.31    0.09    1.14    1.38    20.79    9.47 

 

Note: ND = Not Detected. Limits of detection are the following: S: 0.038 ppm; Ba: 0.001 ppm; Y: 0.000 ppm; Ce: 0.050 ppm; Li: 0.003; Na: 0.094. Summary statistics include only analyses above the limit of detection. The reported impurities are in oxide form.

 

  8-8

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 8.8

Liquids Matter ICP-OES Point B-1 70/140 Test Results

 

Sample  Hole  SiO2   S   Mg   Ni   Ba   Mn   Fe   Cr   Al   Ca   Cu   Ti   Sr   Y   Ce   Li   K   Na 
ID  ID  (%)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm)   (ppm) 
22167  Den-57-1   99.95    17.29    29.80    0.23    ND    0.47    64.85    1.65    232.92    64.31    0.46    4.23    1.04    0.05    5.31    0.42    29.87    ND 
22171  Den-84-1   99.92    16.07    32.97    0.68    ND    0.52    398.83    2.15    238.08    65.79    1.02    6.95    1.07    0.04    1.75    0.36    41.97    ND 
22175  Den-109-1   99.96    27.19    28.01    0.20    ND    0.41    66.00    1.26    216.15    50.84    0.24    2.79    1.03    0.04    3.99    0.42    23.51    ND 
22179  Den-115-1   99.93    18.98    28.53    0.21    ND    0.30    216.60    2.45    250.49    38.66    0.23    5.44    1.56    0.03    3.15    0.32    32.61    23.65 
22183  Den-130-1   99.96    17.52    26.83    0.23    ND    0.41    50.25    1.68    184.71    79.92    0.23    4.78    2.93    0.05    3.40    0.41    20.48    1.52 
22187  Den-134-1   99.92    20.50    66.89    0.35    ND    0.37    57.05    1.98    293.86    267.64    0.46    5.77    6.29    0.04    4.41    0.32    41.54    6.49 
22191  Den-143-1   99.96    19.68    24.97    0.23    ND    0.26    34.44    1.54    218.79    64.08    0.74    4.74    4.23    0.04    1.94    0.33    22.33    2.34 
22199  Den-189-1   99.95    23.86    36.31    0.56    0.01    0.35    63.47    1.77    226.94    94.83    0.21    2.53    2.94    0.04    1.54    0.26    31.95    12.98 
22207  Den-216-1   99.95    8.80    20.66    0.11    0.52    0.22    40.76    0.96    321.96    34.96    0.61    3.87    3.04    0.06    3.94    0.80    18.74    1.25 
22219  Den-304-1   99.90    ND    68.66    0.22    0.70    0.52    97.65    1.28    611.82    119.10    0.12    5.32    3.16    0.07    2.60    0.89    88.54    6.86 
22223  Den-147-1   99.95    ND    28.26    0.30    0.77    0.37    64.30    1.51    273.49    64.92    0.39    6.32    4.70    0.04    2.07    ND    21.13    ND 
22227  Den-150-1   99.96    ND    30.53    0.29    0.37    0.41    81.36    1.48    223.49    53.43    0.62    6.04    1.84    0.05    2.91    ND    20.30    ND 
22231  Den-269-1   99.92    ND    34.72    0.34    1.11    0.75    145.42    1.46    489.39    75.29    0.71    7.15    3.11    0.06    3.18    0.57    21.25    ND 
22235  Den-319-1   99.90    ND    34.46    0.29    0.66    0.44    164.62    1.41    742.63    58.40    0.51    6.50    2.47    0.05    2.47    1.28    23.69    ND 
22239  Den-128-1   99.95    ND    40.22    0.26    0.75    0.45    72.28    1.10    241.60    110.86    0.57    3.77    1.19    0.05    2.37    ND    39.37    ND 
22243  Den-193-1   99.96    ND    37.29    0.26    0.79    0.24    41.96    1.81    244.30    61.30    0.56    7.61    3.24    0.07    3.35    ND    24.26    11.15 
22247  Den-226-1   99.90    11.02    29.94    0.80    0.93    0.50    64.96    2.21    785.18    93.75    0.83    8.44    2.88    0.09    2.63    1.74    19.30    ND 
22251  Den-240-1   99.90    ND    39.36    0.29    0.87    0.53    67.56    1.32    780.69    114.21    0.55    7.58    2.55    0.07    2.30    1.91    18.90    ND 
22255  Den-245-1   99.91    ND    22.70    0.35    0.53    0.25    42.64    1.33    806.56    46.90    0.44    3.92    2.29    0.04    2.26    1.94    7.60    0.71 
22259  Den-318-1   99.64    23.54    76.95    0.34    0.90    1.72    112.97    2.47    1066.56    2211.47    0.74    6.01    2.96    0.13    2.78    3.06    47.34    8.31 
Count  n/a   20    11    20    20    13    20    20    20    20    20    20    20    20    20    20    16    20    10 
Min  n/a   99.64    8.80    20.66    0.11    0.01    0.22    34.44    0.96    184.71    34.96    0.12    2.53    1.03    0.03    1.54    0.26    7.60    0.71 
Max  n/a   99.96    27.19    76.95    0.80    1.11    1.72    398.83    2.47    1066.56    2211.47    1.02    8.44    6.29    0.13    5.31    3.06    88.54    23.65 
Mean  n/a   99.92    18.59    36.90    0.33    0.69    0.47    97.40    1.64    422.48    188.53    0.51    5.49    2.73    0.05    2.92    0.94    29.73    7.53 
Std Deviation  n/a   0.07    5.42    15.61    0.17    0.28    0.32    84.71    0.43    271.09    478.76    0.23    1.65    1.32    0.02    0.95    0.82    16.98    7.10 

 

Note: ND = Not Detected. Limits of detection are the following: S: 0.038 ppm; Ba: 0.001 ppm; Y: 0.000 ppm; Ce: 0.050 ppm; Li: 0.003; Na: 0.094. Summary statistics include only analyses above the limit of detection. The reported impurities are in oxide form.

 

  8-9

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

  8-10

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

  8-11

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

  8-12

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

  8-13

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

  8-14

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

  8-15

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

9DATA VERIFICATION

 

9.1Site Visit and alignment on Field Procedures and Sampling Protocol

 

A Stantec professional geologist assisted with and oversaw the portion of the program involving collection of the field data, sample collection, and the implementation of chain-of-custody documentation during sample shipment. To streamline the program, the Stantec professional geologist conducted a site visit to the Property on September 25 and 26, 2018, which was at the time that the Sio Silica field personnel were drilling DEN 57-1; the first 2018 hole. The timing of this site visit provided the professional geologist the opportunity to align with the Sio Silica field crew on program procedures, as well as to instruct the drilling crew on the required rate of drilling to facilitate sample collection.

 

On June 10, 2022, the QP visited the Sio Silica’s laboratory in Calgary, Alberta, to review the laboratory equipment, and protocols with Sio Silica personnel. The Sio Silica laboratory is used to process the sand to a product that represents “market ready” sand. The process flow includes sample compositing, drying and sieve analysis. The Sio Silica lab is equipped with a magnetic separator to remove iron contaminant particles. It is the QP’s opinion that Sio Silica’s laboratory equipment, procedures, processes and personal are adequate for the performed analytical work. The QP requested that sieve tests on the retained samples that have been analyzed in AGAT laboratory be analyzed in Sio Silica’s lab to ensure consistency and accuracy of the results generated in the Sio Silica’s laboratory.

 

In 2022 and 2023 Sio Silica used Liquids Matter laboratory to perform multiple ICP analyses. On June 10, 2022, the QP conducted a laboratory visit at Liquids Matter facility in Calgary, Alberta. Liquid Matter is an independent testing facility, and a member of the Professional Chemists of Alberta. It is the QP’s opinion that Liquids Matter’s laboratory equipment, procedures, processes and personal are adequate for the performed analytical work.

 

On January 25, 2023, the QP conducted a site visit on the Property. All of the drill hole sites were rehabilitated. The drill hole location of the monitoring well was validated. The sample storage facility was also visited.

 

9.2Sample Chain-of-Custody and Laboratory Results

 

9.2.1Chain-of-Custody

 

All 2018 samples shipped to AGAT were sent from Steinbach, Manitoba to Calgary, Alberta by Purolator. The courier receipts were reviewed by Stantec to verify the shipment dates. Table 9.1 summarizes the date the samples were sent and received by AGAT.

 

  9-1

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Table 9.1

2018 AGAT Sample Chain-of-Custody

 

Hole Name  Samples  Hole Spud Date  Sample Shipment Date  Date Samples Received
DEN 57-1  14601-14617  September 24, 2018  September 26, 2018  September 27, 2018
DEN 84-1  14728-14737  November 23, 2018  January 11, 2019  January 14, 2019
DEN 109-1  14902-14919  November 27, 2018  January 21, 2019  January 23, 2019
DEN 115-1  14694-14711  October 23-25, 2018  November 1, 2018  November 5, 2018
DEN 130-1  14677-14693  October 17-19, 2018  November 1, 2018  November 5, 2018
DEN 134-1  14779; 14763-14778;
14798-14799
  November 21, 2018  January 21, 2019  January 23, 2019
DEN 143-1  14712-14726  October 29-31, 2018  November 1, 2018  November 5, 2018
DEN 178-1  14921-14934  November 28, 2018  January 21, 2019  January 23, 2019
DEN 189-1  14963-14979  November 12, 2018  January 16, 2019  January 18, 2019
DEN 209-1  14953-14961  November 22, 2018  January 16, 2019  January 18, 2019
DEN 216-1  14780-14797  November 30, 2018  January 16, 2019  January 18, 2019
DEN 223-1  14750-14760  November 7, 2018  November 14, 2018  November 16, 2018
DEN 243-1  14631-14645  October 1, 2018  October 4, 2018  October 9, 2018

 

The five duplicate samples sent to Loring were hand delivered by a Sio Silica employee. A chain of custody was obtained with the signature of the receiver at Loring on March 1, 2019.

 

The 2021 and 2022 drilling campaign follows the established sample shipment procedure. The QP did not review the shipment receipt but has no reason to believe that the established sample shipment procedures from previous years were not followed.

 

In 2022, UPS services were used to ship the sand samples from Winnipeg to Sio Silica’s laboratory in Calgary. The sand samples from Sio Silicas’ laboratory to Liquid Matter laboratory are hand delivered by a Sio Silica employee. The email tracking system between Sio Silica and Liquid Matter, as well as the UPS tracking sheets have been reviewed by the QP.

 

The QP’s opinion is that the sample handling and sample security approach is adequate for this type of commodity.

 

9.2.2Laboratory Results

 

The results from the different laboratories were compared to ensure consistency of the analytical data. The sieve results by fraction between AGAT and Loring laboratories on the analyses of the 2018 duplicate samples are compared and shown in Figure 9-1.

 

In 2022 and 2023 Sio Silica conducted sieve analysis in the Sio Silica laboratory. To ensure consistency of the analytical data, samples tested in AGAT laboratory are tested in Sio Silica’s laboratory as well. The result of the comparison is shown on Figure 9-2.

 

Additional sample results from the BRU property tested in AGAT and Sio Silica laboratories were also compared to evaluate the consistency of the analytical data received from these laboratories. The result of the comparison is shown on Figures 9-3.

 

Based on this comparison presented in Figures 9-1 and 9-2 the QP has concluded that the sieve results for the sand analysed by Loring and Sio Silica laboratories have an acceptable level of accuracy and consistency.

 

  9-2

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

  9-3

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

  9-4

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

  9-5

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

10MINERAL PROCESSING AND METALLURGICAL TESTING

 

This Technical Report Summary does not include a discussion of mineral processing and metallurgical testing. However, Section 8.3.2 provides details on the bench scale procedures, developed by Sio Silica, for further purification of raw sand samples from the DEN Property and generate market ready sand product.

 

  10-1

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

11MINERAL RESOURCE ESTIMATES

 

The estimates presented below have been prepared in accordance with the requirements of the SEC S-K 1300 Regulations. The geologic model construction, resource estimation approach, criteria and assumptions taken into consideration during this resource estimation are outlined in the following sub-sections.

 

11.1Computer Model Construction

 

The geologic resource model was developed using Hexagon Mining’s geological modeling and mine planning software, MinePlan® version 15.80-7. MinePlan® (also known as MineSight) is widely used throughout the mining industry for digital resource model development. Hexagon Mining’s suite of interpretive and modeling tools is well-suited to meet the modeling requirements for the Property.

 

A gridded-surface modeling approach was used to evaluate and calculate resource estimates for the Carman Sand Member located within the Property. The 3D gridded-surface model consists of laterally contiguous cells (commonly called grids). The selected grid size is determined by the density of the drill hole data and extent of the property. The grid size for this assessment was 50 m x 50 m (x, y). Each grid has a fixed position of easting and northing within the model limits and contains a list of variables or numeric identifiers, such as the lithology thickness, percent of each sand fraction (product), and other pertinent information.

 

11.1.1Topographic and Lithological Horizons

 

Topography data was downloaded from the Natural Resources Canada website in Canadian Digital Elevation Model (CDEM) format, spatial resolution is 0.75 arc seconds. These datasets were converted into a gridded-surface file within MinePlan®.

 

Based on the drill hole information, the surfaces representing the bottom of the first four lithological units in stratigraphic order were created: bottom of the Diamicton, bottom of the Carbonate (Red River Formation), the bottom of the Upper Shale (Red River Formation) and the bottom of the Carman Sand Member.

 

Elevation values were calculated at each drill hole location representing the bottom of the Diamicton, as well as the bottom of the Upper Shale (or the top of the Carman Sand Member). These elevation data were then used to create triangulated surface utilizing the “Implicit Modeler” tool in MinePlan®. The MinePlan’s “Implicit Modeler” tool uses a radial basis function interpolation algorithm. The triangulated surfaces were then converted into gridded surfaces.

 

The thickness of the Upper Shale was calculated based on the drill hole data. These calculated vertical thicknesses were used to create an isopach gridded surface of the Upper Shale using Inverse Distance Weighted algorithm with power of 2 (IDW2). The isopach gridded values of the Upper Shale were added to the elevation values of the bottom of the Upper Shale gridded surface to construct the elevation of the bottom of the Carbonate.

 

  11-1

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

An isopach gridded surface of the Carman Sand Member was created using the vertical thickness value from the drill holes. The bottom of the Carman Sand Member was constructed by subtracting the interpolated isopach values of the Carman Sand Member from the elevation values of the bottom of the Upper Shale gridded surface.

 

11.1.2Assay Data Compositing and Interpolation

 

Sieve-derived laboratory data from the Carman Sand samples was used to create two sand size fraction (product) weight percent values: 40/70 and 70/140. For each sand product, a length weighted composited percent value was calculated for each drill hole. An IDW4 interpolation was used to calculate each weight percent product for each model grid. Figure 11-1 shows the 40/70 fraction distribution map and Figure 11-2 shows the 70/140 fraction distribution map.

 

The ICP-OES tested samples were composited samples of the entire Carman Sand Member interval for each drill hole, so no additional compositing was required prior to interpolating the data into the model grids. An IDW4 interpolation was used to calculate SiO2, Fe and Al value for each model grid. The interpolation results are shown in Figures 8-1 through 8-4.

 

11.2Resource Estimation Approach

 

Stantec used the following approach to facilitate the estimation of resources:

 

Carman Sand unit thickness was estimated using all drill holes as discussed in Section 7

 

During the modeling process, the variations in the elevation of the top of the carbonate surface, caused by geological undulations and data collection inconsistencies in drill holes from GIN, were accounted for through application of a modeling methodology that averaged the elevation values over an area slightly larger than one quarter section (500m)

 

Percentages of the different sand fractions were used in the constructed geological model as provided from the laboratory

 

MinePlan® Software was used to construct a 3D geological computer model of the property to estimate in-place resources. The modeled gridded surfaces for top and bottom of the Carman Sand unit were used for volume estimation

 

Volumes were converted to tonnage by the application of a representative average bulk density value of 1.5 g/cm3

 

The geological interpretations and the modeled volumes as well as the relationship between the model and the raw data were confirmed through cross-sectional review and statistical model validation

 

This resource estimation only includes extractable sand volumes calculated using the criteria shown in Table 11.2, which are based on the geotechnical analysis discussed in Section 11.4

 

This resource estimation only includes those in-situ sand volumes found within the mining claims boundaries as shown on Figure 3.2

 

The drill hole spacing, the available assay data, and resource spatial distribution were considered in the resource classification

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

11.3Mineral Resource Classification

 

SEC S-K 1300 Regulations are aligned with the Committee for Mineral Reserves International Reporting Standards (CRISCO, 2019) that defines a Mineral Resource as: “A Mineral Resource is a concentration or occurrence of solid material of economic interest in or on the Earth’s crust in such form, grade or quality and quantity that there are reasonable prospects for eventual economic extraction. The location, quantity, grade or quality, continuity and other geological characteristics of a Mineral Resource are known, estimated or interpreted from specific geological evidence and knowledge, including sampling. Mineral Resources are subdivided, in order of increasing geological confidence into Inferred, Indicated and Measured categories.”

 

The CRISCO definition for a Mineral Resources clearly outline that a solid material is considered a resource if there is clear identification of the economic interest in the deposit. For sand deposits this means that the nature of the database, technology for mining and mine planning, some degree of practical recovery constraints and the economic potential in current markets must be considered in order to identify a sand resource.

 

Resources are classified according to the confidence level that can be placed in each estimate. The classification template used in this study is based on the three-dimensional distance to the nearest drill hole that penetrates the top and the bottom of the Carman Sand, as well as the distance to the nearest sample that contains sieve-derived laboratory data.

 

The Carman Sand interval in the Property was classed as Indicated using a 1,600 m radial distance from the nearest drill hole intersection with available sand quality data and classed as Inferred using a 3,200 m radial distance from the nearest drill hole intersection with or without available sand quality data. Only drill holes listed in Section 7.2 and Section 7.3 were used for resource classification. Due to the reduced reliability of the water-wells described in Section 7.1, this data was only used to define the contacts of the lithological units.

 

Figure 11-3 shows the resource distribution map and Figure 11-4 shows the resource classification map. The resource estimate covers an area of approximately 29,600 ha.

 

11.4GEOTECHNICAL Analysis

 

In January 2022, Stantec completed a geotechnical stability analysis related to the development of voids resulting from the sand extraction process at the BRU Property. This analysis was presented to Sio Silica in the report “Geotechnical Analysis for Sio Silica Extraction Project” (Stantec 2022).

 

A similar program of geotechnical sampling and analysis has not yet occurred for the DEN Property. Utilizing the most recent DEN geological interpretation and the results of the BRU geotechnical analysis, Stantec’s geotechnical engineers completed a preliminary high-level analysis of the DEN conditions, and these results were used to inform the current resource estimate. Stantec notes that this geotechnical analysis, and the resulting resource estimate is highly dependent on the DEN site specific geotechnical conditions. Additional geotechnical analysis and assessment is required to confirm cavity behavior, the structure and strength of the limestone caprock, the movement of water in around the extraction voids, the safe distance between adjacent cavities, the range of possible failure modes and other geotechnical conditions.

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

There is a potential that further geotechnical assessments may impact the current resource estimate, either positively or negatively.

 

It is important to note that the Stantec geotechnical assessment for BRU was reviewed by 3rd party experts from AECOM and Arcadis who generally agreed with the results, conclusions and recommendations, and recommended additional investigations and analysis for the next stage of the geotechnical design.

 

11.5Assessment of Reasonable Prospect for Eventual Economic Extraction

 

The results of this Technical Report Summary indicate a positive economic outcome related to the potential development of a silica sand extraction and processing operation for the DEN Property.

 

As such the QP believes the DEN Property continues to demonstrate a reasonable prospect for eventual economic extraction.

 

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11.6Estimation of Sand Volume

 

The modeled volumes and weight of the Carman Sand within the resource area are shown in Table 11.1.

 

Table 11.1

 

Summary of In-Place Carman Sand

 

   In-Place Carman Sand Member in
Mineable Lease Area
 
DEN Property  40/70 mesh
fraction
   70/140 mesh
fraction
 
Estimated Sand Volume (Mm3)   4,910    2,532 
Total Estimated Sand Volume (Mm3)   7,442 
Estimated Sand Weight (Mt)   7,365    3,798 
Total Estimated Sand Weight (Mt)   11,163 

 

The sand weights by fraction that are shown in Table 11.1 are not resources, as it is not technically feasible to produce the entire sand volume using the proposed extraction methods. The extractable sand volume and resource estimates are discussed in Section 11.6.

 

11.7Mineral Resource Estimation

 

Sio Silica plans to develop the DEN Property using an underground extraction technique that involves drilling through the quaternary sediments, a carbonate unit and shale, into the underlying sand. The extraction holes will be cased 5 m into the sand and an extraction casing is then lowered into the sand. Air is injected into the extraction casing through the drill string, approximately 3 m - 5 m above the bottom of the extraction casing. Field tests have shown that the air injection process results in a slurry of sand, water, and air that rises to the surface.

 

In previous resource estimates for the DEN Property Stantec utilized a minimum 15 m carbonate unit thickness as a cut-off along with a 5.6% recovery factor. This methodology was based on initial geotechnical assessments along with an initial understanding of how voids might develop during the sand extraction process.

 

Preliminary geotechnical analysis for the DEN property has resulted in the extraction recommendations as summarized in Table 11.2. The extraction holes are planned to be drilled in a pod or cluster of up to thirteen holes in one extraction pad area. The current planning basis is to extract between 1 K and 33 K tonnes of sand from an extraction cluster, depending on the thickness and structural integrity of the overlying limestone and diamicton material, before relocating to the next extraction pad.

 

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Table 11.2

 

Sand Extraction Recommendations

 

Competent
Limestone
Thickness (m)

 

Quaternary
Material Thickness
(m)

 

 

Extractable Sand
Volume (m3)

 

 

Extractable Sand
Mass (t)

 

Distance Between
Well Clusters (m)
(Center to Center)

>50  0-65  36,156  54,235  127
>50  >65  34,674  52,012  126
45-50  0-55  33,224  49,836  125
45-50  55-65  29,061  43,591  122
45-50  >65  27,736  41,603  121
40-45  0-45  29,061  43,591  122
40-45  45-55  26,442  39,663  120
40-45  55-65  23,949  35,924  118
40-45  >65  21,582  32,373  116
35-40  0-45  22,750  34,125  117
35-40  45-55  20,446  30,669  115
35-40  55-65  17,225  25,837  112
35-40  >65  16,214  24,321  111
30-35  0-45  15,235  22,852  110
30-35  45-55  13,370  20,056  108
30-35  55-65  11,632  17,447  106
30-35  >65  10,809  16,214  105
25-30  0-25  15,235  22,852  110
25-30  25-35  12,485  18,728  107
25-30  35-45  10,018  15,028  104
25-30  45-55  8,531  12,796  102
25-30  55-65  7,169  10,754  100
25-30  >65  6,535  9,803  99
20-25  0-25  9,259  13,888  103
20-25  25-35  7,169  10,754  100
20-25  35-45  5,362  8,043  97
20-25  45-55  4,822  7,234  96
20-25  55-65  3,838  5,757  94
20-25  >65  3,392  5,089  93
15-20  0-25  4,314  6,472  95
15-20  25-35  2,979  4,468  92
15-20  35-45  2,245  3,368  90
15-20  45-55  1,925  2,888  89
15-20  55-65  1,379  2,069  87
15-20  >65  1,379  2,069  87

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

These extraction recommendations have been utilized to update the mineral resource estimate. Table 11.3 shows the estimate of the mineral resource for the Property as of February 21, 2023.

 

The mineral resource shown in Table 11.3 is reported as in-place tonnages. The calculated volumes were converted to tonnage by the application of representative average in-place bulk density value of 1.5 g/cm3.

 

Table 11.3

 

In-Place Mineral Resource Summary

 

   Mineral Resources (Mt) 
DEN Property  40/70 mesh fraction   70/140 mesh fraction   Total 
Measured   0.0    0.0    0.0 
Indicated   55.8    32.6    88.4 
Total Measured and Indicated             88.4 
                
Inferred   169.8    82.9    252.7 
Total Inferred             252.7 

 

The 40/70 and 70/140 size fractions were assessed during the preparation of this report, as some silica sand markets have preference on the product grain size.

 

The accuracy of resource estimates is, in part, a function of the quality and quantity of available data and of engineering and geological interpretation and judgment. Given the data available at the time that this Technical Report Summary was prepared, the estimates presented herein are considered reasonable. However, this estimate should be accepted with the understanding that additional data and analysis available after the date of the estimates, may necessitate revision. These revisions may be material. There is no guarantee that all or any part of the estimated resources will be recoverable.

 

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12MINERAL RESERVE ESTIMATES

 

This Technical Report Summary does not include an estimate of reserves. The level of engineering does not support the preparation of a Pre-Feasibility Study; therefore, in accordance with the requirements of S-K 1300, the reported resources cannot be classified as reserves.

 

This section of the report includes estimates of recoverable sand tonnage for the DEN Property based on preliminary extraction plans, production schedules and processing plant and materials handling plans. These estimates are only intended for the purpose of completion of the cash flow forecasts presented in Section 19. These recoverable estimates are not, and should not be construed to be, estimates of reserves for the DEN Property. They do not comply with the Classification of Reserves as required under S-K 1300. It should be noted that there is no certainty that the resource estimate will be realized.

 

12.1Development Plan

 

The 25-year development plan, that is discussed in more detail in Section 13, results in the sale of 2.72 Mt of clean (saleable) sand each year, totaling 65.4 Mt over the life of the project. Stantec notes that the 25-year development plan only addresses a portion of the DEN Property resource. The remaining resource is available for development in further planning efforts.

 

This estimate of clean (saleable) silica sand is considered to be inclusive of the in-place mineral resource estimate detailed in Section 11. These production estimates are contained within the in- place mineral resource summary and cannot be added to the totals to result in additional resources tonnes.

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

13MINING METHODS

 

13.1Overview

 

Sio Silica plans to develop the DEN Property using an underground extraction technique that involves drilling through the quaternary sediments, carbonate unit and shale, into the underlying sand. The extraction holes will be cased to the top of the sand and an extraction casing is then lowered into the sand. Air is injected into the extraction casing, approximately 3 m - 5 m above the bottom of the casing. Field tests at the BRU Property have shown that the air injection process results in a slurry of sand, water, and air that rises to the surface. The solids content of the slurry ranges from 90% to 20% during the extraction trials. The average solids content is approximately 50%.

 

The extraction holes are planned to be drilled in a pod or cluster of up to five holes in one extraction pad area. The current planning basis is to extract approximately 3,000 to 55,000 tonnes of sand from the extraction cluster before relocating to the next extraction pad.

 

Once the slurry reaches the surface, initial processing will remove any oversize or deleterious material such as sand concretions, shale, or chert before it is transported by an overland slurry pipeline to the wet process facility for further processing.

 

Following wet processing the sand will be stockpiled and fed into a drying and sizing plant where the sand will be separated into saleable fractions and then stored in loadout silos prior to being loaded onto trains for distribution.

 

Sio Silica plans to commence extraction operations in the 2nd Quarter of Year 0, processing operations in the 3rd Quarter of Year 0 with the first product sales planned for the 1st Quarter of Year 1. The extraction and processing operations are planned to take place for eight months a year, April to November, while sales will take place year-round. The sales will commence with 2.72 Mt of saleable product planned in Year 1 and extending out the remainder of the 25-year plan. For the purposes of this Technical Report Summary, Year 0 is defined as 2026.

 

13.2Geotechnical Analysis

 

Stantec completed a preliminary geotechnical analysis of the sand extraction techniques impact on subsurface conditions. The results of the analysis are used to provide recommendations for borehole spacing which are intended to limit surface subsidence to an acceptable level.

 

The preliminary analysis assumes that the shear failure of the Limestone caprock which overlies the sand is the most likely controlling failure mechanism. The analysis incorporated results from geotechnical tests conducted on the overlying Limestone (carbonate unit) as the performance of this unit was considered to be the governing factor in the analysis. The tests concluded that the carbonate unit has an average Geological Strength index (GSI) of between 55 and 65. It is important to note that based upon site specific borehole drilling results, the caprock does not appear to contain extensive vertical fracturing, however drilling has been limited to vertical boreholes which may fail to identify the presence of vertical fractures. The diamicton thickness also controls the loading on the extraction cavity and should be considered in determining the extraction cavity hole dimension.

 

 

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The analysis also assumed that the sandstone unit is unconsolidated and after extraction would form a cone with an angle of repose of 31 degrees from the horizontal. Extraction testing by Sio Silica in 2018 and 2019 indicates that there is likely some amount of consolidation within the sandstone unit, perhaps in discrete layers, or perhaps throughout the unit. The extraction tests also infer that voids formed from the extraction process are more complex than a simple conical void with an angle of repose of 31 degrees. Sio Silica completed a sonar survey of one of the boreholes (BRU 92-2) after sand extraction in May 2021. The testing suggests that the extraction voids may be steeper and could have a cylindrical or spherical shape particularly in the short term after extraction. Inspection of other boreholes sometime after sand extraction shows that the voids backfilled with sand; however, to date the mechanism of change in the shape of the extraction voids and source of backfilled sand in the cavities are not well understood.

 

Sio Silica completed an acoustic borehole image (ABI) and an optical borehole imaging (OBI) of the Limestone cap rock in borehole BRU 92-1 in March 2021. The ABI/OBI survey identified horizontal bedding and joints in the cap rock with no continuous orthogonal (vertical) joints. This and other boreholes are drilled vertically so there is potential for missing vertical or near vertical joints. Although some cross-bedding joints were identified in the survey, they are limited to a fractured zone potentially in Shale.

 

Sio Silica also completed surface surveys in the vicinity of the BRU 92-2 and BRU 92-3 (survey points at 5 m to 13 m distance from the boreholes) before and after sand extraction to measure possible resultant subsidence. Surface surveys showed subsidence close to the precision of the survey (1 mm vertical and 1 cm horizontal) due to sand extraction from BRU 92-2 and BRU 92-3 (with single hole arrangement). No test was completed with multi-hole arrangements.

 

The preliminary analysis indicates that:

 

Subsurface sand extraction should be limited to areas where the carbonate unit is more than 15 m in thickness.

 

The analysis here assumes an overburden thickness of up to 25 m. Overburden thicker than this range should be reviewed case by case to assess potential for subsidence to occur following extraction.

 

The distance from the edge of one extraction void to the edge of the next extraction void should not be less than 60 m.

 

The extraction layout was developed with these geotechnical criteria in mind. The author(s) would like to note that these geotechnical parameters and the resulting geotechnical analysis are based on geotechnical work completed for the Limestone caprock and assuming that the controlling failure mode is shear failure. Additional testing is recommended to support further analysis on the sandstone void space evolution, and the joint system in the limestone (to investigate for the possible presence of vertical jointing and if found, to assess its impact on stability). As stated above, evidence from testing in 2018/2019 suggests that the sandstone angle of repose is steeper than previously assumed, and related adjustments of the extraction plan which would lead to a more refined extraction layout might be required. In addition, more complex void shapes in the sandstone may be occurring with both steep and shallow side slopes.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

As a result of the minimum 15 m cut off for the thickness of the limestone to support overburden loading after sand extraction, and the additional potential for strength analysis on the sandstone layer, recommendations for further geotechnical investigation, testing and analysis will be discussed in the next section. The purpose of this additional assessment is to confirm the Limestone thickness in advance of mining operations, to test the (to date untested) presence of Limestone vertical fractures and the sandstone unit extraction void space and to confirm that other failure modes are not controlling the extraction void maximum size.

 

13.3Extraction Concept

 

Sio Silica conducted 14 extraction tests in the period from 2017 to 2021. The results of these tests indicate that it is reasonable to expect extraction tonnages of approximately 4,500 tonnes from a single extraction well. The current concept involves drilling a central extraction well, surrounded by up to 11 additional extraction wells, depending on the exact geotechnical conditions of the specific area. The spacing of these wells would be approximately 15-20 m from the centre of one drill hole to the centre of the next well. These seven wells would form one extraction cluster or extraction pad where approximately 3,000 to 55,000 tonnes of sand will be produced.

 

The current planning basis utilizes relatively small-scale truck mounted drilling equipment to drill the extraction wells and to set the initial casing. Sio Silica is planning to retrofit a fleet of smaller drill rigs to serve as the primary extraction rigs. These drills will be capable of advancing the extraction casing into the sand unit, applying the necessary air to facilitate the air lifting of the sand slurry, and distributing the sand slurry to surface facilities central to the extraction cluster. These facilities would include the initial processing discussed above as well as mixing with water as required to achieve the appropriate solids content to facilitate overland slurry transport to the final process facilities.

 

A relocatable shack will be located at the extraction pad and will serve as a central control facility for the operating extraction wells, the initial processing, and sand slurry mixing and pumping.

 

The extraction process is planned to take place for eight months a year, April to November inclusive. During this time enough sand will be produced to supply the drying and sizing plant with enough product to operate on a year-round basis. This concept was developed to minimize the difficulties with operating a slurry system and wet process facility in the winter months.

 

13.4Surface Development and Reclamation

 

The planned production discussed above will require the surface development of approximately 290 ha in Year 0, and averages 200 ha in Year 1 and until the end of the 25 year plan. Figure 13.1 illustrates the proposed surface development plan for the DEN property development. This development plan includes offsets from existing road infrastructure, high voltage transmission lines, and residential areas. Please note this development plan is subject to change as extraction progresses.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

The land area required for development will be leased from the current owners for a total of three years. Land required for any specific production year will be leased the prior year. In this manner any pre-production development such as tree clearing/mulching, access road development, slurry pipeline layout, and extraction well drilling will take place one year in advance. In the year following the extraction season, closure and reclamation activities will take place. These activities will include extraction well abandonment, removal of all remaining infrastructure such as slurry and return water piping, and reclamation that is expected to include minor levelling, discing, and seeding to grass.

 

13.5Slurry Transportation

 

Once the sand slurry reaches the surface and has undergone the initial treatment for the removal of oversize and deleterious materials, water will either be added to or removed from the slurry until it reaches the appropriate solids content for slurry transportation. Sio Silica will employ a network of high-density polyethylene (HDPE) pipe to transport the slurry overland to the main process facilities. In the early years of production this overland distance is between three and four km however it grows to approximately 15 km in the latter years of the project. The first stage slurry pumps will be located at the extraction pad. As the overland distance increases, booster pumps will be located as required along the route. The slurry transportation system has been designed to operate at approximately 25% solids. This allows the slurry process to be stopped and then restarted without having to empty the pipeline.

 

Once the slurry reaches the main process facilities it will be piped directly into the wet process facility for further treatment. As discussed, the extraction, slurry transport and wet process facilities will be operational 8 months of the year.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

14PROCESS AND RECOVERY METHODS

 

Details related to the process and recovery methods utilized for the DEN Property have been assumed to be similar to methods developed for the BRU Property.

 

The processing component of the DEN silica operation is guided by a modular and multi-stage recovery process. The four general areas are:

 

A modular well pad screening and dewatering plant for slurry preparation;

 

A dewatering circuit or ‘wet plant’ for raw sand separation;

 

A dry screening plant for final sizing and beneficiation; and

 

The storage and loadout system.

 

14.1Well pad screening circuit

 

The well pad screening circuit is a modular and relocatable system situated at a well pad. Each screening unit is comprised of a series of sumps, screens, and cyclones to ensure the overland slurry transport pipeline is properly fed in terms of size and slurry concentration. The operation is anticipated to have multiple units and several parallel trains of each unit. The units are identified alphanumerically, with a numeral for each unit, e.g. SUW1 identifies the number one (1) Sump (SU) at the well pad (W). A letter identifies one of the two trains, either A or B train. The well pad process is generally as follows:

 

Incoming slurry from extraction is delivered to a two deck 6’x16’ protection screen resting atop at sump; overs from the screen are anticipated to be minimal and will be mainly various cobbles and conglomerates. Screen unders are collected in the sump and pumped to a three-part collection sump in the dewatering plant. The three-part collection sump comprises the initial step of the well pad dewatering plant, allowing the fines and sand to settle and thicken and the water to decant from the initial dilute slurry feed. The settled or thickened solids are pumped to feed a series of 20” cyclones, separating again the ultrafines and gravels. Overflow from the cyclones is recycled to the three-compartment sump for a closed loop circuit; underflow from the cyclones feeds a pair of dewatering screens in series. The sand is then prepared for overland slurry transport in the collection sump. Makeup water is added, diluting the slurry to 28% solids, and pumped to the wet plant.

 

Table 14.1 summarizes the key process equipment for the well pad and dewatering plant up to the overland slurry transport.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Table 14.1

 

Key Process Equipment – Well Pad and Dewatering Plant

 

Item   Identifier (# and train)   Notes/Capacity
Sump, Well pad   SUW1/2/3/4/5 A&B    
Sand Screen   SCW1/2/3/4/5 A&B   6’x’16’ DD
Sand transport pump   PW1/2/3/4/5 A&B   4x6 60 HP
Three compartment sump   SU02 A&B    
Return water pump to well pad   PW1/2/3/4/5 A&B   4x6 40 HP
Transport pump, DW plant   P02 A&B   12x14 250 HP
Sand Cyclone   CY2-1/2/3/4 A&B   20” Krebs GMax
Dewatering Screen   SC02-1/2 A&B   Tabor 8’x12’ SD
Collection sump   SU03 A&B    
Overland transport pump   P03 A&B   8x10 250 HP

 

Generally, the well pad circuit components from the initial sumps SUW 1/2/3/4/5 A&B and the well pad dewatering plant SU02 A&B through P03 A&B are anticipated to be in close vicinity to one another to facilitate inter-operability of allocated infrastructure. The return water pump and sand pumps are designed for approximately 1,500’ radius to allow some flexibility if required.

 

Overland transport pumps are intended to be staged on 3,000’ intervals. As the extraction process progresses further from the wet plant or additional head is encountered due to changing conditions, another booster pump arrangement is required. Preliminary designs indicate 14DR11 piping for the overland slurry transport.

 

14.2Wet Plant

 

The wet plant receives the incoming slurry from the overland piping system. Similar to the dewatering plant, a three-part collection sump comprises the initial step of the wet plant, allowing the fines and sand to settle and thicken and the water to decant from the initial dilute slurry feed. The settled or thickened solids are pumped to feed a series of 20” cyclones in this case serving as dewatering and thickening cyclones. Overflow from the cyclones is recycled to the three- compartment sump and then to the clarifier; underflow from the cyclones feeds a pair of dewatering screens in series. Underflow from the screens returns to the three-compartment sump. Screen deck discharge is collected via conveyor to be stockpiled in the WIP pile. Cyclone underflow can also be diverted processing by wet high intensity magnetic separation (WHIMS) units, by Eriez, to reject the weakly magnetic and ferrous metal inclusions. The rejected material is collected and separated in a separate stream, with the remaining siliceous sand continuing forward to the WIP pile.

 

A fines thickener receives slurried fines from the cyclone overflow via the three-compartment sump. Based on the preliminary sizing, the deep cone thickener will settle the dilute fines entrained in the cyclone overflow, producing a thickened slurry. The slurry will be further dewatered by a pair of 2,000 mm plate presses in batch parallel mode, to provide sufficient capacity for the anticipated full throughput and to dewater to a handleable cake. Fines are handled by front-end loaders (FEL) to remove the produced cakes; clarified overflow will be recycled to the slurry transport system from the wet plant thickener and plate press system.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Wet plant key process equipment is identified in Table 14.2.

 

Table 14.2

 

Key Process Equipment – Wet Plant

 

Item   Identifier (# and train)   Notes/Capacity
Three compartment sump   SU04 A&B    
Return water pump to well pad   PO 5 A&B   10x12 125 HP
Transport pump, Wet plant   P02 A&B   10x12 250 HP
Sand Cyclone   CY4-1/2/3/4 A&B   20” Krebs GMax
Dewatering Screen   SC04-1/2 A&B   Tabor 8’x12’ SD
Collection Conveyor   C101/102/103    
Thickener/Clarifier   THK101   36’ dia. Deep cone.
Mud Tank   MT101    
Filter Press Sump Pump   SP102    
Plate press   PP101/102   2,000 mm plate, 207 plates
Wet high intensity magnet   WM 101/102    

 

Figures 14.1 through 14.6 illustrate the anticipated process flow sheets.

 

 

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14.3Dry Screening plant

 

Dry screening plant begins at the reclaim from the WIP pile. Raw sand is reclaimed from the WIP storage area via front end loaders and fed into a feed hopper with a vibrating grizzly feeder feeding an impactor to break any lumps or potentially conglomerated material while in the WIP storage area. A Louisville rotary dryer will drive off excess moisture, designed to take to nominally 2% moisture. The remaining dry plant is continued through bucket elevators to four parallel sets of Rotex sizing screens, for product sizing and separation prior to storage and loading operations. The key dry plant equipment is identified in Table 14.3.

 

Table 14.3

Key Process Equipment – Dry Plant

 

Item   Identifier (# and train)   Notes/Capacity
Vibrating Grizzly   VGF201   62”x24’ grizzly
Impactor   CR201   Lippman 5165 Impactor
Screen   C202   6’x20’ 3 deck screen
Rotary Dryer   DRY201    
Screening   SCR202 through 209   Rotex 5300 2 Deck screen

 

The dry plant is partially enclosed, with the dryer and main screens and sizing contained within a building structure.

 

14.4Storage and loadout

 

Storage and loading battery limits are fed by bucket elevators to four (4) of 3,000 tonne silos (each). These 100’ tall bolted silos are positioned to provide storage for the planned production in two independent trains of equal capacity. Each train of two silos is reclaimed via independent reclaim conveyors to two sets of two (total of four) rail loading batch silos. Each silo has 75 tonnes of capacity, allowing for a total of 150 tonnes of capacity on each loading track.

 

14.5Plant Design and Construction

 

Turnkey Process Solutions (TPS) has provided designs for the wet plant, dry plant, train loadout and the storage silos. TPS is experienced in plant specification, design and construction, and has worked with Sio Silica throughout the design process and engagement on the project.

 

TPS have developed plant simulations and models to assess the potential plant recovery. These models are based on TPS inspection of and analysis of the DEN project samples and historic test work. Based on this analysis, losses in yield have been accounted for as follows: 4% losses in extraction and wet handling and an additional 3% losses in drying and dry handling.

 

14.6Rail design and construction

 

The rail alignment has been developed by another design contractor, integrated with the Sio Silica team. Trans Energy Services has assessed the site to deliver potential rail services and initial track layouts. Initial concepts have been laid out for the dual loading systems and are laid out in the attached preliminary design schematics.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

15INFRASTRUCTURE

 

Details related to the infrastructure for the DEN Property have been assumed to be similar to the infrastructure required for the BRU Property.

 

15.1Rail

 

Rail designs were conceptualized by Trans Energy Services, an outside rail consultant contracted by Sio Silica to design an operating system for the rail operation. Generally, the design will interface with the existing Canadian Pacific (CP) line and is compliant with the current CP design specifications. The design includes track and sub-grade, sub-ballast, and a perimeter access and inspection road, all compliant to CP design specifications. The multi-loop design includes the capacity to store additional rail cars, or to adapt the operation to container-based loading with future expansion efforts.

 

15.2Power

 

Power to the extraction pad processing and booster pumps will be supplied by relocatable gensets, connected via feeder cables. Incoming power to the wet and dry plant is anticipated to connect to the nearest Manitoba Hydro lines. For the purposes of this report, a high voltage connection line of approximately 1 mile (1.6 km) was allowed for tie-in to the nearest high voltage connection. A substation, with step down transformer and control system, was provided to change to medium distribution voltage. An allowance was made for a power study with the local utility.

 

15.3Access

 

Site access is via local roads and highways. Considering that no local distribution of the final product is planned, the only access should be for Sio Silica workers, labourer’s, and vendors.

 

15.4Gas Line

 

Review of the available gas lines in the area indicate an approximate 22 km overland gas pipeline to provide the gas for the rotary dryer system at the Dry Plant. Stantec has allowed for the tie-in and construction of the line to the dry plant.

 

15.5Maintenance facility

 

A simple maintenance facility designed from arched fabric structures has been designed to allow all weather access and maintenance on mobile equipment. Commonly, these structures are developed with a concrete slab on grade, with a minor curb wall either of blocking or poured structure, to develop an enclosed working surface. The area is planned for mobile equipment maintenance, as well as maintenance on pumps, skids, or electrical equipment.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

15.6Offices

 

Office and lavatory space has been accounted for with three 24 ft x 60 ft units to house all site office and logistics, plus a single 12 ft x 32 ft lavatory trailer.

 

15.7Operations trailer

 

An operations trailer at the at the extraction well pad has been conceptualized to provide an operating center for the drilling, screening, pumping and overland pipeline system.

 

15.8Process water Well

 

Makeup water will be required at the plant site for initial startup and development. An allowance for one well at the plant site has been estimated.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

16MARKET STUDIES

 

16.1Introduction

 

Sio Silica is intending on producing high-quality premium silica sand for end use in the technology markets. The 99.9% SiO2 and low iron content (<100ppm Fe) are typically marketed to manufacturers of solar glass, smart glass for computing and mobile device applications, and semiconductors, among other uses, and receive a premium compared to 95% SiO2 purity. A confidential marketing study was completed by a third party, on behalf of Sio Silica, focused on the premium silica market and salient points are extracted from the study and discussed in further detail below.

 

16.2MARKETS/ DEMAND

 

The global market for silica sand is approximately 350 million tonnes per annum, with approximately three quarters of that total in North America (112 million tonnes) and Asia Pacific (154 million tonnes), as of 2021. The growth has historically been at a compound annual growth rate (CAGR) of 3.6% over the past five years. Of this global market, the high purity market consists of approximately 13 million tonnes per annum.

 

The North American market for high purity, low iron silica has been in the 1 million tonne per annum range historically through 2021 and is anticipated to grow to 2 to 3 million tonnes per annum by 2025, principally driven by the photovoltaic market and technology applications. The growth of PV solar glass is projected at 30% CAGR principally driven by improved economics through manufacturing and new legislation supporting domestic solar PV manufacturing. A 15% compound annual growth rate is projected for smart (technology) glass applications, based on similar regulatory reforms and increased adoption rates.

 

16.3COMPETITION

 

Supply of high purity quartz to the Asian market has traditionally been supplied via Vietnam and Cambodia. Both countries have scaled back exports to China to strengthen their local manufacturing, resulting in a supply shortage in the rest of Asia and therefore higher delivered prices. These higher prices have incented new mines in Australia, with as much as 10 million tonnes per annum potentially coming online by 2026. The anticipated growth in the high purity silica market has provided motivation to other potential sources of supply in Australia, according to the marketing report. It is anticipated that the supply from these to-be-developed proposed mines will require additional beneficiation, adding costs to the mine gate pricing. The timing and tonnage of this new supply and the level of the beneficiation, and associated costs, is uncertain. Australian mining companies are expected to be the primary exporter to China; however, it is unclear how much will materialize, according to the marketing study. In the future scenario, Australian mining companies may potentially have lower delivered costs compared to other international peers for solar glass applications, but will require beneficiation for smart glass applications, resulting in a higher delivered price.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

There are only two mines in the US today capable of providing low iron silica sand (99.9% SiO2, <100 ppm) totaling approximately 1 million tonnes per annum of supply. These two mines are:

 

US Silica mine in RockWood, MI. (0.45 Mtpa of production)

 

Covia mine in Junction City, GA. (0.55 Mtpa of production)

 

The risk of supply substitution for high purity markets is low. Recycled glass is only used for low purity applications. A very limited potential for quartz production of about 0.5 million tonnes per annum as byproduct of lithium production, although this stream is currently immature and will be subject to further verification and testing.

 

16.4CONTRACTS and POTENTIAL OFFTAKERS

 

According to the marketing study, typical contracts are two-to-three-year renewable contracts indexed to inflation, and identified with a specific purity, quality, and quantity. In a similar fashion, there are typically penalties for not meeting these criteria.

 

Sio Silica has provided Stantec with documents regarding product pricing agreements from three companies.

 

Agreement #1

 

The first document is a proposed sales and purchase agreement contract between Sio Silica and Company 1, that Sio Silica has indicated should be finalized in the fourth quarter of 2023. The document states a sales price of US$180 per MT FOB loading port for 500,000 MT per annum. When exchange rates and port and rail costs are considered, it equates to a mine gate price of CDN$149 per MT.

 

The initial term of this proposed agreement is from January 1, 2024 to December 21, 2026. Thereafter term of the agreement will be automatically renewed for an unlimited number of one (1) year terms unless terminated by either the buyer or the seller.

 

Agreement #2

 

The second document is a Memorandum of Understanding between Sio Silica and Company 2 and dated September 15, 2022. The document states a sales price of US$250 per MT FOB loading port for 800,000 MT per annum. When exchange rates and port and rail costs are considered, it equates to a mine gate price of CDN$240 per MT.

 

Both the buyer and the seller agree to use their best efforts to enter into a binding Sales Agreement in the first quarter of 2024.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Agreement #3

 

The third document is an engagement agreement between Sio Silica and Company 3 and dated November 1, 2022. The document states a sales price of US$200 per short ton FOB Mine Gate for 1,200,000 short tons per annum. The agreement also stipulates a service fee equal to 15% of the gross amount of the purchase price paid. When conversion to metric tonnes and the 15% fee are considered, it equates to a mine gate price of CDN$243.60 per MT.

 

The term of this agreement is unlimited unless terminated by either the buyer or the seller.

 

Product Pricing

 

Stantec used a weighted tonnage per annum price from all three agreements for the initial years of the analysis. A weighted tonnage per annum price for the last two agreements was used from 2030 until the end of the project life.

 

Product Quality

 

The first two agreements specify that the quality parameters for the delivered sand shall be a silicon dioxide (SiO2) percentage greater than or equal to 99.9% and Fe2O3 content less than or equal to 100 ppm.

 

It is the opinion of Stantec that given the results of the sand analysis discussed in Section 8, the sand pricing discussed above is applicable to the DEN Property resource and as such has been used in this Study.

 

Stantec does note, however, that confirmed sales agreements or contracts for the full levels of silica sand production that form the basis of this Study have yet to be finalized.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

17ENVIRONMENTAL STUDIES, PERMITTING AND PLANS, NEGOTIATIONS OR AGREEMENTS WITH LOCAL INDIVIDUALS OR GROUPS

 

Sio Silica has engaged AECOM to provide consulting support through the regulatory approval process.

 

The regulatory approval process for the adjoining BRU property has advanced significantly. Although the regulatory process for the DEN Property has not yet commenced, Stantec envisions that it will be materially similar to the BRU process. For further details please refer to the Technical Report Summary BRU Property Manitoba, Canada.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

18CAPITAL AND OPERATING COSTS

 

18.1Cost Summary

 

Cost estimates were prepared for the development and operation of the DEN Project. Unit costs are expressed as dollars/clean tonne, unless specified otherwise.

 

The cost estimates and resulting cash flow analysis were prepared in constant 2023 Canadian dollars (C$). The exchange rate of US$0.77 to C$1.00 was used for the project.

 

The following sources and approaches were used:

 

Extraction and slurry pumping costs were based on estimates prepared by Sio Silica. Wet plant processing, dry plant processing and associated equipment, screening plant, silos, and rail loading systems were developed by Turnkey Process Solutions (TPS). TPS likewise developed budgetary estimates for capital construction and installation costs.

 

Rail transportation costs were provided by CN.

 

Rail siding construction estimates were provided by Trans Energy Services, Sio Silica’s independent consultant and rail specialist. These are based on preliminary designs and development work completed by Trans Energy.

 

Other infrastructure and facilities estimates were compiled by Stantec based on vendor quotes, and discussions with Sio Silica.

 

Operating expenses were estimated by Sio Silica.

 

Labour costs, developed by Sio Silica, were based on knowledge of current labour agreements.

 

Management and staff salaries were estimated by Sio Silica, based on Stantec input on current mining salaries in Western Canada, and in consultation with Sio Silica on their anticipated burden.

 

Electricity rate for process facility operations provided by publicly available sources on Manitoba Hydro and through discussions between Sio Silica and the utility.

 

18.2Project Capital Costs

 

The methods and procedures used to develop the capital cost estimate are described in the following subsections. Project capital costs were sourced from various vendors, and from Stantec’s database of capital costs.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

18.2.1Capital Cost Summary

 

The capital cost summary for the DEN project extraction area is outlined in Table 18.1.

 

The DEN project has been developed to capture the 2.93 MTPA of insitu production, and requisite capital to extract, process, and load the product. The battery limits begin at extraction well pad, including well rigs, the overland slurry line initial pump stations, booster pump and through to the wet and dry plant, as well as the silos, rail, and supporting infrastructure.

 

It should be noted that no contingency is applied in the table.

 

Table 18.1

Capital Cost Summary – (C$), no Contingency

 

Area  Summary
Cost, (C$)
 
Extraction  $43.5M 
Wet Plant  $73.8M 
Dry Plant  $85.4M 
Rail and TLO  $36.3M 
Overland Slurry Pipeline Controls  $6.2M 
Infrastructure  $15.9M 
Engineering, Project Management & Permitting  $2.5M 
Total  $263.6M 

 

18.2.2Contingency

 

A 7% contingency has been applied to all capital cost items to account for any unforeseen or otherwise unanticipated cost elements that could be associated with development and operation of the project. Contingency for the DEN project totals $17.2M.

 

18.2.3Sustaining Costs

 

Sustaining costs are captured under the operating cost sections below including additional land, extraction wells, slurry line and booster pumps, and as well the plant repair and maintenance costs.

 

18.3Project Operating Costs

 

The project team developed the operating costs using construction lengths, land requirements, operating units, and process or dryer unit preliminary power and gas consumption. Areas of operating costs breakouts include:

 

Land leasing
   
Land prep and reclaim
   
Well Production
   
Slurry Transport
   
Wet Process
   
Support Equipment
   
Dry Process

 

 

18-2

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Loadout
   
Rail Costs
   
Manpower
   
General and Administration

 

The diesel fuel cost assumption is $1.59/litre. Propane gas costs are estimated at $0.38/litre propane. Natural gas is estimated at $0.188/m3. As well, the power costs from Manitoba Power are indicative rates based on preliminary verbal discussions. The estimated power rate is $0.045/ kW-hr.

 

18.3.1Land Leasing

 

Land Leasing costs are based on the mine development plan, shown earlier in this study. The developed hectares are considered for the projected extraction plan, and a lease cost of $0.22/t is applied based on work by Sio Silica.

 

18.3.2Land Preparation and Reclamation

 

Land prep and reclaim considers the mulching requirements for the area of the extraction development.

 

18.3.3Well Production

 

Well production is a function of tonnes produced, and the phase of the project. Typical well costs were provided by the Sio Silica team. Drilling costs per well were estimate by Sio Silica at $14,759 per well; abandonment costs are estimated at $3,352 per well; personnel costs are estimated at $10,430 per well. Extraction area processing is planned to operate approximately 203 days per year to allow for the seasonal operating conditions of the pipeline and extraction pads.

 

Slurry transport through overland piping is based on an initial pumpstation at or near the wellpad, then booster pumps added or removed to maintain the slurry line velocity and head. A buildup of slurry pipeline costs include an operator at the well pad, an operator at the dewatering plant, and a maintenance operator roving the system. Each position will be repeated on day and night shift over the anticipated March to October timeframe.

 

18.3.4Wet process, Dry Process, and Loadout

 

Wet process, Dry process and Loadout operating costs are an allowance for maintenance and consumables, as well as gas and power within the plant. Gas consumption is based on the current concept of the dry plant and heating load anticipated to run the dryers. The dryer gas cost is based on the assumption that Year 1 will require trucked propane gas; Year 2 onward will include gas delivered via pipeline at a lower cost rate. It should be noted that the Wet process includes a magnetic separation or beneficiation stage at $0.72 per tonne.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

18.3.5Support Equipment

 

Support equipment consists of the mobile equipment that is required to operate the mine, and their upkeep and fuel consumption. The mobile equipment required for the project includes:

 

Skidsteer Loader (1)

 

Pickup truck (3)

 

Service Truck (1)

 

Manlift (1)

 

Water Truck (1)

 

Off road forklift (1)

 

Railcar mover (1)

 

982M (2)

 

18.3.6Rail & Port

 

Sio Silica has utilized rail costs of $65 per clean tonne and port costs of $20 per clean tonne for sand delivered to ports in Vancouver. Rail costs to other destinations in North America will vary. Sio Silica has adopted a mine gate pricing scenario for this IA.

 

18.3.7Manpower

 

Manpower estimates are based on staffing at the wet, dry and rail loadout areas, with overall support from salaried management. Wellpad staffing is accounted for in the cost per well estimate noted above. Staffing levels for the project are shown in the Table 18.3 outlining anticipated projected roles and responsibilities. The reader should note that annual salary is provided for professional staff while hourly rates are provided for the labour positions.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 18.2 Manpower Roster and Costs

 

Manpower
Role  Number of Employees 

Straight-time Compensation, incl.

Fringes C$ and C$/hr

Plant Manager  1  $218,400 annual
Accountant  1  $154,700 annual
Lab Manager  1  $147,000 annual
Foreman  4  $145,600 annual
Field Geologist  4  $119,000 annual
Lab assistant  1  $84,000 annual
Quality Control  2  $36 / hr
Plant Operator  4  $46 / hr
Utility  8  $49 / hr
Loadout / Rail  4  $44 / hr
Laborer / Bagging  2  $40 / hr
Maintenance 2  2  $49 / hr
Mobile Equipment  4  $42 / hr
Health and Safety Manager  1  $140,000 annual
Environmental Compliance  1  $130,000 annual
Land Management  1  $110,000 annual
Logistics Coordinator  1  $90,000 annual
Warehouse Manager  1  $80,000 annual
Warehouse Assistant  1  $65,000 annual
Asset (Equipment) Manager  1  $120,000 annual
Mechanic  1  $110,000 annual
Jr Mechanic  1  $90,000 annual
Mill Wright  1  $140,000 annual
Welder  1  $100,000 annual
Helper  1  $65,000 annual
Electrician  1  $120,000 annual
Secretary Front Office  1  $55,000 annual
Hydrogeologist  1  $140,000 annual
Field Technology Support  1  $90,000 annual
Heavy Equipment Operator  1  $100,000 annual
Total  55   

 

18.3.8General and Administrative Costs

 

General and administrative expenses for the DEN project were developed on an annual allowance of $1,800,000. The G&A costs are intended to cover items such as legal services, financial support, marketing, office supplies, consultants, and other items.

 

18.3.9Operating cost Summary

 

The total operating cost summary is shown in Table 18.4. In year 1, each extraction site utilizes dedicated supervision leading to higher initial costs. Extraction operation costs are reduced in later years as operations supervision is planned to be centralized. Slurry transport costs are lower in early years due to shorter slurry pumping distances. Dry processing costs are calculated based on the change from trucked propane in Year 1 while the gas line is developed. From Year 2 production onward, operating costs reflect that the installation of a natural gas pipeline and the use of natural gas as opposed to propane.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 18.3

 

Life of mine Operating Cost Summary, C$

 

    Year 1
C$/tonne
    Year 2 onward
C$/tonne
 
Extraction   $ 12.53     $ 8.62  
Slurry Transport   $ 1.74     $ 2.90  
Wet Processing   $ 5.07     $ 5.07  
Dry Processing   $ 11.99     $ 8.63  
Site Labor   $ 1.28     $ 1.28  
Insurance   $ 0.38     $ 0.38  
Total OPEX   $ 32.99     $ 26.88  

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

19ECONOMIC ANALYSIS

 

Sio Silica prepared the economic analyses for the DEN operation and provided the model to Stantec. Stantec reviewed the model and determined it to be appropriate for the purposes of the Study.

 

The economic analyses for this study includes the calculation of Net Present Value (NPV) on a before and after-tax basis. The estimates assume that production, cost targets, pricing and sales goals are achieved. Any deviation from those values affects the determination of NPV.

 

A cash-flow forecast has been developed for the life of the project. This includes a one-year pre- production phase (prior to sales). The production period is 25 years. The NPV is calculated in Year 0, the first year of pre-production. This is 2026 in the project schedule.

 

19.1Assumptions

 

19.1.1Exchange Rate

 

Stantec has utilized an exchange rate of 1.30 to convert US dollars to CDN dollars.

 

19.1.2Rail Transportation Costs

 

Sio Silica solicited a quotation from Canadian National Railway (CN) for the transportation of silica sand from the DEN Property to port destinations in Vancouver, British Columbia. This quotation was factored to include both fuel and rail car rentals, resulting in a rail rate of C$ 65/tonne.

 

19.1.3Port Costs

 

Sio Silica solicited estimates from Vancouver port experts for the unloading of silica sand from bulk railcars and packaging in FIBC super sack bags. As a result, port costs of C$ 20/tonne were used in the IA.

 

19.1.4Product Pricing

 

Sio Silica has provided Stantec with documents regarding product pricing agreements from three companies.

 

Agreement #1

 

The first document is a proposed sales and purchase agreement contract between Sio Silica and Company 1, that Sio Silica has indicated should be finalized in the fourth quarter of 2023. The document states a sales price of US$180 per MT FOB loading port for 500,000 MT per annum. When exchange rates and port and rail costs are considered, it equates to a mine gate price of CDN$149 per MT.

 

Both the buyer and the seller agree to use their best efforts to enter into a binding Sales Agreement in the first quarter of 2024.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Agreement #2

 

The second document is a Memorandum of Understanding between Sio Silica and Company 2 and dated September 15, 2022. The document states a sales price of US$250 per MT FOB loading port for 800,000 MT per annum. When exchange rates and port and rail costs are considered, it equates to a mine gate price of CDN$240 per MT.

 

Agreement #3

 

The third document is an engagement agreement between Sio Silica and Company 3 and dated November 1, 2022. The document states a sales price of US$200 per short ton FOB Mine Gate for 1,200,000 short tons per annum. The agreement also stipulates a service fee equal to 15% of the gross amount of the purchase price paid. When conversion to metric tonnes and the 15% fee are considered, it equates to a mine gate price of CDN$243.60 per MT.

 

The term of this agreement is unlimited unless terminated by either the buyer or the seller.

 

Product Pricing

 

Stantec used a weighted tonnage per annum price from all three agreements for the initial years of the analysis. A weighted tonnage per annum price for the last two agreements was used from 2030 until the end of the project life.

 

Product Quality

 

The first two agreements specify that the quality parameters for the delivered sand shall be a silicon dioxide (SiO2) percentage greater than or equal to 99.9% and Fe2O3 content less than or equal to 100 ppm.

 

19.2DEN Property Life

 

Sio silica plans to commence extraction operations in the 2nd quarter of year 0, processing operations in the 3rd quarter of year 0 with the first product sales planned for the 1st quarter of year 1. The extraction and processing operations are planned to take place for eight months a year, April to November, while sales will take place year-round. The sales will commence with 2.72 mt of saleable product planned in year 1 and extending out the remainder of the 25-year plan. For the purposes of this technical report summary, year 0 is defined as 2026.project payback

 

The forecasted project payback occurs in 2029, 1.00 years after facility construction is completed and commercial operations commence.

 

19.3Royalties and Income Tax

 

19.3.1Royalties

 

Sio Silica has applied the royalties as discussed in Section 3. These royalties equate to 1.34% and 3.0% of pre-tax revenue.

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

19.3.2Mineral Tax

 

Mineral taxes have been applied as per the requirements of the province of Manitoba.

 

In summary the tax applies at the following rates, where mining profit is:

 

< $50 million; tax = mining profit x 10%.

 

$50 to $55 million; tax = (mining profit - $50,000,000) x 65% + $5,000,000.

 

Between $55 and $100 million; tax = mining profit x 15%.

 

$100 to $105 million; tax = (mining profit - $100,000,000) x 57% + $15,000,000.

 

$105 million; tax = mining profit x 17%.

 

A ‘new mine tax holiday’ is in effect which provides that no Mining Tax is payable on new mines until the mining operator has recovered its initial investment.

 

19.3.3Taxes

 

Federal Canadian and Manitoba income taxes were calculated on a project basis in accordance with the applicable tax laws. The calculation assumes the following:

 

A federal income tax rate of 15%

 

A Manitoba income tax rate of 12%

 

19.4Economic Performance

 

The results of the Study base case economic analysis are shown in Table 19.1 Project Economics. The economic performance of the project is positive up to the highest analyzed discount rate of 16%.

 

Table 19.1

Project Economics (C$)

 

Discount Rate  After Tax 
(%)  IRR   NPV 
6   99%  $3,849,723,000 
8   99%  $3,132,092,000 
10   99%  $2,588,786,000 
12   99%  $2,169,955,000 
14   99%  $1,841,529,000 
16   99%  $1,579,856,000 

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Stantec has not completed a rigorous analysis in order to select the project discount rate. However, Stantec notes that current normalized risk-free rate and equity risk premium, composed of 3.5% and 5.7% respectively which shows that the approximate cost of equity capital to be 9.2%. This rate does not account for project risks, industry risk, size and maturity of the operation to name a few. As such the appropriate discount rate for this study is likely in the range of 10-13%. Ultimately investors in the DEN Property will need to conduct their own discount rate analysis.

 

The key project metrics and cash flow summary are summarized in Tables 19.2 and 19.3

 

Table 19.2

 

Key Project Metrics

 

Economic Analysis  DEN 
Net Present Value (NPV), After-Tax  $2,588,786,000 
Internal Rate of Return (IRR), After-Tax   99%
Pay-Back Period (Years based on After-Tax)   1.00 
Capital Costs     
Initial Capital (M)   280.75 
Expansion Capital (M)   N/A 
Operating Costs at Full Production     
Extraction ($/MT )   8.62 
Slurry Transport ($/MT)   2.90 
Wet Processing ($/MT)   5.07 
Dry Processing and Loadout ($/MT)   8.63 
Site Labor and Insurance ($/MT)   1.66 
Total Operating Cost ($/MT)   26.88 
Production Data     
Life of Mine (Years)   25 
Annual Clean Saleable Tonnes Produced (MT)   2,724,000 
Total Clean Saleable Tonnes Produced (MT)   65,376,000 

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Table 19.3 Cash Flow Summary

 

Period  Year 0   Year 1   Year 2   Year 3   Year 4   Year 5   Year 6   Year 7   Year 8   Year 9   Year 10   Year 11   Year 12 
Raw Sand Production (Tonnes)   -    1,831,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000 
                                                                  
Sales Volumes (Tonnes)   -    -    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000 
                                                                  
Minegate Pricing ($/Tonne)   223.53    223.53    223.53    223.53    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55 
                                                                  
Minegate Revenue (M$)   -    -    609    609    661    661    661    661    661    661    661    661    661 
                                                                  
Royalties (M$)   -    -    24    10    11    11    11    11    11    11    11    11    11 
Mining Tax (M$)   -    -    86    89    98    98    98    98    98    98    98    98    98 
Net Revenue (M$)   -    -    499    510    553    553    553    553    553    553    553    553    553 
                                                                  
Extraction Operating Costs (M$)   -    28    44    37    37    37    37    37    37    37    37    37    37 
Wet Processing Operating Costs (M$)   -    3    14    14    14    14    14    14    14    14    14    14    14 
Dry Processing and Loadout Operating Costs (M$)   -    -    33    24    24    24    24    24    24    24    24    24    24 
Total Operating Costs (M$)   -    31    91    74    74    74    74    74    74    74    74    74    74 
                                                                  
Manitoba Operations G&A (M$)   -    -    -    -    -    -    -    -    -    -    -    -    - 
Head office G&A (M$)   2    2    2    2    2    2    2    2    2    2    2    2    2 
Total G&A (M$)   2    2    2    2    2    2    2    2    2    2    2    2    2 
                                                                  
Cash Interest Expense (M$)   3    21    21    2    -    -    -    -    -    -    -    -    - 
Cash Income Tax (M$)   (1)   (14)   69    103    118    121    123    124    125    126    127    127    128 
Total Cash-flow (M$)   (4)   (39)   317    330    359    356    354    353    352    351    350    350    349 
Cumulative Cash-Flow (M$)   (4)   (43)   273    604    963    1,319    1,673    2,026    2,377    2,728    3,078    3,427    3,777 
                                                                  
Phase 1 Capital Expenditures (M$)   21    260    -    -    -    -    -    -    -    -    -    -    - 
Expansion Capital Expenditures (M$)   -    -    -    -    -    -    -    -    -    -    -    -    - 
Total Capital Expenditures (M$)   21    260    -    -    -    -    -    -    -    -    -    -    - 

 

 

19-5

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Period  Year 13   Year 14   Year 15   Year 16   Year 17   Year 18   Year 19   Year 20   Year 21   Year 22   Year 23   Year 24   Year 25   Total 
Raw Sand Production (Tonnes)   2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    2,929,000    72,127,000 
                                                                       
Sales Volumes (Tonnes)   2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    2,724,000    65,376,000 
                                                                       
Minegate Pricing ($/Tonne)   242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55    242.55      
                                                                       
Minegate Revenue (M$)   661    661    661    661    661    661    661    661    661    661    661    661    661    15,753 
                                                                       
Royalties (M$)   11    11    11    11    11    11    11    11    11    11    11    11    11    265 
Mining Tax (M$)   98    98    98    98    98    98    98    98    98    98    98    98    98    2,327 
Net Revenue (M$)   553    552    552    552    552    552    552    552    552    552    552    552    552    13,161 
                                                                       
Extraction Operating Costs (M$)   37    37    37    37    37    37    37    37    37    37    37    37    37    912 
Wet Processing Operating Costs (M$)   14    14    14    14    14    14    14    14    14    14    14    14    14    335 
Dry Processing and Loadout Operating Costs (M$)   24    24    24    24    24    24    24    24    24    24    24    24    24    573 
Total Operating Costs (M$)   74    74    74    74    74    74    74    74    74    74    74    74    74    1,821 
                                                                       
Manitoba Operations G&A (M$)   -    -    -    -    -    -    -    -    -    -    -    -    -    - 
Head office G&A (M$)   2    2    2    2    2    2    2    2    2    2    2    2    2    47 
Total G&A (M$)   2    2    2    2    2    2    2    2    2    2    2    2    2    47 
                                                                       
Cash Interest Expense (M$)   -    -    -    -    -    -    -    -    -    -    -              47 
Cash Income Tax (M$)   128    128    128    128    128    128    128    129    129    129    129    129    129    2,945 
Total Cash-flow (M$)   349    348    348    348    348    348    348    348    348    348    348    348    348    8,302 
Cumulative Cash-Flow (M$)   4,126    4,474    4,822    5,170    5,518    5,866    6,214    6,562    6,910    7,258    7,606    7,953    8,301    - 
                                                                       
Phase 1 Capital Expenditures (M$)   -    -    -    -    -    -    -    -    -    -    -    -    -    281 
Expansion Capital Expenditures (M$)   -    -    -    -    -    -    -    -    -    -    -    -    -    - 
Total Capital Expenditures (M$)   -    -    -    -    -    -    -    -    -    -    -    -    -    281 

 

 

19-6

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

19.5Sensitivity Analysis

 

High-level sensitivity analyses were carried out to determine the impact that changes in product pricing and overall costs (capital and operating) would have on the economic performance of the project. The analyses were carried out to determine the effect on the after-tax IRR and NPV 10 values.

 

Stantec notes that the project economics remain positive all under circumstances modeled herein.

 

 

19-7

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

 

Table 19.4

 

After Tax NPV Sensitivity to Sale Price

 

   Product Pricing 
     -30%   -20%   -10%   0%   10%   20%   30% 
    -30%   1,696,467,000    2,004,291,000    2,312,358,000    2,619,873,000    2,927,520,000    3,234,302,000    3,542,159,000 
    -20%   1,683,156,000    1,991,056,000    2,299,178,000    2,606,737,000    2,914,419,000    3,221,229,000    3,529,109,000 
    -10%   1,673,360,000    1,981,340,000    2,289,521,000    2,597,126,000    2,904,845,000    3,211,684,000    3,519,589,000 
Project   -5%   1,668,992,000    1,977,014,000    2,285,225,000    2,592,854,000    2,900,593,000    3,207,446,000    3,515,365,000 
Costs   0%   1,664,825,000    1,972,889,000    2,281,132,000    2,588,786,000    2,896,544,000    3,203,413,000    3,511,344,000 
    5%   1,660,799,000    1,968,908,000    2,277,183,000    2,584,861,000    2,892,639,000    3,199,524,000    3,507,469,000 
    10%   1,656,876,000    1,965,030,000    2,273,338,000    2,581,042,000    2,888,840,000    3,195,741,000    3,503,700,000 
    20%   1,649,242,000    1,957,489,000    2,265,865,000    2,573,623,000    2,881,464,000    3,188,398,000    3,496,385,000 
    30%   1,641,790,000    1,950,136,000    2,258,584,000    2,566,398,000    2,874,282,000    3,181,251,000    3,489,268,000 

 

 

19-8

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

20ADJACENT PROPERTIES

 

There are no properties exploiting silica sand adjacent to the DEN Property.

 

 

20-1

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

21OTHER RELEVANT DATA AND INFORMATION

 

All relevant information is included in this Report.

 

 

21-1

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

22INTERPRETATION AND CONCLUSIONS

 

This Study indicates a positive economic outcome related to the potential development of a silica sand extraction and processing operation for the DEN Property. The extraction plan addressed only a portion of the In-Situ Mineral Resource previously classified, as the entire DEN resource was not required for the 25-year development plan.

 

Stantec has identified the following risks that could potentially affect the projected economic viability of the DEN Property development.

 

22.1Product Pricing And Cost Escalation

 

As indicated in Section 19 of this Study, the project economics are sensitive to the assumed pricing for silica sand and estimated project costs. A 30% reduction in product pricing combined with a 30% increase in project costs, after a 7% contingency (initial project capital) has been applied, results in positive economics.

 

Stantec has reviewed Sio Silica’s cost estimate and believes it captures reasonable Capex and Opex costs for the project as it is currently planned. However, the cost estimate is based on budgetary quotes provides by third party vendors and Sio Silica’s partners and assumes the project advances as per the current schedule.

 

Stantec understands that Sio Silica intends to proceed with the project development commencing in 2026, partially based on the results of this Study. As such, the risks associated with cost escalation are not insignificant.

 

22.2Timing Of Project Development

 

Certain process and infrastructure components may be subject to longer lead times. These include rotary dryers, gas pipeline installation, and high voltage substations. The full capacity of the DEN operation and the resultant project economics are dependent on these components.

 

22.3Development Of Extraction Process

 

The current extraction process is based on the results from 14 drill holes completed on the BRU Property from 2017 to 2021. Stantec has no reason to believe that the planned extraction process will not be successful. However, Stantec does note the risks to the project should the planned extraction rates be unachievable or unsustainable over the life and geographic extent of the Project.

 

22.4Confirmation Of Geotechnical Testing And Analysis

 

As discussed in Section 11.4, Stantec geotechnical engineers completed a preliminary geotechnical analysis related to extraction of the sand resource on the adjacent BRU Property. A similar program has not yet occurred for the DEN Property. Stantec used the BRU results and DEN geological interpretation and completed a high-level preliminary analysis of the DEN conditions and these results were used to inform the current resource estimate.

 

 

22-1

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

The conclusions of the previous BRU analysis are summarized below:

 

Based upon current information and assessments, Shear and Bending are the most probable failure modes with the potential to affect long-term stability. Unravelling, Caving, and Chimneying are not controlling failure modes for the BRU property due to the nature of the limestone caprock.

 

The Bending failure mode is controlling the long-term stability of the post extraction cavity for the expected range of caprock and overburden thickness and material properties and the extraction depth in the sand. The stability analysis and extraction borehole spacing design were completed to achieve a factor of safety of 2.0, which is considered to be an acceptably conservative FOS for the project.

 

The cavity after extraction is expected to further expand with time resulting in loose sand infilling the extracted void leaving a larger unsupported caprock span. Based on the assumption that the areas with factor of safety larger than 2 are stable in the long-term, approximately 5 m of additional raveling of the post extraction cavity walls is expected (by end of the design life of 100 years). Therefore, the unsupported caprock span will increase by 10 m with time after extraction.

 

Based upon the results of geotechnical assessment and with the understanding that Sio Silica will follow guidance provided by Stantec including continuing to assess the geotechnical characteristics and performance of the sand deposit and overlying materials during the project life and to adjust design accordingly, no large-scale surface subsidence is expected to occur as a result of sand extraction.

 

There is a potential that further geotechnical assessments may impact the current resource estimate, either positively or negatively. In particular, there remains uncertainty regarding the possible presence of vertical fractures in Limestone caprock, which to date has not been investigated or assessed. The presence of continuous vertical fractures in Limestone caprock above extraction voids has the potential to lead to caprock collapse which may propagate to the surface and produce settlement. In addition, there remains uncertainty regarding the long term performance of the extraction voids which may have complex void shapes and have the potential to propagate over larger than currently estimated distances.

 

 

22-2

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

23RECOMMENDATIONS

 

23.1PHASE 1: GEOTECHNICAL AND RESOURCE INVESTIGATION AND ANALYSIS

 

Based on Sio Silica’s current development and production plans, all resources identified in the areas where the first 5 years of production will occur should be classified as Measured. Additional drill holes may be required to increase confidence in the resource estimates within these areas.

 

Stantec geotechnical engineers completed a preliminary geotechnical analysis of the impact of extraction of the sand on the BRU Property. The recommendations from this analysis, which also apply to the DEN Property, are summarized below:

 

Design and execute a site investigation and assess the results to confirm expected geotechnical performance. This investigation may include the following components:

 

oData Collection:

 

Geotechnical borehole drilling, logging, photography, and sampling with vertical and inclined boreholes and SPT or CPT if needed – to characterize extents and properties of sandstone, caprock and overburden.

 

Acoustic and Optical Televiewer Survey of Geotechnical Boreholes – to characterize caprock structure.

 

Side Scan Sonar Survey – to monitor sand cavity shape and behavior.

 

Laboratory testing of selected samples of sandstone, caprock and overburden as required – to characterize properties of sandstone, caprock and overburden.

 

Installation and monitoring of Vibrating Wire Piezometers, Vertical Extensometers and Surface Monuments and Total Station or GPS Survey – to monitor changes in caprock and surface subsidence.

 

oData Analysis:

 

Stability and settlement analysis to identify and assess for changes in assumptions related to vertical jointing (if found) in Limestone caprock, extraction void shape or other design assumptions.

 

Develop and implement a Trigger Action Response Plan as follows:

 

Collected data review - to establish baseline values.

 

Trigger value range identification - low/moderate/high – green/yellow/red

 

Monitoring results verification and comparison against trigger values.

 

Review the impact of potential vibration sources, such as rail traffic, to determine potential offsets from extraction areas.

 

 

23-1

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

Table 23.1 shows the anticipated cost to complete the geotechnical analysis.

 

Table 23.1

 

Cost Estimate – Geotechnical Analysis

 

Task  Estimated Cost (C$) 
Geotechnical Analysis   500,000 

 

23.2PHASE 2: ENGINEERING BRIDGING STUDIES

 

Stantec recommends that Sio Silica continues to more accurately define the CAPEX and OPEX estimate for the DEN Property and to secure relationships with contractors, vendors, and suppliers.

 

Table 23.2 provides cost estimates for these studies.

 

Table 23.2

 

Engineering Bridging Studies

 

 

Task

  Estimated Cost (C$) 
Engineering Bridging Studies   550,000 

 

 

23-2

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

24REFERENCES

 

Bezys, R.K. and Conley, G.G., 1998. Geology of the Ordovician Winnipeg Formation in Manitoba; Manitoba Energy and Mines, Stratigraphic Map Series, Ow-1, 1:2 000 000.

 

Butler, J.R., Battin, R.L., Plank, R.F., and Winston, D.B., 1955. Lithologic correlation of Middle and Lower Paleozoic rocks. Swartz, Joe. And others, eds, South Dakota Black Hills: North Dakota Geological Society Annual Field Conference Guidebook 3. Pp. 38-42.

 

Canadian Securities Administrators, 2011. National Instrument 43-101 Standards of Disclosure for Mineral Projects, Form 43-101F1, Technical Report, and Companion Policy 43-101.

 

CIM Standing Committee on Reserve Definitions. 2010. CIM Definition Standards - For Mineral Resources and Mineral Reserves.

 

Environment Canada, 2017. Canadian Climate Normals or Averages 1981-2010. Stations: Ostenfeld, Winnipeg International Airport, Steinbach, Beausejour, CDA. Accessed August 2017. http://www.climate.weatheroffice.ec.gc.ca/climate_normals/index_e.html

 

Groundwater Information Network (GIN), 2019. Groundwater Information Network. Data obtained on March 13, 2019. http://gin.gw-info.net/service/api_ngwds:gin2/en/gin.html

 

Krumbein, W.C. and Sloss, L., L., 1963. Stratigraphy and Sedimentation, 2nd ed., W.H. Freeman, San Francisco.

 

Lapenskie, K. 2016: Preliminary investigations into the high-purity silica sand of the Winnipeg Formation, southern Manitoba; in Report of Activities 2016, Manitoba Growth, Enterprise and Trade, Manitoba Geological Survey, p. 176 - 180.

 

Le Fever, R.D., Thompson, S.C., and Anderson, D.B., 1978. Earliest Paleozoic history of the Williston Basin in North Dakota; in 5th International Williston Basin Symposium Proceeding, Special Publication No. 9, p. 147-156.

 

Manitoba, 1992a. M.R. 63/92. Drilling Regulation. Mines and Minerals Act (C.C.S.M. c. M162). Queen’s Printer. Accessed September 20, 2017. https://web2.gov.mb.ca/laws/regs/current/_pdf-regs.php?reg=63/92

 

Manitoba, 1992b. MR 64/92. Mineral Disposition and Mineral Lease Regulation 1992. Mines and Minerals Act (C.C.S.M. c. M162). Queen’s Printer. Accessed September 18, 2017. http://web2.gov.mb.ca/laws/regs/current/_pdf-regs.php?reg=64/92

 

Matile G.L.D., and Keller G.R., 2004. Surficial Geology Compilation Map Series. Manitoba Geological Survey, GIS Map Gallery. Geographic Information System. http://www.gov.mb.ca/iem/geo/gis/sgcms/legend.html

 

Natural Resources Canada, 2004. Ice Box Member. CSPG Lexicon of Canadian Stratigraphy, Volume 4, western Canada, including eastern British Columbia, Alberta, Saskatchewan and southern Manitoba; D.J. Glass (editor). Contributor: D.F. Paterson. http://weblex.nrcan.gc.ca/html/006000/GSCC00053006881.html

 

 

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TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

  

Natural Resources Canada, 2009a. Winnipeg Formation. CSPG Lexicon of Canadian Stratigraphy, Volume 4, western Canada, including eastern British Columbia, Alberta, Saskatchewan and southern Manitoba; D.J. Glass (editor). Contributor: D.F. Paterson. http://weblex.nrcan.gc.ca/html/016000/GSCC00053016596.html

 

Natural Resources Canada, 2009b. Carman Sand Member. CSPG Lexicon of Canadian Geological Stratigraphy. Volume 4, western Canada, including eastern British Columbia, Alberta, Saskatchewan and southern Manitoba; D.J. Glass (editor). Contributor: H.R. McCabe. http://weblex.rncan.gc.ca/html/002000/GSCC00053002494.html

 

Natural Resources Canada, 2009c. Black Island Member. CSPG Lexicon of Canadian Stratigraphy, Volume 4, western Canada, including eastern British Columbia, Alberta, Saskatchewan and southern Manitoba; D.J. Glass (editor). Contributor: D.F. Paterson. http://weblex.nrcan.gc.ca/html/001000/GSCC00053001436.html

 

Natural Resources Canada, 2015. Red River Formation. CSPG Lexicon of Canadian Geological Names. CSPG Lexicon of Canadian Geological Stratigraphy. Volume 4, western Canada, including eastern British Columbia, Alberta, Saskatchewan and southern Manitoba; D.J. Glass (editor). Contributor: H.R. McCabe. http://weblex.nrcan.gc.ca/html/012000/GSCC00053012586.html

 

Ozadetz, K.G., and Haidl, F.M., 1989. Tippecanoe Sequence: Middle Ordovician to lowest Devonian: vestiges of a great epeiric sea, Chapter 8; in Western Canada Sedimentary Basin: a case study (B.D. Ricketts, ed.); Canadian Society of Petroleum Geologist, Special Bulletin No. 30, p. 121-137.

 

Railway Association of Canada (RAC), 2017. RAC Canadian Rail Atlas. Accessed October 12, 2017 https://rac.jmaponline.net/canadianrailatlas/

 

Smith R.E., Veldhuis H., Mills G.F., Eilers R.G., Fraser W.R., Lelyk G.W., 1998. Terrestrial Ecozones, Ecoregions and Ecodistricts of Manitoba. An Ecological Stratification of Manitoba’s Natural Landscapes. Research Branch Technical Bulletin 1998-9E. Land Resource Unit. Brandon Research Centre, Research Branch. Agriculture and Agri-Food Canada. pp. 127, 202-204, 260.

 

Underwood McLellan & Associates Limited, 1967. A Feasibility Study of Recovery and Utilization of the St. Anne Silica Sand Deposits. Project No. 41 60 0751 01/02. pp. 52.

 

Winnipeg. 2017. The Greater Winnipeg Water District Railway. Water and Waste Department. Accessed October 12, 2017 http://www.winnipeg.ca/waterandwaste/dept/railway.stm

 

 

24-2

TECHNICAL REPORT SUMMARY, DEN PROPERTY, MANITOBA, CANADA

 

25RELIANCE ON INFORMATION PROVIDED BY THE REGISTRANT

 

The Qualified Persons did not rely on a report, opinion or statement of another expert who is not a Qualified Person or on information provided by the issuer, concerning legal, political, environmental, or tax matters.

 

 

 

 

 

 

 

  25-1