VANCOUVER, BC, Aug. 5, 2024
/CNW/ - August 6, 2024 –
Sydney, Australia
HIGHLIGHTS
- The Mineral Resource Estimate for the Shaakichiuwaanaan
Lithium Project (formerly known as Corvette) reaffirmed as the
largest lithium pegmatite Mineral Resource in the Americas and
the 8th largest globally:
- Consolidated Mineral Resource statement (CV5 &
CV13 spodumene pegmatites)
- 80.1 Mt at 1.44% Li2O and 163 ppm
Ta2O5 Indicated, and
- 62.5 Mt at 1.31% Li2O and 147 ppm
Ta2O5, Inferred.
- The Company remains on track to provide the market with a
Preliminary Economic Assessment for the CV5 Spodumene
Pegmatite by the end of the September quarter based on the Mineral
Resource Estimate announced herein.
- Shaakichiuwaanaan Mineral Resource includes 6.9 km of
collective strike length now confirmed to host continuous spodumene
pegmatite Mineral Resources (4.6 km at CV5 and 2.3 km at
CV13).
- Significant growth potential – both the CV5 and CV13
spodumene pegmatites remain open along strike at both ends, and to
depth.
- Cut-off grade sensitivity analysis defines significant
tonnage at very high grade, primarily reflecting the Nova and
Vega zone discoveries at CV5 and
CV13, respectively.
- Mineral Resource Estimate includes only the CV5 and
CV13 spodumene pegmatites. It does not include any of the other
known spodumene pegmatite clusters on the Property – CV4, CV8, CV9,
CV10, CV12, and CV14.
- The Company intends to aggressively advance the
remaining infill drilling at CV5 to underpin a maiden ore
reserve and Feasibility Study scheduled for Q3-2025.
Darren L. Smith, Vice President
of Exploration, comments: "This is a significant update to our
Mineral Resource Estimate at Shaakichiuwaanaan, which now includes
both the CV5 and CV13 spodumene pegmatites as well as a significant
amount of resources now classified as Indicated. This resource
update objectively reaffirms the Tier 1 nature of the spodumene
pegmatites that define the Shaakichiuwaanaan Project. Further, with
both the CV5 and CV13 pegmatites remaining open, as well as
multiple spodumene pegmatite clusters on the Property still to be
drill tested, significant potential for further resource growth is
evident."
"Exploration success in this industry is never less than a
team effort. In this regard, I would like to acknowledge the
dedication, work ethic, and contributions from the exploration and
development teams, our supporting service providers and
consultants, and finally our Chisasibi community workers who have all
helped advance Shaakichiuwaanaan through to this key milestone on
the path to potential production," added Mr. Smith.
Ken Brinsden, President, CEO, and
Managing Director, comments: "This is a significant
accomplishment for our team and a major milestone for the Company
as we cement the Shaakichiuwaanaan Lithium Project's position as
one of the most important new hard rock lithium assets
globally."
"The delivery of a substantial maiden Indicated Resource of
over 80 million tonnes is a major milestone which will underpin
development studies, while the continued growth of the overall
resource – in conjunction with the Exploration Target announced
separately today – highlights the Tier-1 scale of the mineral
system and the enormous potential for further growth. I am
immensely proud of our team members and consultants who continue to
put a significant focus on safety and quality deliverables as we
move forward through the various phases of development".
"As we advance towards a Preliminary Economic Assessment in
the near-term for the Shaakichiuwaanaan Project, and further
towards a Feasibility Study scheduled for completion Q3 2025, the
Company is firmly positioned as a leading candidate to provide
long-term spodumene supply to the North American and European
markets," added Mr. Brinsden.
Patriot Battery Metals Inc. (the "Company" or "Patriot")
(TSX: PMET) (ASX: PMT) (OTCQX: PMETF) (FSE: R9GA) is pleased
to announce an updated consolidated Mineral Resource Estimate
("MRE" or "Consolidated MRE") for the CV5 and CV13 spodumene
pegmatites at its 100%-owned Shaakichiuwaanaan Property (the
"Property" or "Project") – formerly known as Corvette – located in
the Eeyou Istchee James Bay region of Quebec. The CV5 Spodumene Pegmatite is
situated approximately 13.5 km south of the regional and
all–weather Trans-Taiga Road and powerline infrastructure corridor,
and is accessible year-round by all-season road. The CV13 Spodumene
Pegmatite is located approximately 3 km west-southwest of CV5.
The updated Consolidated MRE for the Shaakichiuwaanaan Project
includes both the CV5 and CV13 spodumene pegmatites for a total of
80.1 Mt at 1.44% Li2O Indicated and
62.5 Mt at 1.31% Li2O Inferred, for
4.88 Mt contained lithium carbonate equivalent ("LCE") (Table
1, Figure 1, and Figure 2). Presented by resource location/name,
this MRE includes 78.6 Mt at 1.43% Li2O Indicated and
43.3 Mt at 1.25% Li2O Inferred at CV5, and
1.5 Mt at 1.62% Li2O Indicated and 19.1 Mt at
1.46% Li2O Inferred at CV13. The cut-off grade is
variable depending on the mining method and pegmatite (see
footnotes in Table 1 for details). Mineral Resources are not
Mineral Reserves as they do not have demonstrated economic
viability
The Consolidated MRE for the Shaakichiuwaanaan Project,
including that of the CV5 Pegmatite on its own, reaffirms it – by a
wide margin – as the largest lithium pegmatite Mineral Resource
in the Americas and 8th largest
globally (Figure 1, Figure 2, Appendix 2, and Appendix
3). These metrics and context firmly reaffirm and entrench
the Project as a Tier 1, world class lithium pegmatite
asset.
A primary objective of the drilling completed subsequent to the
July 2023 MRE, was to target a
significant upgrade from Inferred resources to Indicated resources,
which correlates to a more robust Mineral Resource with higher
confidence classification. As a result, in addition to the overall
size of the MRE increasing compared to the maiden MRE (see news
release dated July 30, 2023), a
significant amount of the resource has now been classified as
Indicated (80.1 Mt at 1.44% Li2O) compared to no
Indicated resources being classified in the maiden MRE.
The Consolidated MRE statement for the Shaakichiuwaanaan
Project, presented in Table 1, includes only the CV5 and CV13
spodumene pegmatites, which remain open at both ends along strike
and to depth along most of their length. Therefore, this
Consolidated MRE does not include any of the other known spodumene
pegmatite clusters on the Property – CV4, CV8, CV9, CV10, CV12, and
CV14 (Figure 3 and Figure 33). Collectively, this highlights a
considerable potential for resource growth through continued
drill exploration at the Property.
The Mineral Resource statement and relevant disclosure,
sensitivity analysis, peer comparison, geological and block model
views, and cross-sections are presented in the following figures
and tables. A detailed overview of the MRE and Project is presented
in the following sections in accordance with ASX Listing Rule
5.8.
MINERAL RESOURCE STATEMENT (NI 43-101)
Table 1: NI 43-101 Mineral Resource Statement for the
Shaakichiuwaanaan Project.
Pegmatite
|
Classification
|
Tonnes
|
Li2O
(%)
|
Ta2O5
(ppm)
|
Contained
Li2O
(Mt)
|
Contained
LCE
(Mt)
|
CV5 &
CV13
|
Indicated
|
80,130,000
|
1.44
|
163
|
1.15
|
2.85
|
Inferred
|
62,470,000
|
1.31
|
147
|
0.82
|
2.03
|
•
|
Mineral Resources were
prepared in accordance with National Instrument 43-101 – Standards
for Disclosure of Mineral Projects ("NI 43-101") and the CIM
Definition Standards (2014). Mineral Resources that are not Mineral
Reserves do not have demonstrated economic viability. This estimate
of Mineral Resources may be materially affected by environmental,
permitting, legal, title, taxation, sociopolitical, marketing,
economic, or other relevant issues.
|
•
|
The independent
Competent Person (CP), as defined under JORC, and Qualified Person
(QP), as defined by NI 43–101 for this estimate is Todd McCracken,
P.Geo., Director – Mining & Geology – Central Canada, BBA
Engineering Ltd. The Effective Date of the estimate is June 27,
2024 (through drill hole CV24-526).
|
•
|
Estimation was
completed using a combination of ordinary kriging and inverse
distance squared (ID2) in Leapfrog Edge software with
dynamic anisotropy search ellipse on specific domains.
|
•
|
Drill hole composites
at 1 m in length. Block size is 10 m x 5 m x 5 m with
sub-blocking.
|
•
|
Both underground and
open-pit conceptual mining shapes were applied as constraints to
demonstrate reasonable prospects for eventual economic extraction.
Cut-off grades for open-pit constrained resources are 0.40%
Li2O for both CV5 and CV13, and for underground
constrained resources are 0.60% Li2O for CV5 and 0.80%
Li2O for CV13. Open-pit and underground Mineral Resource
constraints are based on a spodumene concentrate price of
US$1,500/tonne (6% basis FOB Bécancour) and an exchange rate of
0.76 USD/CAD.
|
•
|
Rounding may result in
apparent summation differences between tonnes, grade, and contained
metal content.
|
•
|
Tonnage and grade
measurements are in metric units.
|
•
|
Conversion factors
used: Li2O = Li x 2.153; LCE (i.e.,
Li2CO3) = Li2O x 2.473,
Ta2O5 = Ta x 1.221.
|
•
|
Densities for pegmatite
blocks (both CV5 & CV13) were estimated using a linear
regression function (SG = 0.0688x Li2O% + 2.625) derived
from the specific gravity ("SG") field measurements and
Li2O grade. Non-pegmatite blocks were assigned a fixed
SG based on the field measurement median value of their respective
lithology.
|
The Shaakichiuwaanaan MRE covers a collective strike length of
approximately 6.9 km, drill hole to drill hole (4.6 km at CV5, and
2.3 km at CV13). Further, the CV5 and CV13 spodumene pegmatites are
situated along the same geological trend, separated by
approximately 2.9 km, and therefore this corridor is considered
highly prospective for lithium pegmatite (Figure 3). This corridor
remains to be drill tested; however, current interpretation of the
collective dataset over the trend indicates a reasonable potential
for connectivity of the pegmatite body(s). As such, given the
similar mineralogy, geochemistry, host geological and structural
trend, and close proximity to each other (< 3 km), the MREs for
the CV5 and CV13 pegmatites have been presented as a consolidated
MRE for the Project (Table 1). The MRE is further detailed below
with respect to conceptual mining constraint shapes by resource
location/name (Table 2).
The Shaakichiuwaanaan database includes 537 diamond drill holes
completed over the 2021, 2022, 2023, and 2024 (through the end of
April – drill hole CV24-526) programs, for a collective total of
169,526 m, as well as 88 outcrop
channels totalling 520 m. The MRE is supported by 344 holes
(129,673 m) and 11 outcrop channels
(63 m) at CV5, and 132 holes (29,059
m) and 54 outcrop channels (340 m) at CV13.
Table 2: Shaakichiuwaanaan Mineral Resource by Pegmatite and
Conceptual Mining Constraint.
Cut-off
Grade
Li2O
(%)
|
Conceptual
Mining
Constraint
|
Pegmatite
|
Classification
|
Tonnes
(Mt)
|
Li2O
(%)
|
Ta2O5
(ppm)
|
Contained
Li2O
(Mt)
|
Contained
LCE
(Mt)
|
0.40
|
Open-Pit
|
CV5
|
Indicated
|
78.1
|
1.44
|
162
|
1.12
|
2.78
|
0.60
|
Underground
|
0.5
|
0.91
|
169
|
0.00
|
0.01
|
|
|
Total
|
|
78.6
|
1.43
|
162
|
1.13
|
2.79
|
0.40
|
Open-Pit
|
CV5
|
Inferred
|
29.9
|
1.34
|
168
|
0.40
|
0.99
|
0.60
|
Underground
|
13.4
|
1.04
|
145
|
0.14
|
0.35
|
|
|
Total
|
|
43.3
|
1.25
|
161
|
0.54
|
1.34
|
|
|
|
|
|
|
|
|
|
0.40
|
Open-Pit
|
CV13
|
Indicated
|
1.5
|
1.62
|
195
|
0.02
|
0.06
|
0.80
|
Underground
|
0
|
0
|
0
|
0.00
|
0.00
|
|
|
Total
|
|
1.5
|
1.62
|
195
|
0.02
|
0.06
|
0.40
|
Open-Pit
|
CV13
|
Inferred
|
17.7
|
1.50
|
118
|
0.27
|
0.66
|
0.80
|
Underground
|
1.4
|
1.05
|
73
|
0.01
|
0.04
|
|
|
Total
|
|
19.1
|
1.46
|
115
|
0.28
|
0.69
|
All Table 1 footnotes
are applicable.
|
SENSITIVITY ANALYSIS
The sensitivity analysis for the Shaakichiuwaanaan MRE (Table
3 and Figure 4) is presented as the sum of the open-pit and
underground constrained and classified resources at the same
cut-off. The sensitivity analysis by cut-off grade ("COG")
defines significant tonnage at very high-grade, primarily
reflecting the Nova Zone at CV5 and Vega Zone at CV13.
- At a 1.5% Li2O COG for the CV5 Pegmatite, there is a
total of 30.4 Mt at 2.09 Li2O Indicated and 13.6 Mt at
1.99 Li2O Inferred.
- At a 1.5% Li2O COG for the CV13 Pegmatite, there is
a total of 0.7 Mt at 2.20 Li2O Indicated and 6.6 Mt at
2.47 Li2O Inferred.
Both the Nova and Vega zones
have been traced over a significant distance/area with
multiple drill hole intercepts (core length) ranging from 2 to
25 m (CV5) and 2 to 10 m (CV13) at >5% Li2O, each
within a significantly wider mineralized pegmatite zone of >2%
Li2O (Figure 16, Figure 25, and Figure 26). These zones
are located approximately 6 km apart, along the same geological
trend, and emphasize not only the scale of the entire mineralized
system at Shaakichiuwaanaan but also its robustness in mineralized
intensity defined to date.
The following Table 3 and Figure 4 outline the corresponding
tonnage and lithium grade at various cut-off grades for the
Shaakichiuwaanaan MRE. In addition to evaluating sensitivities to
cut-off grades, this table can help relate the tonnage and grades
at Shaakichiuwaanaan more directly to those calculated for peer
deposits, which may have applied different cut-off grades to their
resources.
GEOLOGICAL AND BLOCK MODELS
The geological model underpinning the MRE for the CV5 Spodumene
Pegmatite interprets a single, steeply dipping (northerly),
continuous, principal spodumene pegmatite body ranging in true
thickness from <10 m to more than
125 m, extending over a strike length
of approximately 4.6 km (drill hole to drill hole), which is
flanked by multiple subordinate lenses. At CV5, the pegmatite may
extend from surface to depths of more than 450 m in some locations. The CV5 Spodumene
Pegmatite, which includes the principal body and all subordinate
lenses, remains open along strike at both ends and to depth along a
significant portion of its length.
The geological model underpinning the MRE for the CV13 Spodumene
Pegmatite interprets a series of flat-lying to moderately dipping
(northerly), sub-parallel trending spodumene pegmatite bodies, of
which three appear to dominate. The pegmatite ranges in true
thickness from <5 m to more than
40 m, and extends over a strike
length of approximately 2.3 km. The CV13 Spodumene Pegmatite, which
includes all proximal pegmatite lenses, remains open along strike
at both ends and to depth along a significant portion of its
length.
The geological model of the CV5 Spodumene Pegmatite, which forms
the bulk of the Shaakichiuwaanaan MRE, is presented in plan,
inclined, and side view in Figure 5 to Figure 11. The MRE block
model of the CV5 Spodumene Pegmatite, block classifications, and
cross-sections are presented in Figure 12 to Figure 18.
The geological model of the CV13 Spodumene Pegmatite is
presented in plan and inclined view in Figure 19 and Figure 20,
respectively. The MRE block model of the CV13 Spodumene Pegmatite,
block classifications, and cross-sections are presented in Figure
21 to Figure 28.
CV5 Spodumene Pegmatite
Figures
7-18
Geologically modelled pegmatite where blocks do not populate,
have not reached the threshold confidence for the Inferred Mineral
Resource category based on the classification criteria and/or
mining constraint shape applied. Additional drilling is required to
elevate confidence to the threshold allowing for an inferred
classification of grade and tonnage to be assigned, and for these
blocks to fall within a conceptual mining constraint shape required
to satisfy RPEEE in accordance with NI 43-101.
CV13 Spodumene Pegmatite
Figures
19-28
TANTALUM
In addition to the lithium as the primary commodity of interest,
the CV5 Pegmatite also contains a significant amount of tantalum as
a potentially recoverable by-product – 80.1 Mt at 1.44%
Li2O and 163 ppm Ta2O5
Indicated, and 62.5 Mt at 1.31% Li2O and 147 ppm
Ta2O5 Inferred. Mineralogy completed to
date indicates that tantalite is the tantalum-bearing mineral,
which may potentially be recoverable from the tailings of the
primary lithium recovery process (i.e., potential valorization of
waste streams). Additionally, the MRE suggests tantalum grades
at the CV5 Pegmatite are generally higher compared to that of
the CV13 Pegmatite, although grades at CV13 remain significant
(Table 2). The tantalum grades were not used in generating the
potential mineable shapes at CV5 and CV13
Tantalum is currently listed as a critical and strategic mineral
by the province of Quebec (Canada), Canada, European Union, Australia, Japan, India,
South Korea, and the United States. Tantalum is a critical
component required for a range of high-tech devices, electronics,
and essential niche applications, including in capacitors as it has
the highest capacitance of any metal. According to the United
States Geological Survey, no tantalum is currently produced in
North America or Europe, with a majority of production coming
out of the Democratic Republic of
Congo and Rwanda.
NEXT STEPS
The Company will continue infill drilling at the CV5 Pegmatite
this summer-fall, as well as testing for extensions along strike,
up dip, and down dip, where it remains open. The primary focus of
the drill program is to support a further increase in MRE
confidence from the Inferred category to the Indicated category.
This drilling will target Inferred blocks as categorized in the MRE
announced herein, with the ultimate objective of delineating a
coherent body of Indicated Mineral Resource blocks to underpin a
Feasibility Study scheduled for the second half of 2025.
Additionally, the Company will continue its exploratory drill
program at CV13, focused on further delineation of the high-grade
Vega Zone, as well as various geotechnical, hydrogeological, and
geomechanical drilling in support of advancing development studies
at CV5.
ASX LISTING RULE 5.8
As the Company is listed on both the Canadian Toronto Stock
Exchange (the "TSX") as well as the Australian Securities Exchange
(the "ASX"), there are two applicable regulatory bodies resulting
in additional disclosure requirements. This Mineral Resource
estimate has been completed in accordance with the Canadian
National Instrument 43-101 – Standards of Disclosure for Mineral
Projects, and the Company will, in accordance with NI 43-101,
prepare and file a technical report supporting the Mineral Resource
Estimate on SEDAR+ within 45 days of this announcement.
Additionally, in accordance with ASX Listing Rule 5.8 and the JORC
2012 reporting guidelines, a summary of the material information
used to estimate the Mineral Resource for the Shaakichiuwaanaan
Project is detailed below. For additional information, please refer
to JORC Table 1, Section 1, 2, and 3, as presented in Appendix 1 of
this announcement.
MINERAL TITLE
The Shaakichiuwaanaan Property is located approximately 220 km
east of Radisson, QC, and
240 km north-northeast of Nemaska,
QC. The northern border of the Property's primary claim
grouping is located within approximately 6 km to the south of the
Trans-Taiga Road and powerline infrastructure corridor (Figure 29).
The La Grande-4 (LG4) hydroelectric dam complex is located
approximately 40 km north-northeast of the Property. The CV5
Spodumene Pegmatite, part of the Shaakichiuwaanaan MRE, is located
central to the Property, approximately 13.5 km south of KM270 on
the Trans-Taiga Road, and is accessible year-round by all-season
road. The CV13 Spodumene Pegmatite is located approximately 3 km
west-southwest of CV5.
The Property is comprised of 463 CDC mineral claims that cover
an area of approximately 23,710 ha with the primary claim
grouping extending dominantly east-west for approximately 51 km as
a nearly continuous, single claim block. All claims are registered
100% in the name of Lithium Innova Inc., a wholly owned subsidiary
of Patriot Battery Metals Inc.
GEOLOGY AND GEOLOGICAL INTERPRETATION
The Property overlies a large portion of the Lac Guyer
Greenstone Belt, considered part of the larger La Grande River
Greenstone Belt, and is dominated by volcanic rocks metamorphosed
to amphibolite facies. Rocks of the Guyer Group (amphibolite, iron
formation, intermediate to mafic volcanics, peridotite, pyroxenite,
komatiite, as well as felsic volcanics) predominantly underly the
Property (Figure 32). The amphibolite rocks that trend east-west
(generally steeply south dipping) through this region are bordered
to the north by the Magin Formation (conglomerate and wacke) and to
the south by an assemblage of tonalite, granodiorite, and diorite,
in addition to metasediments of the Marbot Group (conglomerate,
wacke) in the areas proximal to the CV5 Spodumene Pegmatite.
Several regional-scale Proterozoic gabbroic dykes also cut through
portions of the Property (Lac Spirt Dykes, Senneterre Dykes). The
lithium pegmatites on the Property are hosted predominantly within
amphibolite's, metasediments, and to a lesser extent ultramafic
rocks.
Exploration of the Property has outlined three primary mineral
exploration trends, crossing dominantly east-west over large
portions of the Property – Golden Trend (gold), Maven Trend
(copper, gold, silver), and CV Trend (Li-Cs-Ta Pegmatite). The
Golden Trend is focused over the northern areas of the Property,
the Maven Trend in the southern areas, and the CV Trend
"sandwiched" between. Historically, the Golden Trend has received
the exploration focus followed by the Maven Trend. However, the
identification of the CV Trend and the numerous lithium-tantalum
pegmatites discovered to date, represents a previously unknown
lithium pegmatite district that was first identified in 2016/2017
by Dahrouge Geological Consulting Ltd. and the Company. The
Company's Vice President of Exploration, Darren L. Smith, M.Sc., P.Geo., was a member of
the initial team that identified the potential at
Shaakichiuwaanaan, later joining the Company's Advisory Board in
2018, and as Vice President of Exploration in 2019. Mr. Smith has
managed the exploration of the Shaakichiuwaanaan Property since the
initial work programs, including drilling of the lithium
pegmatites.
At the Property, including CV5 and CV13, lithium mineralization
is observed to occur within lithium-cesium-tantalum ("LCT")
pegmatites, which may be exposed at surface as isolated high relief
'whale-back' landforms (i.e., outcrops) (Figure 30 and Figure 31).
Given the proximity of some lithium pegmatite outcrops to each
other at the various clusters, as well as the shallow till cover,
it is probable that some of the outcrops may reflect a
discontinuous surface exposure of a single, larger pegmatite
'outcrop' subsurface. Further, the high number of well-mineralized
pegmatites along the trend at these clusters indicates a strong
potential for a series of relatively closely spaced/stacked,
sub-parallel, and sizable spodumene-bearing pegmatite bodies, with
significant lateral and depth extent, to be present.
To date, the LCT pegmatites at the Property have been observed
to occur within a corridor of approximately 1 km in width that
extends in a general east-west direction across the Property for at
least 25 km – the 'CV Lithium Trend' – with significant areas of
prospective trend that remain to be assessed. The core area of the
trend includes the CV5 and CV13 spodumene pegmatites with
approximate strike lengths of 4.6 km and 2.3 km, respectively, as
defined by drilling to date and which remain open. Further, the CV5
and CV13 spodumene pegmatites are situated along the same
geological trend, separated by approximately 2.9 km of highly
prospective lithium pegmatite trend (Figure 3). This corridor
remains to be drill tested; however, current interpretation of the
collective dataset indicates a reasonable potential for
connectivity of the pegmatite body(s) that define the CV5 and CV13
pegmatites.
To date, eight (8) distinct lithium pegmatite clusters have been
discovered along the CV Lithium Trend at the Property – CV4, CV5,
CV8, CV9, CV10, CV12, CV13, and CV14. Each of these clusters
includes multiple lithium pegmatite outcrops in close proximity,
oriented along the same local trend, and have been grouped to
simplify exploration approach and discussion (Figure 33). The
Mineral Resource Estimate reported herein is limited to only the
CV5 and CV13 spodumene pegmatites (Figure 3).
The pegmatites at the Property, including CV5 and CV13, are very
coarse-grained and off-white in appearance, with darker sections
commonly composed of mica and smoky quartz, and occasionally
tourmaline. Spodumene is the dominant lithium-bearing mineral
identified at all the lithium occurrences documented to date. It
occurs as typically centimetre to decimetre-scale crystals that may
exceed 1.5 m in length and range in
colour from cream-white, to light-grey, to light-green. Minor
localized lepidolite has been observed in core and in a small
number of lithium pegmatite outcrops.
To date, at the CV5 Spodumene Pegmatite, multiple
individual spodumene pegmatite dykes have been geologically
modelled. However, a vast majority of the Mineral Resource is
hosted within a single, large, principal spodumene pegmatite dyke,
which is flanked on both sides by multiple, subordinate,
sub-parallel trending dykes. The CV5 Spodumene Pegmatite, including
the principal dyke, is modelled to extend continuously over a
lateral distance of at least 4.6 km and remains open along strike
at both ends and to depth along a large portion of its length. The
width of the currently known mineralized corridor at CV5 is
approximately ~500 m, with spodumene pegmatite intersected at
depths of more than 450 m in
some locations (vertical depth from surface). The pegmatite dykes
at CV5 trend west-southwest (approximately 250°/070° RHR), and
therefore dip northerly, which is different than the host
amphibolites, metasediments, and ultramafics which dip moderately
in a southerly direction.
The principal spodumene pegmatite dyke at CV5 ranges from
<10 m to more than 125 m in true width, and may pinch and swell
aggressively along strike, as well as up and down dip. It is
primarily the thickest at near-surface to moderate depths
(<225 m), forming a relatively
bulbous, elongated shape, which may flair to surface and to depth
variably along its length. As drilling has focused over the
principal dyke, the immediate CV5 corridor has not been adequately
drill tested and it is interpreted that additional subordinate
pegmatite lenses are situated proximal, especially in the
southcentral areas of the deposit. The pegmatites that define CV5
are relatively undeformed and very competent, although likely have
some meaningful structural control.
The geological model underpinning the MRE for the CV13
Spodumene Pegmatite interprets a series of flat-lying to
moderately dipping (northerly), sub-parallel trending spodumene
pegmatite bodies, of which three appear to dominate. The pegmatite
bodies are coincident with the apex of a regional structural
flexure whereby the pegmatite manifests a west arm trending ~290°
and an east arm trending ~230°. Drilling to date indicates the east
arm includes significantly more pegmatite stacking compared to the
west, and also carries a significant amount of the overall CV13
Pegmatite tonnage and grade, highlighted by the high-grade Vega
Zone.
The CV13 Pegmatite ranges in true thickness from
<5 m to more than 40 m and extends continuously over a collective
strike length of approximately 2.3 km, along its west and east
arms. The CV13 Spodumene Pegmatite, which includes all proximal
pegmatite lenses, remains open along strike at both ends and to
depth along a significant portion of its length. Spodumene
mineralization has been traced more than 400
m down-dip; however, due to the typically shallow dips of
the pegmatite bodies, is only ~200 m vertical depth from
surface.
Both the CV5 and CV13 spodumene pegmatites display internal
fractionation along strike and up/down dip, which is evidenced by
variation in mineral abundance including spodumene and tantalite.
This is highlighted by the high-grade Nova Zone (CV5) and
Vega Zone (CV13), each situated at the base of their
respective pegmatite lenses, and traced over a significant distance
with multiple drill hole intercepts (core length) ranging from 2 to
25 m (CV5) and 2 to 10 m (CV13) at >5% Li2O,
respectively, each within a significantly wider mineralized zone of
>2% Li2O (Figure 16 and Figure 26). The Vega
Zone is situated approximately 6 km south-west and along geological
trend of the Nova Zone. Both zones share several similarities
including lithium grades and very coarse decimetre to metre size
spodumene crystals. However, both pegmatite zones have distinct
orientations whereby the Vega Zone is relatively flat-lying to
shallow dipping while the Nova Zone is steeply dipping to
vertical.
The CV5 Spodumene Pegmatite (4.6 km in strike length) has
currently been delineated to within approximately 1.5 km of the CV4
Spodumene Pegmatite to the east, and to within approximately 2.9 km
of the CV13 Spodumene Pegmatite (2.3 km in strike length) to the
west (Figure 3). The CV12 Spodumene Pegmatite cluster is situated
~2.4 km northwest along strike of CV13. Collectively, this area of
the CV Lithium Pegmatite trend extends nearly 15 km, of which
6.9 km is confirmed by drilling to be continuous spodumene
pegmatite hosting defined Mineral Resources, with ~8 km of this
highly prospective trend remaining to be drill tested.
The scale of LCT pegmatite present along this local trend (CV12
through CV4), as well as the similar mineralogy and very coarse
spodumene crystal size, suggests a deeply rooted and common
'plumbing' system and source of the lithium mineralized bodies
discovered to date. The area of the CV Lithium Trend, extending
from CV12 easterly to CV4, is therefore highly prospective with
data collected to date suggesting a reasonable potential for
lithium pegmatite to be present throughout this trend, and
potentially continuously. Due to a veil of glacial till cover,
there is poor outcrop exposure, therefore requiring significant
drill testing to confirm continuity.
DRILLING TECHNIQUES AND CLASSIFICATION CRITERIA
The Shaakichiuwaanaan Mineral Resource Estimate, including the
CV5 and CV13 spodumene pegmatites is supported by 537 diamond drill
holes of NQ (predominant) or HQ size, completed over the 2021,
2022, 2023, and 2024 (through the end of April – drill hole
CV24-526) programs, for a collective total of 169,526 m, as well as eighty-eight (88) outcrop
channels totalling 520 m. This equates to 344 holes
(129,673 m) and eleven (11) outcrop
channels (63 m) at CV5, and 132 holes (23,059 m) and fifty-four (54) outcrop channels
(340 m) at CV13 (Figure 34, Figure 35, and Figure 36).
Each drill hole collar was surveyed with an RTK tool (Topcon GR5
or Trimble Zephyr 3), with some
minor exceptions that were surveyed using a handheld GPS (Garmin
GPSMAP 64s) only (Table 4). Downhole deviation surveys for each
drill hole were completed with a Devico DeviGyro tool (2021 holes),
Reflex Gyro Sprint IQ tool (2022, 2023, and 2024 holes), Axis Champ
Gyro (2023 holes), or Reflex OMNI Gyro Sprint IQ (2024 holes).
Survey shots were continuous at approximate 3-5 m intervals. The use of the gyro tool system
negated potential deflection issues arising from minor but common
pyrrhotite within the host amphibolite. All collar and downhole
deviation data have been validated by the project geologists on
site, and by the database lead.
Drill core has not been oriented; however, downhole optical and
acoustic televiewer surveys have been completed on multiple holes,
at both CV5 and CV13, to assess overall structure. This data guided
the current geological models supporting this Mineral Resource
Estimate.
At CV5, drill hole collar spacing is dominantly grid based.
Several collars are typically completed from the same pad at varied
orientations targeting pegmatite pierce points of ~50 to
100 m spacing. The initial drill
holes targeting CV5, completed in 2021, assumed a southerly dip to
the pegmatite and therefore three (3) of four (4) holes were
oriented northerly. However, most holes completed to date are
oriented southerly (typically 158°), to cross-cut perpendicular the
steeply, northerly dipping pegmatite, apart from drill holes
targeting specific structure or areas of the pegmatite.
At CV13, drill hole spacing is a combination of grid based (at
~100 spacing) and fan based. Several collars are typically
completed from the same pad at varied orientations targeting
pegmatite pierce points of ~50 to 100
m spacing. Due to the varied orientation of the pegmatite
bodies along strike at CV13, hole orientations may vary widely.
Drill hole spacing and orientation at the CV5 and CV13
pegmatites is sufficient to support the geological models and
resource classifications applied herein.
All drill holes were completed by Fusion Forage Drilling Ltd. of
Hawkesbury, ON. Procedures at the
drill followed industry best practices with drill core placed in
either 4 or 5 ft long, typically flat, square-bottom wooden boxes
with the appropriate hole and box ID noted and block depth markers
placed in the box. Core recovery typically exceeds 90%. Once full,
the box was fibre taped shut with wooden lids at the drill and
transported (helicopter and truck) to Mirage Lodge for
processing.
Channel sampling followed industry best practices with a 3 to 5
cm wide, saw-cut channel completed across the pegmatite outcrop as
practical, perpendicular to the interpreted pegmatite strike.
Samples were collected at ~1 m contiguous intervals with the
channel bearing noted, and GPS coordinate collected at the start
and end points of the channel. Channel samples were transported
along the same route as drill core for processing at Mirage
Lodge.
SAMPLING AND SUB-SAMPLING TECHNIQUES
Core sampling protocols met industry standard practices. Upon
receipt at the core shack at Mirage Lodge, all drill core is pieced
together, oriented to maximum foliation, metre marked,
geotechnically logged (TCR, RQD, ISRM, and Q-Method (since
mid-winter 2023)), alteration logged, geologically logged (rock
type), and sample logged on an individual sample basis. Wet and dry
core box photos are also collected of all core drilled, regardless
of perceived mineralization. Specific gravity measurements of
entire pegmatite samples were collected at systematic intervals
(approximately 1 SG measurement every 4-5
m) using the water immersion method.
Core sampling was guided by rock type as determined during
geological logging (i.e., by a geologist). All pegmatite intervals
were sampled in their entirety, regardless of whether spodumene
mineralization was noted or not (in order to ensure an unbiased
sampling approach) in addition to ~1 to 3
m of sampling into the adjacent host rock (dependent on
pegmatite interval length) to "bookend" the sampled pegmatite. The
minimum individual sample length is typically 0.3-0.5 m and the maximum sample length is typically
2.0 m. Targeted individual pegmatite
sample lengths are 1.0 to 1.5 m. All
drill core was saw-cut, using an Almonte automatic core saw in 2022, 2023, and
2024 with one half-core collected for assay, and the other
half-core remaining in the box for reference.
Channels were geologically logged upon collection on an
individual sample basis; however, were not geotechnically logged.
Channel recovery was effectively 100%.
The logging of drill core and channels was qualitative by
nature, and included estimates of spodumene grain size, inclusions,
and model mineral estimates. These logging practices meet or exceed
current industry standard practices and are of appropriate detail
to support a Mineral Resource estimation and disclosure herein.
All core samples were bagged and sealed individually, and then
placed in large supersacs for added security, palleted, and shipped
by third party transport, or directly by representatives of the
Company, to the designated sample preparation laboratory
(Activation Laboratories Ltd. ("Activation Laboratories") in
Ancaster, ON, in 2021, SGS Canada
Inc. ("SGS Canada") in either Lakefield,
ON, Val-d'Or, QC, or
Radisson, QC, in 2022, 2023, and
2024, being tracked during shipment along with chain of custody
documentation. A small number of holes were sent for sample
preparation to SGS Canada's Sudbury,
ON, and Burnaby, BC,
facilities in 2022. Upon arrival at the laboratory, the samples
were cross-referenced with the shipping manifest to confirm all
samples were accounted for and had not been tampered with.
SAMPLE ANALYSIS METHOD AND QUALITY CONTROL
Core samples collected from 2021 drill holes were shipped to
Activation Laboratories in Ancaster,
ON, for standard sample preparation (code RX1) which
included crushing to 80% passing 10 mesh, followed by a 250 g
riffle split and pulverizing to 95% passing 105 microns. All 2021
core sample pulps were analyzed, at the same lab, for multi-element
(including lithium) by four-acid digestion with ICP-OES finish
(package 1F2) and tantalum by INAA (code 5B), with any samples returning >8,000 ppm Li
by 1F2 reanalyzed for Li by code 8-4 Acid ICP Assay. Activation
Laboratories is a commercial lab with the relevant accreditations
(ISO 17025) and is independent of the Company.
Core samples collected from 2022 and 2023 drill holes CV22-015
through CV23-107 were shipped to SGS Canada's laboratory in either
Lakefield, ON (vast majority),
Sudbury, ON (CV22-028, 029, 030),
or Burnaby, BC (CV22-031, 032,
033, and 034), for standard sample preparation (code PRP89) which
included drying at 105°C, crush to 75% passing 2 mm, riffle split
250 g, and pulverize 85% passing 75 microns. Core samples collected
from 2023 drill holes CV23-108 through 365 were shipped to SGS
Canada's laboratory in Val-d'Or,
QC, for standard sample preparation (code PRP89). Core
samples collected from 2024 drill holes were shipped to SGS
Canada's laboratory in either Val-d'Or,
QC, or Radisson, QC, for a
sample preparation (code PRP90 special) which includes drying at
105°C, crush to 90% passing 2 mm, riffle split 250 g, and pulverize
85% passing 75 microns.
All 2022, 2023, and 2024 (through drill hole CV24-526) core
sample pulps were shipped by air to SGS Canada's laboratory in
Burnaby, BC, where the samples
were homogenized and subsequently analyzed for multi-element
(including Li and Ta) using sodium peroxide fusion with ICP-AES/MS
finish (codes GE_ICP91A50 and GE_IMS91A50). SGS Canada is a commercial lab with the relevant
accreditations (ISO 17025) and is independent of the Company.
A Quality Assurance / Quality Control (QAQC) protocol following
industry best practices was incorporated into the drill programs
and included systematic insertion of quartz blanks and certified
reference materials into sample batches, as well as collection of
quarter-core duplicates (through hole CV23-190 only), at a rate of
approximately 5% each. Additionally, analysis of pulp-split and
coarse-split (through hole CV23-365 only) sample duplicates were
completed to assess analytical precision at different stages of the
laboratory preparation process, and external (secondary) laboratory
pulp-split duplicates were prepared at the primary lab for
subsequent check analysis and validation at a secondary lab (SGS
Canada in 2021, and ALS Canada in 2022, 2023, and 2024).
Channel samples collected in 2017 were shipped to SGS Canada's
laboratory in Lakefield, ON, for
standard preparation. Pulps were analyzed at SGS Canada's
laboratory in either Lakefield,
ON, (2017), or Burnaby, BC
(2022), for multi-element (including Li and Ta) using sodium
peroxide fusion with ICP-AES/MS finish. All subsequent channel
samples were shipped to Val-d'Or,
QC for standard sample preparation with the pulps shipped by
air to SGS Canada's laboratory in Burnaby, BC, where the samples were
homogenized and subsequently analyzed for multi-element (including
Li and Ta) using sodium peroxide fusion with ICP-AES/MS finish
(codes GE_ICP91A50 and GE_IMS91A50).
A QAQC protocol following industry best practices was
incorporated into the channel programs and included systematic
insertion of quartz blanks and certified reference materials into
sample batches.
CRITERIA USED FOR CLASSIFICATION
The Shaakichiuwaanaan resource classification has been completed
in accordance with the NI 43-101, JORC 2012, and CIM Definition
Standards for Mineral Resources and Reserves reporting guidelines.
All reported Mineral Resources have been constrained by conceptual
open-pit or underground mineable shapes to demonstrate reasonable
prospects for eventual economic extraction ("RPEEE").
Blocks were classified as Indicated when:
- Demonstrated geological continuity and minimum thickness of
2 m.
- The drill spacing was 70 m or
lower and meeting the minimum estimation criteria parameters.
- Grade continuity at the reported cut-off grade.
Blocks were classified Inferred when drill spacing was between
70 m and 140
m and meeting the minimum estimation criteria parameters.
Geological continuity and a minimum thickness of 2 m were also mandatory. There are no
measured classified blocks. Pegmatite dykes or extension with lower
level of information / confidence were also not classified.
Classification shapes are created around contiguous blocks at
the stated criteria with consideration for the selected mining
method. The Mineral Resource Estimate appropriately reflect the
view of the Competent Person.
ESTIMATION METHODOLOGY
Compositing was done every 1.0 m.
Unsampled intervals were assigned a grade of 0.0005% Li and 0.25
ppm Ta. Capping was done after compositing. Based on the
statistical analysis capping varies by lithological domain.
CV5 Parameters
For the spodumene-rich domain within the CV5 principal
pegmatite, no capping was required for Li2O, but
Ta2O5 was capped at 3,000 ppm. For the
feldspar-rich domain within the CV5 principal pegmatite, a capping
of 3.5% Li2O and 1,500 ppm Ta2O5
was applied. For the parallel dykes a capping of 5% Li2O
and 1,200 ppm Ta2O5 was applied.
Variography was done both in Leapfrog Edge and Supervisor. For
Li2O, a well-structured variogram model was obtained for
the CV5 principal pegmatite's spodumene-rich domain. For the CV5
principal pegmatite, both domains (spodumene-rich and feldspar-rich
domains) were estimated using ordinary kriging (OK), using Leapfrog
Edge.
For Ta2O5, the spodumene-rich domain and
the feldspar-rich domain within CV5 principal pegmatite did not
yield well-structured variograms. Therefore,
Ta2O5 was estimated using Inverse Distance
Squared (ID2).
The remaining pegmatite dykes at CV5 (8) domains did not yield
well-structured variograms for either Li2O and
Ta2O5 and therefore were estimated using
Inverse Distance Squared (ID2), also using Leapfrog
Edge.
Three (3) orientated search ellipsoids were used to select data
and interpolate Li2O and Ta2O5
grades in successively less restrictive passes. The ellipse sizes
and anisotropies were based on the variography, drillhole spacing,
and pegmatite geometry. The ellipsoids were 100 m x 50 m x
30 m, 200
m x 100 m x 60 m, and 400 m x
200 m x 120
m. For the first pass interpolation a minimum of five (5)
composites and a maximum of twelve (12) composites with a minimum
of two (2) holes were needed to interpolate. For the second and
third pass a minimum of three (3) composites with a maximum of
twelve (12) without a minimum per hole was used. Variable search
ellipse orientations (dynamic anisotropy) were used to interpolate
for the eight (8) parallel dykes. Spatial anisotropy of the dykes
is respected during estimation using Leapfrog Edge's Variable
Orientation tool. The search ellipse follows the trend of the
central reference plane of each dyke.
CV13 Parameters
For the CV13 Pegmatite dykes, it was determined that no capping
was required for Li2O, but Ta2O5
was capped at 1,500 ppm.
Variography analysis did not yield a well-structured variogram.
On CV13, Li2O and Ta2O5 were
estimated using ID2 in Leapfrog Edge.
Three (3) orientated search ellipsoids were used to select data
and interpolate Li2O and Ta2O5
grades in successively less restrictive passes. The ellipse sizes
and anisotropies were based on the variography, drillhole spacing,
and pegmatite geometry. The ellipsoids were 80 m x 60 m x
10 m, 160
m x 120 m x 20 m, and 320 m x
240 m x 40
m. For the first pass interpolation a minimum of five (5)
composites and a maximum of twelve (12) composites with a minimum
of two (2) holes were needed to interpolate. For the second and
third pass a minimum of three (3) composites with a maximum of
twelve (12) without a minimum per hole was used. Variable search
ellipse orientations (dynamic anisotropy) were used to interpolate
the dykes. Spatial anisotropy of the dykes is respected during
estimation using Leapfrog Edge's Variable Orientation tool. The
search ellipse follows the trend of the central reference plane of
each dyke.
Parent cells of 10 m x
5 m x 5
m, subblocked four (4) times in each direction (for minimum
subcells of 2.5 m in x, 1.25 m in y, and 1.25
m in z were used. Subblocks are triggered by the geological
model. Li2O and Ta2O5 grades are
estimated on the parent cells and automatically populated to
subblocks.
The CV5 and CV13 block model is rotated around the Z axis
(Leapfrog 340°). Hard boundaries between all the pegmatite domains
were used for all Li2O and Ta2O5
estimates. For CV5, the Mineral Resource Estimate includes blocks
within the pit shell above the cut-off grade of 0.40%
Li2O or all blocks within underground mining shapes
constructed with a 0.60% cut-off grade. For CV13, the Mineral
Resource Estimate includes blocks within the pit shell above the
cut-off grade of 0.40% Li2O or all blocks within
underground mining shapes constructed with a 0.80% cut-off
grade.
Validation of the block model was performed using Swath Plots,
nearest neighbours grade estimates, global means comparisons, and
by visual inspection in 3D and along plan views and
cross-sections.
CUT-OFF GRADE AND BASIS FOR SELECTION
The cut-off grade ("COG") adopted for the Mineral Resource
Estimate is 0.40% Li2O for open-pit resources (CV5 and
CV13), 0.60% Li2O for underground resources at CV5, and
0.80% Li2O for underground resources at CV13. It has
been determined based on operational cost estimates, primarily
through benchmarking, for mining (open-pit and underground
methods), tailings management, G&A, and concentrate transport
costs from the mine site to Bécancour, QC, as the base case.
Process recovery assumed a Dense Media Separation (DMS) only
operation at approximately 70% average recovery into a 5.5%
Li2O spodumene concentrate (Figure 37). A spodumene
concentrate price of US $1,500 was
assumed with USD/CAD exchange rate of 0.76. A royalty of 2% was
applied.
MINING & METALLURGICAL METHODS AND PARAMETERS, AND OTHER
MODIFYING FACTORS CONSIDERED
Mineral Resources that are not Mineral Reserves do not have
demonstrated economic viability. This estimate of Mineral Resources
may be materially affected by environmental, permitting, legal,
title, taxation, sociopolitical, marketing, economic, or other
relevant issues.
The extraction scenario constraint retained for the Mineral
Resource Estimate at the CV5 Spodumene Pegmatite is mainly
open-pit. A pit slope ranging between 45° and 53° was assumed,
resulting in a strip ratio of 8.3 (waste to minable resource) at a
revenue factor of 1. Underground long hole mining method accounts
for approximately 11% of CV5 resources.
The extraction scenario constraint retained for the maiden
Mineral Resource Estimate at the CV13 Spodumene Pegmatite is mainly
open-pit. A pit slope of 45° was assumed, resulting in a strip
ratio of 9.8 (waste to minable resource) at a revenue factor of 1.
Underground mining method accounts for approximately 7% of CV13
resources
The metallurgical assumptions are supported by metallurgical
test programs completed by SGS Canada at their Lakefield, ON, facility. The testwork included
Heavy Liquid Separation ("HLS") and magnetics, which has produced
6+% Li2O spodumene concentrates at >70% recovery on
drill core samples from both the CV5 and CV13 pegmatites. A
subsequent Dense Media Separation ("DMS") test on CV5 Spodumene
Pegmatite material returned a spodumene concentrate grading 5.8%
Li2O at 79% recovery, strongly indicating potential for
a DMS only operation to be applicable. For the Mineral Resource
conceptual mining shapes, based on a grade versus recovery curve of
the test work completed to date, an average recovery of
approximately 70% to produce a 5.5% Li2O spodumene
concentrate was used (Figure 37).
Various mandates required for advancing the Project towards
economic studies have been initiated, including but not limited to,
environmental baseline, metallurgy, geotechnical, geomechanics,
hydrogeology, hydrology, stakeholder engagement, geochemical
characterization, as well as concentrate transport and logistical
studies.
QUALIFIED/COMPETENT PERSON
The information in this news release that relates the Mineral
Resource Estimate for the Shaakichiuwaanaan Project (CV5 and CV13
spodumene pegmatites), as well as other relevant technical
information for the Property, is based on, and fairly represents,
information compiled by Mr. Todd
McCracken, P.Geo., who is a Qualified Person as defined by
NI 43-101, and member in good standing with the Ordre des Géologues
du Québec and with the Professional Geoscientists of Ontario. Mr. McCracken has reviewed and
approved the technical information in this news release.
Mr. McCracken is Director – Mining & Geology – Central Canada, of BBA Engineering Ltd. and is
independent of the Company. Mr. McCracken does not hold any
securities in the Company.
Mr. McCracken has sufficient experience, which is relevant to
the style of mineralization, type of deposit under consideration,
and to the activities being undertaken to qualify as a Competent
Person as described by the JORC Code, 2012. Mr. McCracken consents
to the inclusion in this news release of the matters based on his
information in the form and context in which it appears.
Table 4: Attributes for drill holes and channels included in the
Shaakichiuwaanaan MRE (CV5).
Hole ID
|
Hole
Type
|
Substrate
|
Total Depth
(m)
|
Azimuth
(°)
|
Dip
(°)
|
Easting
|
Northing
|
Elevation
(m)
|
Core Size
|
Pegmatite
|
CF21-001
|
DD
|
Land
|
229.1
|
340
|
-45
|
570312.0
|
5930632.4
|
382.9
|
NQ
|
CV5
|
CF21-002
|
DD
|
Land
|
274.2
|
340
|
-45
|
570417.4
|
5930652.0
|
382.9
|
NQ
|
CV5
|
CF21-003
|
DD
|
Land
|
106.1
|
160
|
-45
|
570284.8
|
5930718.2
|
377.5
|
NQ
|
CV5
|
CF21-004
|
DD
|
Land
|
148.3
|
340
|
-45
|
569797.9
|
5930446.4
|
379.7
|
NQ
|
CV5
|
CV22-015
|
DD
|
Ice
|
176.9
|
158
|
-45
|
570514.7
|
5930803.9
|
372.8
|
NQ
|
CV5
|
CV22-016
|
DD
|
Ice
|
252.1
|
158
|
-45
|
570476.4
|
5930897.7
|
372.9
|
NQ
|
CV5
|
CV22-017
|
DD
|
Ice
|
344.7
|
158
|
-45
|
571422.5
|
5931224.6
|
372.9
|
NQ
|
CV5
|
CV22-018
|
DD
|
Ice
|
149.9
|
158
|
-45
|
570604.1
|
5930841.2
|
372.9
|
NQ
|
CV5
|
CV22-019
|
DD
|
Ice
|
230.9
|
158
|
-45
|
570573.7
|
5930929.8
|
373.0
|
NQ
|
CV5
|
CV22-020
|
DD
|
Ice
|
203.8
|
338
|
-45
|
571532.0
|
5931099.6
|
372.9
|
NQ
|
CV5
|
CV22-021
|
DD
|
Ice
|
246.0
|
158
|
-45
|
571533.1
|
5931095.7
|
372.9
|
NQ
|
CV5
|
CV22-022
|
DD
|
Ice
|
184.0
|
158
|
-45
|
570695.2
|
5930878.2
|
372.9
|
NQ
|
CV5
|
CV22-023
|
DD
|
Ice
|
285.0
|
338
|
-45
|
571202.6
|
5930974.2
|
372.8
|
NQ
|
CV5
|
CV22-024
|
DD
|
Ice
|
156.0
|
158
|
-45
|
570791.5
|
5930912.6
|
372.7
|
NQ
|
CV5
|
CV22-025
|
DD
|
Ice
|
153.0
|
158
|
-45
|
570883.9
|
5930953.5
|
372.8
|
NQ
|
CV5
|
CV22-026
|
DD
|
Ice
|
156.0
|
0
|
-90
|
571203.1
|
5930973.7
|
372.8
|
NQ
|
CV5
|
CV22-027
|
DD
|
Ice
|
150.1
|
158
|
-45
|
570976.2
|
5930991.9
|
372.8
|
NQ
|
CV5
|
CV22-028
|
DD
|
Ice
|
291.0
|
158
|
-45
|
570940.9
|
5931083.5
|
372.9
|
NQ
|
CV5
|
CV22-029
|
DD
|
Ice
|
165.0
|
158
|
-45
|
571068.2
|
5931036.9
|
372.6
|
NQ
|
CV5
|
CV22-030
|
DD
|
Ice
|
258.0
|
158
|
-45
|
570385.1
|
5930855.6
|
372.8
|
NQ
|
CV5
|
CV22-031
|
DD
|
Ice
|
231.0
|
158
|
-45
|
570849.7
|
5931043.2
|
372.7
|
NQ
|
CV5
|
CV22-033
|
DD
|
Land
|
261.1
|
158
|
-45
|
571349.6
|
5931146.9
|
376.3
|
NQ
|
CV5
|
CV22-034
|
DD
|
Land
|
329.8
|
158
|
-55
|
570138.4
|
5930801.6
|
380.8
|
NQ
|
CV5
|
CV22-035
|
DD
|
Land
|
281.0
|
158
|
-45
|
571233.8
|
5931157.5
|
378.2
|
NQ
|
CV5
|
CV22-036
|
DD
|
Land
|
334.8
|
158
|
-45
|
570041.9
|
5930778.2
|
379.9
|
NQ
|
CV5
|
CV22-037
|
DD
|
Land
|
311.0
|
158
|
-45
|
571441.5
|
5931177.6
|
377.3
|
NQ
|
CV5
|
CV22-038
|
DD
|
Land
|
316.8
|
158
|
-45
|
569940.4
|
5930729.6
|
377.1
|
NQ
|
CV5
|
CV22-039
|
DD
|
Land
|
256.9
|
158
|
-45
|
571398.5
|
5931163.6
|
377.0
|
NQ
|
CV5
|
CV22-040
|
DD
|
Land
|
403.8
|
158
|
-45
|
569853.1
|
5930698.0
|
375.6
|
NQ
|
CV5
|
CV22-041
|
DD
|
Land
|
295.9
|
158
|
-45
|
571487.3
|
5931201.3
|
379.2
|
NQ
|
CV5
|
CV22-042
|
DD
|
Land
|
393.0
|
158
|
-65
|
571487.1
|
5931201.7
|
379.1
|
NQ
|
CV5
|
CV22-043
|
DD
|
Land
|
513.6
|
158
|
-59
|
569853.0
|
5930698.2
|
375.5
|
NQ
|
CV5
|
CV22-044
|
DD
|
Land
|
414.5
|
158
|
-45
|
571378.4
|
5931326.0
|
379.1
|
NQ
|
CV5
|
CV22-045
|
DD
|
Land
|
377.4
|
158
|
-45
|
569764.1
|
5930673.7
|
377.3
|
NQ
|
CV5
|
CV22-046
|
DD
|
Land
|
463.9
|
158
|
-50
|
570343.7
|
5930959.1
|
383.3
|
NQ
|
CV5
|
CV22-047
|
DD
|
Land
|
554.1
|
158
|
-59
|
571378.5
|
5931326.2
|
378.9
|
NQ
|
CV5
|
CV22-048
|
DD
|
Land
|
449.2
|
158
|
-45
|
570257.0
|
5930903.3
|
381.1
|
NQ
|
CV5
|
CV22-049
|
DD
|
Land
|
304.8
|
158
|
-45
|
571132.3
|
5931145.9
|
376.5
|
NQ
|
CV5
|
CV22-050
|
DD
|
Land
|
339.0
|
158
|
-60
|
571132.6
|
5931146.4
|
376.4
|
NQ
|
CV5
|
CV22-051
|
DD
|
Land
|
520.8
|
158
|
-58
|
570158.5
|
5930876.4
|
382.2
|
NQ
|
CV5
|
CV22-052
|
DD
|
Land
|
284.8
|
158
|
-45
|
571042.1
|
5931111.4
|
375.5
|
NQ
|
CV5
|
CV22-053
|
DD
|
Water
|
218.5
|
158
|
-45
|
570756.9
|
5930998.2
|
373.1
|
NQ
|
CV5
|
CV22-054
|
DD
|
Land
|
126.4
|
158
|
-58
|
570014.4
|
5930567.1
|
378.9
|
NQ
|
CV5
|
CV22-055
|
DD
|
Land
|
320.0
|
158
|
-60
|
571042.1
|
5931111.7
|
375.5
|
NQ
|
CV5
|
CV22-056
|
DD
|
Water
|
241.9
|
158
|
-45
|
570678.6
|
5930970.9
|
373.3
|
NQ
|
CV5
|
CV22-057
|
DD
|
Land
|
443.1
|
158
|
-45
|
570014.4
|
5930566.9
|
379.0
|
NQ
|
CV5
|
CV22-058
|
DD
|
Land
|
299.0
|
158
|
-45
|
571169.8
|
5931057.3
|
376.4
|
NQ
|
CV5
|
CV22-059
|
DD
|
Water
|
352.9
|
158
|
-45
|
570300.2
|
5930796.4
|
373.2
|
NQ
|
CV5
|
CV22-060
|
DD
|
Land
|
147.1
|
158
|
-45
|
570148.9
|
5930635.1
|
383.4
|
NQ
|
CV5
|
CV22-061
|
DD
|
Land
|
340.9
|
158
|
-45
|
571279.4
|
5931068.3
|
378.9
|
NQ
|
CV5
|
CV22-062
|
DD
|
Land
|
220.8
|
158
|
-45
|
570233.0
|
5930693.9
|
375.8
|
NQ
|
CV5
|
CV22-063
|
DD
|
Land
|
325.4
|
158
|
-45
|
571580.8
|
5931234.3
|
376.5
|
NQ
|
CV5
|
CV22-064
|
DD
|
Water
|
340.7
|
158
|
-53
|
570199.3
|
5930782.3
|
373.2
|
NQ
|
CV5
|
CV22-065
|
DD
|
Land
|
242.0
|
158
|
-45
|
570331.7
|
5930722.3
|
381.7
|
NQ
|
CV5
|
CV22-066
|
DD
|
Land
|
437.0
|
158
|
-48
|
571560.9
|
5931295.4
|
377.0
|
NQ
|
CV5
|
CV22-067
|
DD
|
Land
|
281.1
|
158
|
-45
|
570430.5
|
5930741.1
|
380.0
|
NQ
|
CV5
|
CV22-068
|
DD
|
Land
|
233.0
|
158
|
-45
|
569930.0
|
5930522.4
|
378.2
|
NQ
|
CV5
|
CV22-069
|
DD
|
Land
|
494.1
|
158
|
-65
|
571560.6
|
5931295.6
|
377.0
|
NQ
|
CV5
|
CV22-070
|
DD
|
Water
|
297.4
|
158
|
-45
|
570118.7
|
5930731.4
|
373.2
|
NQ
|
CV5
|
CV22-071
|
DD
|
Land
|
377.0
|
158
|
-45
|
569827.9
|
5930505.3
|
377.5
|
NQ
|
CV5
|
CV22-072
|
DD
|
Water
|
404.0
|
158
|
-45
|
570080.9
|
5930689.0
|
373.2
|
NQ
|
CV5
|
CV22-073
|
DD
|
Land
|
541.9
|
158
|
-52
|
571274.6
|
5931307.1
|
381.4
|
NQ
|
CV5
|
CV22-074
|
DD
|
Land
|
398.0
|
158
|
-45
|
569719.7
|
5930500.1
|
385.9
|
NQ
|
CV5
|
CV22-075
|
DD
|
Water
|
372.4
|
158
|
-45
|
569987.6
|
5930639.4
|
373.7
|
NQ
|
CV5
|
CV22-076
|
DD
|
Land
|
161.0
|
158
|
-45
|
571349.0
|
5930872.5
|
377.7
|
NQ
|
CV5
|
CV22-078
|
DD
|
Land
|
163.8
|
158
|
-65
|
571348.8
|
5930872.4
|
377.4
|
NQ
|
CV5
|
CV22-079
|
DD
|
Land
|
425.0
|
158
|
-45
|
571661.1
|
5931296.1
|
379.5
|
NQ
|
CV5
|
CV22-080
|
DD
|
Water
|
359.0
|
158
|
-45
|
569929.5
|
5930618.7
|
374.3
|
NQ
|
CV5
|
CV22-083
|
DD
|
Land
|
440.0
|
158
|
-65
|
571660.9
|
5931296.4
|
379.5
|
NQ
|
CV5
|
CV22-086
|
DD
|
Water
|
200.0
|
158
|
-45
|
571400.8
|
5931070.6
|
373.6
|
NQ
|
CV5
|
CV22-089
|
DD
|
Water
|
251.0
|
158
|
-45
|
571636.1
|
5931142.4
|
373.1
|
NQ
|
CV5
|
CV22-090
|
DD
|
Land
|
416.0
|
158
|
-45
|
571743.8
|
5931362.1
|
378.3
|
NQ
|
CV5
|
CV22-093
|
DD
|
Land
|
408.2
|
158
|
-65
|
571743.5
|
5931362.3
|
378.3
|
NQ
|
CV5
|
CV22-097
|
DD
|
Land
|
506.1
|
158
|
-72
|
571644.7
|
5931342.7
|
378.5
|
NQ
|
CV5
|
CV22-098
|
DD
|
Land
|
374.0
|
158
|
-45
|
570791.5
|
5931143.5
|
380.7
|
NQ
|
CV5
|
CV22-100
|
DD
|
Land
|
458.0
|
158
|
-45
|
571472.6
|
5931356.6
|
376.6
|
NQ
|
CV5
|
CV22-102
|
DD
|
Land
|
393.2
|
158
|
-45
|
570626.6
|
5931060.4
|
378.5
|
NQ
|
CV5
|
CV23-105
|
DD
|
Land
|
452.0
|
158
|
-65
|
571832.1
|
5931386.7
|
376.5
|
NQ
|
CV5
|
CV23-106
|
DD
|
Land
|
491.0
|
158
|
-65
|
571929.5
|
5931439.0
|
377.8
|
NQ
|
CV5
|
CV23-107
|
DD
|
Land
|
428.2
|
158
|
-65
|
572027.0
|
5931475.3
|
374.5
|
NQ
|
CV5
|
CV23-108
|
DD
|
Land
|
461.0
|
158
|
-65
|
572118.4
|
5931506.1
|
374.0
|
NQ
|
CV5
|
CV23-109
|
DD
|
Land
|
392.1
|
158
|
-45
|
571832.3
|
5931386.2
|
376.5
|
NQ
|
CV5
|
CV23-110
|
DD
|
Land
|
431.0
|
158
|
-45
|
571866.1
|
5931434.5
|
375.7
|
NQ
|
CV5
|
CV23-111
|
DD
|
Land
|
356.0
|
158
|
-45
|
572027.2
|
5931474.7
|
374.4
|
NQ
|
CV5
|
CV23-112
|
DD
|
Land
|
377.1
|
158
|
-45
|
571929.7
|
5931438.5
|
377.8
|
NQ
|
CV5
|
CV23-113
|
DD
|
Land
|
389.0
|
158
|
-45
|
572118.5
|
5931505.7
|
374.2
|
NQ
|
CV5
|
CV23-114
|
DD
|
Land
|
500.1
|
158
|
-55
|
571865.9
|
5931434.7
|
375.7
|
NQ
|
CV5
|
CV23-115
|
DD
|
Land
|
431.1
|
158
|
-45
|
572056.8
|
5931529.0
|
373.0
|
NQ
|
CV5
|
CV23-116
|
DD
|
Land
|
476.0
|
158
|
-65
|
572214.5
|
5931532.1
|
373.5
|
NQ
|
CV5
|
CV23-117
|
DD
|
Land
|
566.1
|
158
|
-75
|
571865.9
|
5931434.7
|
375.7
|
NQ
|
CV5
|
CV23-118
|
DD
|
Land
|
437.1
|
158
|
-45
|
572214.8
|
5931531.4
|
373.4
|
NQ
|
CV5
|
CV23-119
|
DD
|
Land
|
389.0
|
158
|
-45
|
572099.4
|
5931442.2
|
373.8
|
NQ
|
CV5
|
CV23-120
|
DD
|
Land
|
443.0
|
158
|
-45
|
572150.2
|
5931552.7
|
376.5
|
NQ
|
CV5
|
CV23-121
|
DD
|
Land
|
454.7
|
158
|
-48
|
571782.1
|
5931402.9
|
377.0
|
NQ
|
CV5
|
CV23-122
|
DD
|
Land
|
403.9
|
158
|
-45
|
572167.6
|
5931496.0
|
375.3
|
NQ
|
CV5
|
CV23-123
|
DD
|
Land
|
386.0
|
158
|
-45
|
571997.7
|
5931407.9
|
374.2
|
NQ
|
CV5
|
CV23-124
|
DD
|
Land
|
653.0
|
158
|
-45
|
571955.3
|
5931497.9
|
374.4
|
NQ
|
CV5
|
CV23-125
|
DD
|
Land
|
545.0
|
158
|
-65
|
572647.7
|
5931670.5
|
382.4
|
NQ
|
CV5
|
CV23-127
|
DD
|
Land
|
548.0
|
158
|
-59
|
571680.9
|
5931383.8
|
375.3
|
NQ
|
CV5
|
CV23-128
|
DD
|
Land
|
362.0
|
158
|
-45
|
571212.0
|
5931077.7
|
376.5
|
NQ
|
CV5
|
CV23-129
|
DD
|
Land
|
380.0
|
158
|
-45
|
571100.3
|
5931096.5
|
375.6
|
NQ
|
CV5
|
CV23-130
|
DD
|
Land
|
377.0
|
158
|
-45
|
571171.8
|
5931167.6
|
374.9
|
NQ
|
CV5
|
CV23-131
|
DD
|
Ice
|
454.9
|
158
|
-45
|
571907.3
|
5931366.9
|
373.2
|
NQ
|
CV5
|
CV23-132
|
DD
|
Land
|
374.0
|
158
|
-49
|
571068.0
|
5931148.3
|
374.7
|
NQ
|
CV5
|
CV23-133
|
DD
|
Land
|
604.8
|
220
|
-45
|
572646.6
|
5931668.7
|
382.6
|
NQ
|
CV5
|
CV23-134
|
DD
|
Land
|
331.0
|
158
|
-45
|
571281.9
|
5931163.8
|
379.2
|
NQ
|
CV5
|
CV23-135
|
DD
|
Land
|
360.6
|
158
|
-60
|
571171.6
|
5931167.9
|
374.9
|
NQ
|
CV5
|
CV23-136
|
DD
|
Ice
|
403.9
|
158
|
-45
|
572240.8
|
5931603.3
|
373.1
|
NQ
|
CV5
|
CV23-137
|
DD
|
Land
|
389.0
|
158
|
-65
|
571067.9
|
5931148.6
|
374.7
|
NQ
|
CV5
|
CV23-138
|
DD
|
Land
|
359.1
|
158
|
-60
|
571281.9
|
5931163.8
|
379.2
|
NQ
|
CV5
|
CV23-139
|
DD
|
Ice
|
565.9
|
158
|
-65
|
572396.1
|
5931617.8
|
372.9
|
NQ
|
CV5
|
CV23-140
|
DD
|
Ice
|
545.3
|
158
|
-65
|
572306.4
|
5931573.2
|
373.0
|
NQ
|
CV5
|
CV23-141
|
DD
|
Land
|
400.9
|
158
|
-65
|
571781.4
|
5931403.7
|
377.9
|
NQ
|
CV5
|
CV23-142
|
DD
|
Land
|
359.0
|
158
|
-73
|
571387.3
|
5931180.7
|
377.2
|
NQ
|
CV5
|
CV23-143
|
DD
|
Land
|
530.2
|
158
|
-45
|
572647.9
|
5931670.0
|
382.4
|
NQ
|
CV5
|
CV23-145
|
DD
|
Land
|
53.0
|
0
|
-90
|
569657.7
|
5930878.2
|
372.7
|
HQ
|
CV5
|
CV23-146
|
DD
|
Ice
|
416.0
|
158
|
-45
|
572306.4
|
5931573.2
|
373.0
|
NQ
|
CV5
|
CV23-148
|
DD
|
Land
|
332.0
|
158
|
-58
|
571387.4
|
5931180.3
|
377.3
|
NQ
|
CV5
|
CV23-150
|
DD
|
Land
|
302.1
|
0
|
-90
|
571426.9
|
5931160.9
|
376.7
|
NQ
|
CV5
|
CV23-151
|
DD
|
Ice
|
486.0
|
158
|
-45
|
572396.1
|
5931617.8
|
372.9
|
NQ
|
CV5
|
CV23-153
|
DD
|
Land
|
300.1
|
0
|
-90
|
571785.2
|
5931397.3
|
378.6
|
NQ
|
CV5
|
CV23-154
|
DD
|
Ice
|
574.9
|
158
|
-65
|
572487.3
|
5931652.3
|
372.9
|
NQ
|
CV5
|
CV23-156
|
DD
|
Land
|
581.3
|
176
|
-67
|
572647.4
|
5931670.4
|
382.6
|
NQ
|
CV5
|
CV23-157
|
DD
|
Land
|
278.1
|
0
|
-90
|
570694.6
|
5931128.2
|
379.0
|
NQ
|
CV5
|
CV23-159
|
DD
|
Land
|
50.0
|
0
|
-90
|
570520.0
|
5931135.3
|
375.6
|
HQ
|
CV5
|
CV23-160A
|
DD
|
Land
|
443.0
|
158
|
-45
|
569567.5
|
5930470.9
|
380.4
|
NQ
|
CV5
|
CV23-161
|
DD
|
Land
|
360.0
|
158
|
-45
|
569627.6
|
5930449.9
|
384.8
|
NQ
|
CV5
|
CV23-162
|
DD
|
Ice
|
482.0
|
158
|
-45
|
572487.3
|
5931652.3
|
372.9
|
NQ
|
CV5
|
CV23-164
|
DD
|
Land
|
200.0
|
0
|
-90
|
570020.1
|
5930773.5
|
378.1
|
NQ
|
CV5
|
CV23-165
|
DD
|
Land
|
555.1
|
165
|
-60
|
572647.7
|
5931669.8
|
382.4
|
NQ
|
CV5
|
CV23-166A
|
DD
|
Land
|
50.0
|
0
|
-90
|
569353.0
|
5930256.3
|
389.1
|
HQ
|
CV5
|
CV23-168A
|
DD
|
Ice
|
388.1
|
158
|
-47
|
571515.8
|
5931250.9
|
373.0
|
NQ
|
CV5
|
CV23-169
|
DD
|
Land
|
302.0
|
0
|
-90
|
569733.9
|
5930466.5
|
379.2
|
NQ
|
CV5
|
CV23-170
|
DD
|
Ice
|
431.6
|
158
|
-45
|
572461.9
|
5931596.5
|
373.0
|
NQ
|
CV5
|
CV23-171
|
DD
|
Land
|
373.4
|
158
|
-63
|
569568.8
|
5930470.2
|
380.1
|
NQ
|
CV5
|
CV23-172
|
DD
|
Land
|
404.0
|
158
|
-45
|
569479.9
|
5930448.2
|
384.1
|
NQ
|
CV5
|
CV23-173
|
DD
|
Ice
|
516.7
|
158
|
-65
|
572461.9
|
5931596.5
|
373.0
|
NQ
|
CV5
|
CV23-174
|
DD
|
Land
|
421.7
|
0
|
-90
|
569992.0
|
5930469.4
|
381.0
|
NQ
|
CV5
|
CV23-175
|
DD
|
Ice
|
458.0
|
158
|
-57
|
571316.1
|
5931230.2
|
372.9
|
NQ
|
CV5
|
CV23-176
|
DD
|
Land
|
434.0
|
158
|
-45
|
569388.0
|
5930399.5
|
386.2
|
NQ
|
CV5
|
CV23-177
|
DD
|
Ice
|
394.7
|
158
|
-45
|
571453.4
|
5931292.5
|
373.0
|
NQ
|
CV5
|
CV23-178
|
DD
|
Land
|
473.2
|
158
|
-62
|
569479.8
|
5930448.6
|
384.1
|
NQ
|
CV5
|
CV23-179
|
DD
|
Ice
|
437.0
|
158
|
-45
|
572368.8
|
5931547.6
|
372.9
|
NQ
|
CV5
|
CV23-180
|
DD
|
Land
|
379.6
|
150
|
-60
|
569387.8
|
5930400.0
|
386.2
|
NQ
|
CV5
|
CV23-181
|
DD
|
Ice
|
354.0
|
158
|
-46
|
571316.2
|
5931230.0
|
372.9
|
NQ
|
CV5
|
CV23-182
|
DD
|
Land
|
369.0
|
158
|
-45
|
569295.1
|
5930361.6
|
389.4
|
NQ
|
CV5
|
CV23-183
|
DD
|
Ice
|
477.1
|
158
|
-65
|
572368.7
|
5931548.1
|
372.8
|
NQ
|
CV5
|
CV23-184
|
DD
|
Land
|
417.4
|
158
|
-45
|
569198.6
|
5930332.0
|
392.7
|
NQ
|
CV5
|
CV23-185
|
DD
|
Ice
|
425.0
|
158
|
-60
|
571453.3
|
5931292.7
|
372.9
|
NQ
|
CV5
|
CV23-187
|
DD
|
Land
|
287.0
|
158
|
-45
|
569698.8
|
5930420.6
|
381.0
|
NQ
|
CV5
|
CV23-188
|
DD
|
Land
|
362.0
|
158
|
-60
|
569294.9
|
5930361.9
|
389.3
|
NQ
|
CV5
|
CV23-189
|
DD
|
Land
|
287.0
|
158
|
-45
|
571702.0
|
5931318.4
|
380.1
|
NQ
|
CV5
|
CV23-190
|
DD
|
Land
|
303.3
|
338
|
-45
|
569596.9
|
5930277.1
|
382.2
|
NQ
|
CV5
|
CV23-192
|
DD
|
Land
|
354.0
|
0
|
-90
|
570330.5
|
5930613.3
|
383.4
|
NQ
|
CV5
|
CV23-193
|
DD
|
Land
|
250.9
|
0
|
-90
|
569597.2
|
5930276.2
|
381.2
|
NQ
|
CV5
|
CV23-194
|
DD
|
Land
|
282.0
|
0
|
-90
|
570802.4
|
5930731.5
|
382.1
|
NQ
|
CV5
|
CV23-196
|
DD
|
Land
|
263.0
|
158
|
-45
|
569599.0
|
5930272.7
|
381.3
|
NQ
|
CV5
|
CV23-199
|
DD
|
Land
|
261.1
|
0
|
-90
|
570473.2
|
5930744.8
|
376.9
|
NQ
|
CV5
|
CV23-201
|
DD
|
Land
|
385.8
|
158
|
-45
|
569015.1
|
5930242.6
|
390.3
|
NQ
|
CV5
|
CV23-203
|
DD
|
Land
|
374.0
|
158
|
-45
|
569121.0
|
5930244.3
|
396.1
|
NQ
|
CV5
|
CV23-205
|
DD
|
Land
|
353.0
|
158
|
-60
|
569015.0
|
5930242.8
|
390.2
|
NQ
|
CV5
|
CV23-206
|
DD
|
Land
|
322.8
|
158
|
-60
|
569120.8
|
5930244.6
|
396.1
|
NQ
|
CV5
|
CV23-208
|
DD
|
Land
|
368.0
|
158
|
-45
|
568937.2
|
5930165.2
|
391.0
|
NQ
|
CV5
|
CV23-209
|
DD
|
Land
|
434.0
|
158
|
-45
|
569043.4
|
5930314.1
|
384.9
|
NQ
|
CV5
|
CV23-211
|
DD
|
Land
|
425.0
|
158
|
-60
|
568937.1
|
5930165.5
|
391.0
|
NQ
|
CV5
|
CV23-212
|
DD
|
Water
|
296.0
|
158
|
-45
|
571736.6
|
5931251.3
|
372.7
|
NQ
|
CV5
|
CV23-214
|
DD
|
Land
|
502.1
|
158
|
-55
|
569043.3
|
5930314.3
|
384.7
|
NQ
|
CV5
|
CV23-217
|
DD
|
Land
|
329.0
|
158
|
-45
|
568751.3
|
5930093.9
|
390.0
|
NQ
|
CV5
|
CV23-219
|
DD
|
Land
|
380.1
|
158
|
-45
|
568848.3
|
5930136.9
|
394.8
|
NQ
|
CV5
|
CV23-220
|
DD
|
Water
|
275.0
|
158
|
-45
|
571824.6
|
5931284.7
|
372.2
|
NQ
|
CV5
|
CV23-222
|
DD
|
Land
|
404.0
|
158
|
-65
|
568751.1
|
5930094.6
|
390.1
|
NQ
|
CV5
|
CV23-223
|
DD
|
Land
|
428.0
|
158
|
-60
|
568848.3
|
5930137.2
|
394.9
|
NQ
|
CV5
|
CV23-225
|
DD
|
Water
|
452.0
|
158
|
-45
|
571936.0
|
5931267.6
|
372.2
|
NQ
|
CV5
|
CV23-226
|
DD
|
Land
|
338.0
|
158
|
-45
|
568706.3
|
5930070.7
|
386.7
|
NQ
|
CV5
|
CV23-228
|
DD
|
Land
|
510.0
|
158
|
-80
|
568847.6
|
5930136.7
|
394.7
|
NQ
|
CV5
|
CV23-230
|
DD
|
Water
|
311.0
|
158
|
-45
|
570172.3
|
5930717.7
|
372.7
|
NQ
|
CV5
|
CV23-231
|
DD
|
Land
|
359.0
|
158
|
-65
|
568706.0
|
5930071.1
|
386.6
|
NQ
|
CV5
|
CV23-232
|
DD
|
Water
|
388.9
|
158
|
-45
|
572029.7
|
5931311.9
|
373.4
|
NQ
|
CV5
|
CV23-236
|
DD
|
Land
|
383.1
|
158
|
-45
|
568615.9
|
5930016.6
|
387.6
|
NQ
|
CV5
|
CV23-240
|
DD
|
Land
|
377.0
|
158
|
-45
|
568637.2
|
5930099.9
|
391.5
|
NQ
|
CV5
|
CV23-241
|
DD
|
Water
|
418.9
|
158
|
-62
|
570172.4
|
5930717.8
|
372.6
|
NQ
|
CV5
|
CV23-243
|
DD
|
Land
|
395.0
|
158
|
-65
|
568615.8
|
5930017.1
|
387.4
|
NQ
|
CV5
|
CV23-244
|
DD
|
Water
|
313.0
|
158
|
-45
|
572125.2
|
5931345.5
|
372.9
|
NQ
|
CV5
|
CV23-246
|
DD
|
Land
|
431.0
|
0
|
-90
|
570215.1
|
5930649.7
|
382.3
|
NQ
|
CV5
|
CV23-248
|
DD
|
Land
|
466.1
|
158
|
-65
|
568636.9
|
5930100.4
|
391.6
|
NQ
|
CV5
|
CV23-251
|
DD
|
Water
|
160.9
|
158
|
-45
|
570938.7
|
5930950.0
|
373.2
|
NQ
|
CV5
|
CV23-252
|
DD
|
Water
|
281.0
|
158
|
-45
|
572214.3
|
5931370.1
|
372.2
|
NQ
|
CV5
|
CV23-256
|
DD
|
Water
|
296.2
|
158
|
-45
|
571043.3
|
5930964.1
|
372.1
|
NQ
|
CV5
|
CV23-259
|
DD
|
Land
|
383.0
|
158
|
-45
|
568550.1
|
5930065.0
|
393.5
|
NQ
|
CV5
|
CV23-260
|
DD
|
Water
|
260.0
|
158
|
-45
|
572336.8
|
5931379.7
|
372.1
|
NQ
|
CV5
|
CV23-265
|
DD
|
Water
|
277.9
|
158
|
-45
|
571134.0
|
5931003.5
|
372.3
|
NQ
|
CV5
|
CV23-268
|
DD
|
Land
|
417.6
|
158
|
-65
|
568550.3
|
5930064.6
|
393.4
|
NQ
|
CV5
|
CV23-272A
|
DD
|
Water
|
410.2
|
158
|
-45
|
570328.8
|
5930856.6
|
372.8
|
NQ
|
CV5
|
CV23-273
|
DD
|
Land
|
359.0
|
158
|
-45
|
568457.9
|
5930020.1
|
392.5
|
NQ
|
CV5
|
CV23-274
|
DD
|
Water
|
226.4
|
158
|
-45
|
571199.9
|
5930974.4
|
372.6
|
NQ
|
CV5
|
CV23-279
|
DD
|
Water
|
227.7
|
158
|
-45
|
571250.2
|
5930988.5
|
373.1
|
NQ
|
CV5
|
CV23-283
|
DD
|
Land
|
362.0
|
158
|
-45
|
568526.0
|
5929989.7
|
387.7
|
NQ
|
CV5
|
CV23-285
|
DD
|
Water
|
469.9
|
158
|
-60
|
570328.4
|
5930856.8
|
372.8
|
NQ
|
CV5
|
CV23-287
|
DD
|
Water
|
176.0
|
158
|
-45
|
571336.6
|
5931031.0
|
372.8
|
NQ
|
CV5
|
CV23-290
|
DD
|
Land
|
443.0
|
158
|
-60
|
569197.2
|
5930336.0
|
392.0
|
NQ
|
CV5
|
CV23-291
|
DD
|
Water
|
169.2
|
158
|
-70
|
571336.7
|
5931031.4
|
372.3
|
NQ
|
CV5
|
CV23-292
|
DD
|
Land
|
389.1
|
158
|
-65
|
568457.4
|
5930020.9
|
392.5
|
NQ
|
CV5
|
CV23-295
|
DD
|
Land
|
362.9
|
158
|
-65
|
568526.0
|
5929990.0
|
387.7
|
NQ
|
CV5
|
CV23-297
|
DD
|
Water
|
194.0
|
158
|
-45
|
571682.5
|
5931113.0
|
372.5
|
NQ
|
CV5
|
CV23-298
|
DD
|
Water
|
440.1
|
158
|
-64
|
570449.3
|
5930831.3
|
372.7
|
NQ
|
CV5
|
CV23-303
|
DD
|
Land
|
290.9
|
158
|
-45
|
568922.1
|
5930064.4
|
395.4
|
NQ
|
CV5
|
CV23-307
|
DD
|
Land
|
357.3
|
285
|
-45
|
569814.2
|
5930403.6
|
382.3
|
NQ
|
CV5
|
CV23-308
|
DD
|
Water
|
171.2
|
158
|
-46
|
571479.7
|
5931087.4
|
372.9
|
NQ
|
CV5
|
CV23-313
|
DD
|
Water
|
371.0
|
158
|
-45
|
570449.7
|
5930830.8
|
372.7
|
NQ
|
CV5
|
CV23-314
|
DD
|
Water
|
359.0
|
338
|
-45
|
571479.2
|
5931088.9
|
372.1
|
NQ
|
CV5
|
CV23-317
|
DD
|
Land
|
431.9
|
338
|
-45
|
568922.9
|
5930067.3
|
395.1
|
NQ
|
CV5
|
CV23-321
|
DD
|
Land
|
252.1
|
158
|
-45
|
569813.6
|
5930404.2
|
381.9
|
NQ
|
CV5
|
CV23-325
|
DD
|
Water
|
238.9
|
158
|
-47
|
571440.8
|
5931045.2
|
372.2
|
NQ
|
CV5
|
CV23-327
|
DD
|
Water
|
386.0
|
158
|
-45
|
570541.7
|
5930871.4
|
372.7
|
NQ
|
CV5
|
CV23-329
|
DD
|
Land
|
277.8
|
310
|
-55
|
569812.8
|
5930405.2
|
381.9
|
NQ
|
CV5
|
CV23-331
|
DD
|
Land
|
423.0
|
158
|
-45
|
568415.4
|
5929988.0
|
395.9
|
NQ
|
CV5
|
CV23-335
|
DD
|
Water
|
263.0
|
158
|
-76
|
571440.5
|
5931063.1
|
372.7
|
NQ
|
CV5
|
CV23-337
|
DD
|
Land
|
427.9
|
338
|
-45
|
569717.2
|
5930368.0
|
382.0
|
NQ
|
CV5
|
CV23-338
|
DD
|
Water
|
176.0
|
158
|
-45
|
570761.8
|
5930850.3
|
372.9
|
NQ
|
CV5
|
CV23-340
|
DD
|
Water
|
212.0
|
158
|
-60
|
571760.9
|
5931197.6
|
372.9
|
NQ
|
CV5
|
CV23-342
|
DD
|
Water
|
212.0
|
158
|
-45
|
570631.7
|
5930908.8
|
372.8
|
NQ
|
CV5
|
CV23-344
|
DD
|
Land
|
530.2
|
158
|
-65
|
568415.3
|
5929988.4
|
395.9
|
NQ
|
CV5
|
CV23-347
|
DD
|
Land
|
230.0
|
158
|
-45
|
569717.7
|
5930367.4
|
382.0
|
NQ
|
CV5
|
CV23-349
|
DD
|
Water
|
133.9
|
158
|
-45
|
571865.8
|
5931191.5
|
373.4
|
NQ
|
CV5
|
CV23-352
|
DD
|
Land
|
227.0
|
158
|
-45
|
569626.0
|
5930335.2
|
381.7
|
NQ
|
CV5
|
CV23-354
|
DD
|
Land
|
296.0
|
158
|
-45
|
569536.2
|
5930296.9
|
381.9
|
NQ
|
CV5
|
CV23-357
|
DD
|
Land
|
328.8
|
158
|
-45
|
568371.0
|
5929961.8
|
392.7
|
NQ
|
CV5
|
CV23-359
|
DD
|
Land
|
251.1
|
158
|
-45
|
569443.3
|
5930256.2
|
383.8
|
NQ
|
CV5
|
CV23-362
|
DD
|
Land
|
356.1
|
338
|
-45
|
571560.3
|
5931009.3
|
373.3
|
NQ
|
CV5
|
CV23-363
|
DD
|
Land
|
218.0
|
158
|
-45
|
569347.1
|
5930221.6
|
389.4
|
NQ
|
CV5
|
CV23-364
|
DD
|
Land
|
401.0
|
158
|
-65
|
568370.8
|
5929962.2
|
392.6
|
NQ
|
CV5
|
CV24-366
|
DD
|
Land
|
489.4
|
158
|
-52
|
570954.3
|
5931181.8
|
376.3
|
NQ
|
CV5
|
CV24-367
|
DD
|
Land
|
459.2
|
160
|
-49
|
571374.2
|
5931330.7
|
378.5
|
NQ
|
CV5
|
CV24-368
|
DD
|
Land
|
493.9
|
158
|
-50
|
569790.2
|
5930721.4
|
375.2
|
NQ
|
CV5
|
CV24-370
|
DD
|
Land
|
511.8
|
158
|
-48
|
570073.6
|
5930820.6
|
381.2
|
NQ
|
CV5
|
CV24-371
|
DD
|
Land
|
561.9
|
158
|
-57
|
571477.3
|
5931353.1
|
374.7
|
NQ
|
CV5
|
CV24-372
|
DD
|
Land
|
487.9
|
158
|
-45
|
570218.9
|
5930863.1
|
375.2
|
NQ
|
CV5
|
CV24-373
|
DD
|
Land
|
479.2
|
160
|
-45
|
569832.6
|
5930629.6
|
373.0
|
NQ
|
CV5
|
CV24-374
|
DD
|
Land
|
470.0
|
158
|
-46
|
570693.3
|
5931027.8
|
373.3
|
NQ
|
CV5
|
CV24-375
|
DD
|
Land
|
302.1
|
158
|
-45
|
569251.7
|
5930186.6
|
395.0
|
NQ
|
CV5
|
CV24-376
|
DD
|
Land
|
583.7
|
158
|
-60
|
570036.0
|
5930779.8
|
377.9
|
NQ
|
CV5
|
CV24-377
|
DD
|
Land
|
451.9
|
158
|
-45
|
569911.5
|
5930690.1
|
374.0
|
NQ
|
CV5
|
CV24-378
|
DD
|
Land
|
493.0
|
158
|
-47
|
571569.3
|
5931385.6
|
374.0
|
NQ
|
CV5
|
CV24-379
|
DD
|
Land
|
613.9
|
158
|
-60
|
570693.4
|
5931028.3
|
373.3
|
NQ
|
CV5
|
CV24-380
|
DD
|
Land
|
559.9
|
158
|
-60
|
570218.9
|
5930863.3
|
374.9
|
NQ
|
CV5
|
CV24-381
|
DD
|
Land
|
302.1
|
158
|
-45
|
569160.9
|
5930149.9
|
395.0
|
NQ
|
CV5
|
CV24-382
|
DD
|
Land
|
506.0
|
158
|
-56
|
569911.6
|
5930690.5
|
373.9
|
NQ
|
CV5
|
CV24-383A
|
DD
|
Land
|
308.0
|
158
|
-45
|
569003.7
|
5930137.6
|
396.3
|
NQ
|
CV5
|
CV24-384
|
DD
|
Land
|
545.9
|
158
|
-57
|
569946.9
|
5930739.3
|
376.4
|
NQ
|
CV5
|
CV24-385
|
DD
|
Land
|
382.9
|
158
|
-45
|
569148.4
|
5930308.3
|
394.3
|
NQ
|
CV5
|
CV24-386
|
DD
|
Land
|
552.6
|
158
|
-58
|
571388.7
|
5931175.9
|
376.5
|
NQ
|
CV5
|
CV24-388
|
DD
|
Land
|
515.0
|
158
|
-58
|
571569.1
|
5931386.1
|
374.1
|
NQ
|
CV5
|
CV24-389
|
DD
|
Land
|
388.2
|
158
|
-45
|
569443.3
|
5930367.7
|
383.5
|
NQ
|
CV5
|
CV24-390
|
DD
|
Land
|
620.0
|
158
|
-45
|
570392.4
|
5930967.3
|
379.2
|
NQ
|
CV5
|
CV24-391
|
DD
|
Land
|
341.0
|
158
|
-45
|
569214.2
|
5930279.5
|
396.6
|
NQ
|
CV5
|
CV24-392
|
DD
|
Land
|
633.1
|
165
|
-58
|
571841.1
|
5931393.0
|
377.3
|
NQ
|
CV5
|
CV24-393
|
DD
|
Land
|
462.3
|
158
|
-75
|
569003.4
|
5930138.0
|
396.2
|
NQ
|
CV5
|
CV24-394
|
DD
|
Land
|
575.2
|
158
|
-47
|
571605.9
|
5931299.3
|
377.2
|
NQ
|
CV5
|
CV24-395
|
DD
|
Land
|
296.1
|
158
|
-45
|
569280.1
|
5930256.9
|
394.0
|
NQ
|
CV5
|
CV24-398
|
DD
|
Land
|
431.0
|
158
|
-45
|
569409.3
|
5930473.0
|
374.9
|
NQ
|
CV5
|
CV24-399
|
DD
|
Ice
|
527.0
|
158
|
-60
|
570600.6
|
5930984.8
|
372.1
|
NQ
|
CV5
|
CV24-400
|
DD
|
Land
|
551.0
|
158
|
-52
|
571388.7
|
5931175.6
|
376.5
|
NQ
|
CV5
|
CV24-401A
|
DD
|
Land
|
626.1
|
158
|
-58
|
572056.2
|
5931528.9
|
373.1
|
NQ
|
CV5
|
CV24-402
|
DD
|
Land
|
444.4
|
158
|
-75
|
569280.1
|
5930257.5
|
393.9
|
NQ
|
CV5
|
CV24-403
|
DD
|
Land
|
373.9
|
158
|
-45
|
569031.2
|
5930205.5
|
393.6
|
NQ
|
CV5
|
CV24-404
|
DD
|
Land
|
668.2
|
162
|
-59
|
571931.0
|
5931431.7
|
377.3
|
NQ
|
CV5
|
CV24-405
|
DD
|
Land
|
439.9
|
158
|
-60
|
571659.0
|
5931300.4
|
378.4
|
NQ
|
CV5
|
CV24-407
|
DD
|
Land
|
296.0
|
158
|
-45
|
569066.8
|
5930115.0
|
394.7
|
NQ
|
CV5
|
CV24-408
|
DD
|
Land
|
410.0
|
158
|
-45
|
569237.8
|
5930354.0
|
389.3
|
NQ
|
CV5
|
CV24-409
|
DD
|
Land
|
356.1
|
158
|
-45
|
569542.0
|
5930406.0
|
383.7
|
NQ
|
CV5
|
CV24-410
|
DD
|
Ice
|
609.0
|
158
|
-47
|
570507.2
|
5930955.1
|
372.0
|
NQ
|
CV5
|
CV24-413
|
DD
|
Ice
|
431.0
|
158
|
-62
|
570940.7
|
5931079.8
|
372.1
|
NQ
|
CV5
|
CV24-414
|
DD
|
Land
|
425.0
|
158
|
-45
|
569516.5
|
5930473.0
|
383.8
|
NQ
|
CV5
|
CV24-415A
|
DD
|
Land
|
576.4
|
158
|
-45
|
571679.3
|
5931388.3
|
374.3
|
NQ
|
CV5
|
CV24-416
|
DD
|
Land
|
334.8
|
158
|
-45
|
569358.6
|
5930330.1
|
389.7
|
NQ
|
CV5
|
CV24-418
|
DD
|
Ice
|
624.4
|
158
|
-47
|
570600.7
|
5930984.1
|
372.1
|
NQ
|
CV5
|
CV24-419
|
DD
|
Land
|
595.9
|
165
|
-45
|
572117.8
|
5931509.9
|
372.8
|
NQ
|
CV5
|
CV24-422
|
DD
|
Land
|
572.8
|
158
|
-58
|
571955.7
|
5931504.0
|
373.3
|
NQ
|
CV5
|
CV24-423A
|
DD
|
Land
|
329.0
|
158
|
-75
|
569358.9
|
5930329.9
|
389.6
|
NQ
|
CV5
|
CV24-424
|
DD
|
Land
|
389.0
|
158
|
-53
|
569615.3
|
5930495.5
|
378.1
|
NQ
|
CV5
|
CV24-426
|
DD
|
Ice
|
587.0
|
158
|
-45
|
571004.5
|
5931058.8
|
371.9
|
NQ
|
CV5
|
CV24-428
|
DD
|
Ice
|
543.1
|
158
|
-45
|
570728.4
|
5930940.4
|
372.1
|
NQ
|
CV5
|
CV24-430
|
DD
|
Land
|
361.9
|
158
|
-45
|
569187.9
|
5930215.3
|
397.6
|
NQ
|
CV5
|
CV24-431
|
DD
|
Land
|
352.9
|
338
|
-60
|
569800.9
|
5930431.0
|
379.5
|
NQ
|
CV5
|
CV24-433
|
DD
|
Ice
|
508.9
|
158
|
-48
|
570881.7
|
5931098.0
|
372.1
|
NQ
|
CV5
|
CV24-434
|
DD
|
Ice
|
467.8
|
158
|
-60
|
570507.2
|
5930955.1
|
372.0
|
NQ
|
CV5
|
CV24-435
|
DD
|
Land
|
502.9
|
158
|
-60
|
572117.8
|
5931509.9
|
372.8
|
NQ
|
CV5
|
CV24-437
|
DD
|
Land
|
433.9
|
158
|
-55
|
571679.2
|
5931388.7
|
374.3
|
NQ
|
CV5
|
CV24-438
|
DD
|
Ice
|
408.3
|
158
|
-48
|
571812.0
|
5931329.7
|
372.0
|
NQ
|
CV5
|
CV24-440
|
DD
|
Land
|
438.5
|
158
|
-75
|
569187.5
|
5930215.9
|
397.5
|
NQ
|
CV5
|
CV24-441
|
DD
|
Ice
|
342.2
|
158
|
-65
|
571004.7
|
5931058.3
|
372.0
|
NQ
|
CV5
|
CV24-442
|
DD
|
Land
|
299.1
|
158
|
-87
|
569802.0
|
5930429.6
|
379.4
|
NQ
|
CV5
|
CV24-443
|
DD
|
Ice
|
383.2
|
158
|
-45
|
570818.0
|
5930984.2
|
372.0
|
NQ
|
CV5
|
CV24-445
|
DD
|
Ice
|
295.3
|
158
|
-45
|
571968.9
|
5931339.0
|
371.9
|
NQ
|
CV5
|
CV24-447
|
DD
|
Land
|
308.4
|
130
|
-55
|
571152.3
|
5931101.1
|
375.1
|
NQ
|
CV5
|
CV24-448
|
DD
|
Land
|
341.9
|
158
|
-75
|
569802.0
|
5930430.0
|
379.4
|
NQ
|
CV5
|
CV24-449
|
DD
|
Ice
|
291.8
|
158
|
-62
|
570881.7
|
5931098.3
|
372.0
|
NQ
|
CV5
|
CV24-450
|
DD
|
Land
|
299.0
|
160
|
-45
|
569864.8
|
5930545.1
|
373.3
|
NQ
|
CV5
|
CV24-451
|
DD
|
Ice
|
503.0
|
158
|
-45
|
571771.2
|
5931288.6
|
372.0
|
NQ
|
CV5
|
CV24-452
|
DD
|
Land
|
505.9
|
145
|
-50
|
571679.5
|
5931388.0
|
374.3
|
HQ
|
CV5
|
CV24-455
|
DD
|
Ice
|
379.8
|
158
|
-45
|
570909.9
|
5931018.4
|
372.0
|
NQ
|
CV5
|
CV24-456
|
DD
|
Land
|
456.9
|
200
|
-55
|
570174.5
|
5930836.0
|
378.3
|
NQ
|
CV5
|
CV24-458
|
DD
|
Ice
|
328.0
|
152
|
-62
|
571968.6
|
5931339.6
|
371.9
|
NQ
|
CV5
|
CV24-460
|
DD
|
Ice
|
263.0
|
158
|
-45
|
571650.2
|
5931198.3
|
372.0
|
NQ
|
CV5
|
CV24-462
|
DD
|
Land
|
299.5
|
158
|
-45
|
569773.4
|
5930503.0
|
377.2
|
NQ
|
CV5
|
CV24-463
|
DD
|
Land
|
337.9
|
158
|
-45
|
570612.9
|
5930686.0
|
378.8
|
NQ
|
CV5
|
CV24-465
|
DD
|
Ice
|
325.0
|
158
|
-48
|
571877.8
|
5931300.2
|
372.1
|
NQ
|
CV5
|
CV24-466
|
DD
|
Ice
|
530.3
|
338
|
-45
|
571841.0
|
5931124.0
|
372.0
|
NQ
|
CV5
|
CV24-467
|
DD
|
Ice
|
539.2
|
158
|
-45
|
570782.1
|
5931075.0
|
372.3
|
NQ
|
CV5
|
CV24-468
|
DD
|
Ice
|
461.0
|
158
|
-46
|
571695.3
|
5931217.0
|
372.0
|
NQ
|
CV5
|
CV24-469
|
DD
|
Land
|
409.9
|
40
|
-60
|
571572.0
|
5930953.4
|
373.2
|
NQ
|
CV5
|
CV24-472
|
DD
|
Land
|
355.9
|
338
|
-45
|
570503.6
|
5930694.8
|
379.8
|
NQ
|
CV5
|
CV24-473
|
DD
|
Ice
|
359.0
|
153
|
-58
|
571514.3
|
5931262.1
|
371.9
|
NQ
|
CV5
|
CV24-474
|
DD
|
Land
|
223.9
|
159
|
-46
|
569207.2
|
5930170.9
|
396.0
|
NQ
|
CV5
|
CV24-475
|
DD
|
Ice
|
280.1
|
158
|
-45
|
572062.4
|
5931376.6
|
371.9
|
NQ
|
CV5
|
CV24-476
|
DD
|
Land
|
557.0
|
154
|
-55
|
570170.7
|
5930834.1
|
378.4
|
NQ
|
CV5
|
CV24-479
|
DD
|
Land
|
467.1
|
16
|
-55
|
570355.0
|
5930476.9
|
379.2
|
NQ
|
CV5
|
CV24-480
|
DD
|
Land
|
560.3
|
158
|
-65
|
571994.4
|
5931554.1
|
372.2
|
NQ
|
CV5
|
CV24-481
|
DD
|
Land
|
272.3
|
157
|
-46
|
569311.2
|
5930294.6
|
391.0
|
NQ
|
CV5
|
CV24-482
|
DD
|
Ice
|
305.0
|
158
|
-55
|
572062.4
|
5931376.0
|
371.9
|
NQ
|
CV5
|
CV24-485
|
DD
|
Ice
|
365.0
|
150
|
-45
|
571515.2
|
5931261.4
|
371.9
|
NQ
|
CV5
|
CV24-486
|
DD
|
Ice
|
299.0
|
156
|
-45
|
571551.6
|
5931169.2
|
372.0
|
NQ
|
CV5
|
CV24-488
|
DD
|
Land
|
197.0
|
160
|
-45
|
569373.9
|
5930278.5
|
390.3
|
NQ
|
CV5
|
CV24-489
|
DD
|
Land
|
356.0
|
158
|
-45
|
570204.3
|
5930636.1
|
382.0
|
NQ
|
CV5
|
CV24-490
|
DD
|
Ice
|
314.3
|
158
|
-47
|
572155.1
|
5931412.9
|
372.1
|
NQ
|
CV5
|
CV24-493
|
DD
|
Land
|
218.1
|
160
|
-45
|
569649.4
|
5930384.4
|
381.0
|
NQ
|
CV5
|
CV24-494
|
DD
|
Land
|
439.9
|
158
|
-60
|
570227.9
|
5930714.7
|
374.8
|
NQ
|
CV5
|
CV24-495
|
DD
|
Ice
|
230.3
|
158
|
-45
|
571803.4
|
5931216.2
|
372.0
|
NQ
|
CV5
|
CV24-496
|
DD
|
Land
|
509.0
|
113
|
-55
|
571529.1
|
5931440.2
|
390.7
|
NQ
|
CV5
|
CV24-500
|
DD
|
Land
|
512.1
|
158
|
-65
|
571932.1
|
5931649.5
|
378.7
|
NQ
|
CV5
|
CV24-501A
|
DD
|
Land
|
403.2
|
155
|
-49
|
572023.6
|
5931471.2
|
374.6
|
NQ
|
CV5
|
CV24-502
|
DD
|
Land
|
476.5
|
145
|
-52
|
570360.1
|
5930766.7
|
374.0
|
NQ
|
CV5
|
CV24-503
|
DD
|
Land
|
533.1
|
160
|
-45
|
570305.6
|
5930884.3
|
372.1
|
NQ
|
CV5
|
CV24-504
|
DD
|
Land
|
302.4
|
158
|
-45
|
570181.3
|
5930561.3
|
385.0
|
NQ
|
CV5
|
CV24-505
|
DD
|
Land
|
581.0
|
158
|
-58
|
569994.1
|
5930753.1
|
376.5
|
NQ
|
CV5
|
CV24-509
|
DD
|
Land
|
425.4
|
157
|
-53
|
570262.4
|
5930743.7
|
373.9
|
NQ
|
CV5
|
CV24-512
|
DD
|
Land
|
317.0
|
158
|
-46
|
570054.0
|
5930596.6
|
376.9
|
NQ
|
CV5
|
CV24-514
|
DD
|
Land
|
601.3
|
158
|
-50
|
570459.7
|
5931100.8
|
378.2
|
NQ
|
CV5
|
CV24-515
|
DD
|
Ice
|
424.4
|
160
|
-58
|
572240.8
|
5931602.7
|
371.8
|
NQ
|
CV5
|
CV24-516
|
DD
|
Land
|
517.9
|
170
|
-45
|
572564.5
|
5931732.2
|
375.0
|
NQ
|
CV5
|
CV24-517
|
DD
|
Land
|
428.1
|
152
|
-56
|
570402.3
|
5930773.8
|
374.1
|
NQ
|
CV5
|
CV24-521
|
DD
|
Land
|
504.1
|
158
|
-45
|
568928.0
|
5930328.5
|
377.9
|
NQ
|
CV5
|
CV24-522
|
DD
|
Land
|
260.2
|
159
|
-45
|
570073.4
|
5930544.4
|
379.3
|
NQ
|
CV5
|
CV24-526
|
DD
|
Land
|
442.9
|
158
|
-45
|
569994.4
|
5930752.6
|
376.4
|
NQ
|
CV5
|
|
|
|
|
|
|
|
|
|
|
|
CH22-001
|
CH
|
Land
|
2.1
|
342
|
-7
|
571342.6
|
5930847.1
|
378.4
|
n/a
|
CV5
|
CH22-002
|
CH
|
Land
|
3.9
|
165
|
-31
|
571340.7
|
5930846.3
|
378.5
|
n/a
|
CV5
|
CH22-003
|
CH
|
Land
|
1.9
|
346
|
-6
|
571377.5
|
5930850.9
|
377.9
|
n/a
|
CV5
|
CH22-007
|
CH
|
Land
|
7.3
|
340
|
-30
|
570151.2
|
5930541.4
|
385.3
|
n/a
|
CV5
|
CV1-CH01
|
CH
|
Land
|
8.0
|
0
|
0
|
571477.3
|
5931121.0
|
373.4
|
n/a
|
CV5
|
CV1-CH02
|
CH
|
Land
|
6.0
|
0
|
0
|
571393.9
|
5931098.8
|
381.9
|
n/a
|
CV5
|
CV1-CH03
|
CH
|
Land
|
11.0
|
0
|
0
|
571381.0
|
5931103.9
|
382.2
|
n/a
|
CV5
|
CV1-CH04
|
CH
|
Land
|
4.0
|
0
|
0
|
571340.5
|
5931110.5
|
381.2
|
n/a
|
CV5
|
CV1-CH05
|
CH
|
Land
|
11.0
|
0
|
0
|
571435.1
|
5931107.2
|
380.6
|
n/a
|
CV5
|
CV2-CH01
|
CH
|
Land
|
4.0
|
338
|
0
|
571299.6
|
5931156.1
|
379.6
|
n/a
|
CV5
|
CV2-CH02
|
CH
|
Land
|
4.0
|
355
|
0
|
571274.9
|
5931156.7
|
380.0
|
n/a
|
CV5
|
(1) Coordinate
system NAD83 / UTM zone 18N; (2) DD = diamond drill, CH =
channel; (3) DD azimuths and dips presented are those 'planned' and
may vary off collar/downhole
|
Table 5: Attributes for drill holes and channels included in the
Shaakichiuwaanaan MRE (CV13).
Hole
ID
|
Hole
Type
|
Substrate
|
Total
Depth
(m)
|
Azimuth
(°)
|
Dip
(°)
|
Easting
|
Northing
|
Elevation
(m)
|
Core
Size
|
Pegmatite
|
CV22-077
|
DD
|
Land
|
209.0
|
200
|
-45
|
564974.5
|
5927821.5
|
390.9
|
NQ
|
CV13
|
CV22-081
|
DD
|
Land
|
50.0
|
200
|
-80
|
564974.4
|
5927822.2
|
390.9
|
NQ
|
CV13
|
CV22-082
|
DD
|
Land
|
186.7
|
200
|
-45
|
565010.2
|
5927856.7
|
398.5
|
NQ
|
CV13
|
CV22-084
|
DD
|
Land
|
247.8
|
200
|
-80
|
565010.3
|
5927857.6
|
398.5
|
NQ
|
CV13
|
CV22-085
|
DD
|
Land
|
201.1
|
200
|
-45
|
565050.0
|
5927857.9
|
399.2
|
NQ
|
CV13
|
CV22-088
|
DD
|
Land
|
185.0
|
140
|
-45
|
565052.8
|
5927858.4
|
399.0
|
NQ
|
CV13
|
CV22-091
|
DD
|
Land
|
200.0
|
135
|
-45
|
565249.5
|
5928035.3
|
429.6
|
NQ
|
CV13
|
CV22-092
|
DD
|
Land
|
260.0
|
145
|
-45
|
565267.4
|
5928079.4
|
434.6
|
NQ
|
CV13
|
CV22-095
|
DD
|
Land
|
58.9
|
145
|
-65
|
565266.9
|
5928080.0
|
434.7
|
NQ
|
CV13
|
CV22-096
|
DD
|
Land
|
218.0
|
140
|
-45
|
565731.7
|
5928451.9
|
386.0
|
NQ
|
CV13
|
CV22-099
|
DD
|
Land
|
248.1
|
140
|
-45
|
565795.5
|
5928473.1
|
382.7
|
NQ
|
CV13
|
CV22-101
|
DD
|
Land
|
245.1
|
140
|
-65
|
565795.1
|
5928473.5
|
382.7
|
NQ
|
CV13
|
CV22-103
|
DD
|
Land
|
269.0
|
200
|
-45
|
564406.1
|
5927962.1
|
403.8
|
NQ
|
CV13
|
CV22-104
|
DD
|
Land
|
68.0
|
200
|
-65
|
564406.1
|
5927962.5
|
403.7
|
NQ
|
CV13
|
CV23-191
|
DD
|
Land
|
308.2
|
170
|
-45
|
565125.9
|
5928034.9
|
432.4
|
NQ
|
CV13
|
CV23-195
|
DD
|
Land
|
308.0
|
0
|
-90
|
565125.7
|
5928035.6
|
432.3
|
NQ
|
CV13
|
CV23-198
|
DD
|
Land
|
98.0
|
140
|
-80
|
565126.2
|
5928036.0
|
432.4
|
NQ
|
CV13
|
CV23-200
|
DD
|
Land
|
250.9
|
100
|
-45
|
565128.0
|
5928036.2
|
432.4
|
NQ
|
CV13
|
CV23-202
|
DD
|
Land
|
302.0
|
220
|
-45
|
565054.8
|
5927953.3
|
419.4
|
NQ
|
CV13
|
CV23-204
|
DD
|
Land
|
262.9
|
130
|
-80
|
565057.6
|
5927954.3
|
419.2
|
NQ
|
CV13
|
CV23-207
|
DD
|
Land
|
278.0
|
140
|
-45
|
565058.1
|
5927953.0
|
419.0
|
NQ
|
CV13
|
CV23-210
|
DD
|
Land
|
272.0
|
210
|
-55
|
564875.9
|
5927914.8
|
409.7
|
NQ
|
CV13
|
CV23-213
|
DD
|
Land
|
209.0
|
200
|
-85
|
564876.6
|
5927915.3
|
409.7
|
NQ
|
CV13
|
CV23-215
|
DD
|
Land
|
215.0
|
150
|
-45
|
564878.4
|
5927914.4
|
409.5
|
NQ
|
CV13
|
CV23-216
|
DD
|
Land
|
209.1
|
200
|
-75
|
564841.1
|
5927978.0
|
415.4
|
NQ
|
CV13
|
CV23-218
|
DD
|
Land
|
254.1
|
200
|
-45
|
564841.3
|
5927978.6
|
415.4
|
NQ
|
CV13
|
CV23-221
|
DD
|
Land
|
218.0
|
0
|
-90
|
564841.4
|
5927979.0
|
415.3
|
NQ
|
CV13
|
CV23-224
|
DD
|
Land
|
308.0
|
200
|
-45
|
564748.9
|
5928008.0
|
414.1
|
NQ
|
CV13
|
CV23-227
|
DD
|
Land
|
237.5
|
200
|
-75
|
564749.1
|
5928009.1
|
414.2
|
NQ
|
CV13
|
CV23-229
|
DD
|
Land
|
254.1
|
200
|
-75
|
564657.3
|
5928047.4
|
412.2
|
NQ
|
CV13
|
CV23-233
|
DD
|
Land
|
179.0
|
200
|
-75
|
564561.0
|
5928082.7
|
411.1
|
NQ
|
CV13
|
CV23-235
|
DD
|
Land
|
203.2
|
200
|
-45
|
564560.9
|
5928082.2
|
411.0
|
NQ
|
CV13
|
CV23-238
|
DD
|
Land
|
176.2
|
200
|
-45
|
564466.0
|
5928113.6
|
409.4
|
NQ
|
CV13
|
CV23-242
|
DD
|
Land
|
161.0
|
200
|
-75
|
564466.5
|
5928114.2
|
409.4
|
NQ
|
CV13
|
CV23-245A
|
DD
|
Land
|
142.9
|
200
|
-45
|
564339.9
|
5928050.1
|
405.0
|
NQ
|
CV13
|
CV23-249
|
DD
|
Land
|
224.0
|
160
|
-45
|
564934.8
|
5927940.8
|
417.2
|
NQ
|
CV13
|
CV23-250
|
DD
|
Land
|
116.0
|
200
|
-85
|
564340.5
|
5928051.4
|
405.0
|
NQ
|
CV13
|
CV23-253
|
DD
|
Land
|
161.1
|
200
|
-45
|
564619.1
|
5927947.5
|
402.2
|
NQ
|
CV13
|
CV23-255
|
DD
|
Land
|
131.2
|
80
|
-45
|
564936.2
|
5927944.4
|
417.7
|
NQ
|
CV13
|
CV23-257
|
DD
|
Land
|
161.0
|
200
|
-85
|
564619.4
|
5927948.4
|
402.2
|
NQ
|
CV13
|
CV23-258
|
DD
|
Land
|
296.0
|
0
|
-90
|
564935.3
|
5927944.3
|
417.6
|
NQ
|
CV13
|
CV23-263
|
DD
|
Land
|
86.0
|
200
|
-45
|
564434.5
|
5928018.3
|
401.2
|
NQ
|
CV13
|
CV23-266
|
DD
|
Land
|
127.9
|
300
|
-65
|
565064.9
|
5928000.9
|
429.2
|
NQ
|
CV13
|
CV23-269
|
DD
|
Land
|
83.0
|
200
|
-85
|
564434.9
|
5928019.4
|
401.6
|
NQ
|
CV13
|
CV23-270
|
DD
|
Land
|
119.0
|
200
|
-45
|
564527.9
|
5927979.6
|
404.0
|
NQ
|
CV13
|
CV23-271
|
DD
|
Land
|
149.2
|
110
|
-75
|
565068.5
|
5927999.1
|
429.0
|
NQ
|
CV13
|
CV23-276
|
DD
|
Land
|
182.0
|
140
|
-45
|
565180.4
|
5928160.3
|
441.7
|
NQ
|
CV13
|
CV23-277
|
DD
|
Land
|
287.0
|
200
|
-85
|
564528.6
|
5927980.6
|
404.1
|
NQ
|
CV13
|
CV23-280
|
DD
|
Land
|
209.0
|
200
|
-45
|
565178.1
|
5928159.7
|
441.5
|
NQ
|
CV13
|
CV23-282
|
DD
|
Land
|
184.9
|
70
|
-45
|
565181.4
|
5928163.8
|
441.8
|
NQ
|
CV13
|
CV23-286
|
DD
|
Land
|
95.0
|
200
|
-45
|
564804.5
|
5927873.3
|
402.3
|
NQ
|
CV13
|
CV23-288
|
DD
|
Land
|
314.0
|
0
|
-90
|
565180.8
|
5928163.4
|
441.8
|
NQ
|
CV13
|
CV23-293
|
DD
|
Land
|
133.9
|
140
|
-45
|
565325.0
|
5928117.9
|
430.8
|
NQ
|
CV13
|
CV23-294
|
DD
|
Land
|
170.2
|
200
|
-85
|
564804.9
|
5927874.2
|
402.3
|
NQ
|
CV13
|
CV23-299
|
DD
|
Land
|
113.1
|
0
|
-90
|
565324.1
|
5928118.8
|
430.9
|
NQ
|
CV13
|
CV23-300
|
DD
|
Land
|
146.2
|
200
|
-45
|
564715.7
|
5927915.2
|
404.2
|
NQ
|
CV13
|
CV23-301
|
DD
|
Land
|
113.0
|
140
|
-45
|
565359.3
|
5928206.8
|
435.5
|
NQ
|
CV13
|
CV23-302
|
DD
|
Land
|
125.0
|
200
|
-85
|
564716.3
|
5927916.3
|
404.2
|
NQ
|
CV13
|
CV23-305
|
DD
|
Land
|
149.0
|
200
|
-60
|
564373.9
|
5928148.8
|
408.0
|
NQ
|
CV13
|
CV23-306
|
DD
|
Land
|
209.0
|
140
|
-90
|
565358.6
|
5928207.5
|
435.6
|
NQ
|
CV13
|
CV23-309
|
DD
|
Land
|
79.9
|
200
|
-45
|
564244.9
|
5928082.6
|
404.2
|
NQ
|
CV13
|
CV23-311
|
DD
|
Land
|
421.9
|
140
|
-45
|
565394.5
|
5928309.7
|
414.3
|
NQ
|
CV13
|
CV23-312
|
DD
|
Land
|
149.0
|
200
|
-90
|
564373.8
|
5928148.9
|
408.1
|
NQ
|
CV13
|
CV23-316
|
DD
|
Land
|
164.0
|
200
|
-60
|
564278.9
|
5928174.3
|
406.9
|
NQ
|
CV13
|
CV23-318
|
DD
|
Land
|
98.0
|
200
|
-90
|
564245.2
|
5928083.3
|
404.0
|
NQ
|
CV13
|
CV23-319
|
DD
|
Land
|
149.1
|
200
|
-45
|
564147.1
|
5928113.7
|
400.9
|
NQ
|
CV13
|
CV23-320
|
DD
|
Land
|
176.1
|
200
|
-90
|
564279.1
|
5928174.7
|
406.9
|
NQ
|
CV13
|
CV23-322
|
DD
|
Land
|
404.1
|
140
|
-90
|
565393.9
|
5928310.4
|
414.9
|
NQ
|
CV13
|
CV23-323
|
DD
|
Land
|
143.0
|
200
|
-60
|
564180.4
|
5928212.8
|
411.6
|
NQ
|
CV13
|
CV23-324
|
DD
|
Land
|
197.2
|
200
|
-90
|
564147.4
|
5928114.3
|
400.9
|
NQ
|
CV13
|
CV23-328
|
DD
|
Land
|
432.0
|
200
|
-45
|
564057.2
|
5928154.3
|
403.9
|
NQ
|
CV13
|
CV23-330
|
DD
|
Land
|
215.1
|
200
|
-90
|
564180.7
|
5928213.2
|
412.1
|
NQ
|
CV13
|
CV23-332
|
DD
|
Land
|
427.9
|
140
|
-45
|
565421.2
|
5928393.4
|
405.5
|
NQ
|
CV13
|
CV23-336
|
DD
|
Land
|
149.0
|
200
|
-60
|
564091.2
|
5928247.1
|
412.0
|
NQ
|
CV13
|
CV23-339
|
DD
|
Land
|
158.1
|
200
|
-90
|
564091.5
|
5928247.4
|
412.4
|
NQ
|
CV13
|
CV23-343
|
DD
|
Land
|
194.2
|
200
|
-60
|
564000.8
|
5928282.3
|
408.5
|
NQ
|
CV13
|
CV23-346
|
DD
|
Land
|
164.1
|
200
|
-90
|
564057.4
|
5928154.8
|
403.8
|
NQ
|
CV13
|
CV23-348
|
DD
|
Land
|
386.0
|
140
|
-90
|
565420.9
|
5928393.8
|
405.3
|
NQ
|
CV13
|
CV23-350
|
DD
|
Land
|
104.0
|
200
|
-45
|
563965.0
|
5928183.6
|
406.1
|
NQ
|
CV13
|
CV23-351
|
DD
|
Land
|
164.1
|
200
|
-90
|
564000.9
|
5928282.6
|
408.4
|
NQ
|
CV13
|
CV23-353
|
DD
|
Land
|
137.9
|
200
|
-90
|
563965.1
|
5928184.3
|
406.1
|
NQ
|
CV13
|
CV23-355
|
DD
|
Land
|
245.0
|
200
|
-45
|
563865.2
|
5928215.9
|
401.4
|
NQ
|
CV13
|
CV23-356
|
DD
|
Land
|
180.7
|
200
|
-60
|
563906.9
|
5928314.1
|
400.8
|
NQ
|
CV13
|
CV23-358
|
DD
|
Land
|
311.2
|
140
|
-45
|
565552.3
|
5928455.0
|
394.9
|
NQ
|
CV13
|
CV23-360
|
DD
|
Land
|
140.0
|
200
|
-90
|
563865.5
|
5928216.7
|
401.4
|
NQ
|
CV13
|
CV23-361
|
DD
|
Land
|
208.8
|
200
|
-90
|
563907.1
|
5928314.9
|
400.7
|
NQ
|
CV13
|
CV23-365
|
DD
|
Land
|
322.9
|
140
|
-90
|
565551.9
|
5928455.4
|
394.9
|
NQ
|
CV13
|
CV24-396
|
DD
|
Land
|
357.1
|
140
|
-65
|
565052.7
|
5928112.1
|
434.0
|
NQ
|
CV13
|
CV24-397
|
DD
|
Land
|
428.0
|
140
|
-45
|
565424.4
|
5928248.6
|
421.7
|
NQ
|
CV13
|
CV24-406
|
DD
|
Land
|
128.0
|
70
|
-55
|
565054.1
|
5928112.6
|
434.1
|
NQ
|
CV13
|
CV24-411
|
DD
|
Land
|
356.1
|
310
|
-70
|
565055.0
|
5928114.7
|
434.1
|
NQ
|
CV13
|
CV24-412
|
DD
|
Land
|
348.4
|
140
|
-90
|
565423.8
|
5928249.4
|
421.5
|
NQ
|
CV13
|
CV24-417
|
DD
|
Land
|
196.9
|
20
|
-45
|
565058.0
|
5928116.1
|
434.3
|
NQ
|
CV13
|
CV24-420
|
DD
|
Land
|
305.0
|
200
|
-60
|
564988.6
|
5928082.2
|
429.5
|
NQ
|
CV13
|
CV24-421
|
DD
|
Land
|
475.9
|
140
|
-45
|
565433.9
|
5928165.4
|
416.5
|
NQ
|
CV13
|
CV24-425
|
DD
|
Land
|
209.0
|
200
|
-90
|
564988.8
|
5928082.7
|
429.4
|
NQ
|
CV13
|
CV24-427
|
DD
|
Land
|
331.6
|
200
|
-60
|
564895.7
|
5928116.7
|
426.4
|
NQ
|
CV13
|
CV24-429
|
DD
|
Land
|
515.2
|
140
|
-65
|
565433.8
|
5928165.9
|
416.3
|
NQ
|
CV13
|
CV24-432
|
DD
|
Land
|
278.0
|
200
|
-90
|
564895.9
|
5928117.1
|
426.3
|
NQ
|
CV13
|
CV24-436
|
DD
|
Land
|
220.9
|
200
|
-60
|
564799.1
|
5928146.2
|
422.6
|
NQ
|
CV13
|
CV24-439
|
DD
|
Land
|
326.5
|
140
|
-45
|
565515.1
|
5928210.6
|
412.7
|
NQ
|
CV13
|
CV24-444
|
DD
|
Land
|
248.0
|
200
|
-90
|
564799.0
|
5928146.2
|
422.6
|
NQ
|
CV13
|
CV24-446
|
DD
|
Land
|
286.6
|
140
|
-90
|
565514.5
|
5928211.3
|
412.6
|
NQ
|
CV13
|
CV24-453
|
DD
|
Land
|
160.9
|
140
|
-45
|
565199.0
|
5927986.7
|
422.8
|
NQ
|
CV13
|
CV24-454
|
DD
|
Land
|
209.0
|
200
|
-60
|
564708.5
|
5928185.6
|
421.7
|
NQ
|
CV13
|
CV24-457
|
DD
|
Land
|
143.0
|
140
|
-45
|
565145.6
|
5927920.0
|
407.6
|
NQ
|
CV13
|
CV24-461
|
DD
|
Land
|
345.7
|
140
|
-45
|
565434.8
|
5928491.5
|
394.0
|
NQ
|
CV13
|
CV24-464
|
DD
|
Land
|
262.9
|
200
|
-90
|
564708.7
|
5928186.2
|
421.6
|
NQ
|
CV13
|
CV24-470
|
DD
|
Land
|
281.3
|
320
|
-80
|
565430.9
|
5928494.3
|
393.9
|
NQ
|
CV13
|
CV24-471
|
DD
|
Land
|
212.1
|
200
|
-60
|
564613.7
|
5928220.3
|
420.4
|
NQ
|
CV13
|
CV24-477
|
DD
|
Land
|
332.1
|
140
|
-45
|
565529.8
|
5928379.0
|
399.3
|
NQ
|
CV13
|
CV24-478
|
DD
|
Land
|
248.0
|
200
|
-90
|
564613.9
|
5928220.6
|
420.3
|
NQ
|
CV13
|
CV24-483
|
DD
|
Land
|
185.0
|
200
|
-60
|
564518.5
|
5928253.3
|
414.9
|
NQ
|
CV13
|
CV24-484
|
DD
|
Land
|
263.2
|
140
|
-45
|
565645.4
|
5928423.4
|
392.3
|
NQ
|
CV13
|
CV24-487
|
DD
|
Land
|
308.1
|
140
|
-45
|
565807.6
|
5928565.2
|
378.9
|
NQ
|
CV13
|
CV24-491
|
DD
|
Land
|
248.0
|
200
|
-90
|
564518.7
|
5928253.8
|
415.0
|
NQ
|
CV13
|
CV24-492
|
DD
|
Land
|
290.4
|
140
|
-45
|
565697.4
|
5928512.1
|
385.7
|
NQ
|
CV13
|
CV24-497
|
DD
|
Land
|
230.0
|
200
|
-60
|
564427.0
|
5928280.4
|
409.6
|
NQ
|
CV13
|
CV24-498
|
DD
|
Land
|
218.0
|
140
|
-45
|
565467.1
|
5928559.6
|
387.9
|
NQ
|
CV13
|
CV24-499
|
DD
|
Land
|
176.2
|
320
|
-55
|
565803.9
|
5928569.8
|
379.0
|
NQ
|
CV13
|
CV24-506
|
DD
|
Land
|
218.2
|
200
|
-90
|
564427.3
|
5928280.9
|
409.6
|
NQ
|
CV13
|
CV24-507
|
DD
|
Land
|
187.0
|
0
|
-90
|
565466.6
|
5928560.1
|
387.7
|
NQ
|
CV13
|
CV24-508
|
DD
|
Land
|
152.0
|
140
|
-45
|
565710.4
|
5928599.6
|
382.2
|
NQ
|
CV13
|
CV24-510
|
DD
|
Land
|
239.0
|
270
|
-55
|
565458.5
|
5928561.1
|
387.8
|
NQ
|
CV13
|
CV24-511
|
DD
|
Land
|
200.0
|
200
|
-60
|
564329.6
|
5928311.9
|
413.2
|
NQ
|
CV13
|
CV24-513
|
DD
|
Land
|
171.2
|
320
|
-75
|
565707.2
|
5928604.4
|
381.9
|
NQ
|
CV13
|
CV24-518
|
DD
|
Land
|
199.9
|
200
|
-90
|
564329.8
|
5928312.3
|
413.2
|
NQ
|
CV13
|
CV24-519
|
DD
|
Land
|
248.0
|
140
|
-45
|
565599.7
|
5928537.4
|
385.4
|
NQ
|
CV13
|
CV24-520
|
DD
|
Land
|
243.7
|
320
|
-60
|
565459.7
|
5928564.3
|
387.4
|
NQ
|
CV13
|
CV24-523
|
DD
|
Land
|
203.2
|
200
|
-60
|
564237.2
|
5928354.7
|
414.2
|
NQ
|
CV13
|
CV24-524
|
DD
|
Land
|
209.0
|
20
|
-60
|
565464.9
|
5928560.5
|
387.7
|
NQ
|
CV13
|
CV24-525
|
DD
|
Land
|
161.0
|
320
|
-75
|
565596.8
|
5928540.8
|
385.1
|
NQ
|
CV13
|
|
|
|
|
|
|
|
|
|
|
|
CH22-008
|
CH
|
Land
|
3.04
|
134
|
-10
|
565327.4
|
5927991.9
|
412.9
|
n/a
|
CV13
|
CH22-009
|
CH
|
Land
|
3.46
|
314
|
-20
|
565327.4
|
5927991.9
|
412.9
|
n/a
|
CV13
|
CH22-010
|
CH
|
Land
|
5.24
|
341
|
-20
|
565319.8
|
5927982.1
|
412.8
|
n/a
|
CV13
|
CH22-011
|
CH
|
Land
|
1.49
|
164
|
-7
|
565290.2
|
5927974.0
|
411.6
|
n/a
|
CV13
|
CH22-012
|
CH
|
Land
|
5.31
|
344
|
-18
|
565290.2
|
5927974.0
|
411.6
|
n/a
|
CV13
|
CH22-013
|
CH
|
Land
|
2.47
|
168
|
-13
|
565276.5
|
5927969.0
|
409.5
|
n/a
|
CV13
|
CH22-014
|
CH
|
Land
|
2.77
|
348
|
-10
|
565276.5
|
5927969.0
|
409.5
|
n/a
|
CV13
|
CH22-015
|
CH
|
Land
|
1.3
|
151
|
-20
|
565261.4
|
5927948.5
|
406.3
|
n/a
|
CV13
|
CH22-016
|
CH
|
Land
|
0.8
|
331
|
-5
|
565261.4
|
5927948.5
|
406.3
|
n/a
|
CV13
|
CH22-017
|
CH
|
Land
|
13.1
|
161
|
-15
|
565008.4
|
5927781.9
|
396.5
|
n/a
|
CV13
|
CH22-018
|
CH
|
Land
|
1.63
|
7
|
-5
|
564999.3
|
5927781.8
|
397.9
|
n/a
|
CV13
|
CH22-019
|
CH
|
Land
|
8.87
|
187
|
-10
|
564999.3
|
5927781.8
|
397.9
|
n/a
|
CV13
|
CH22-020
|
CH
|
Land
|
3.49
|
1
|
-10
|
564958.2
|
5927787.0
|
398.7
|
n/a
|
CV13
|
CH22-021
|
CH
|
Land
|
3.57
|
181
|
-10
|
564958.2
|
5927787.0
|
398.7
|
n/a
|
CV13
|
CH22-022
|
CH
|
Land
|
8.42
|
14
|
-15
|
564933.1
|
5927793.5
|
397.7
|
n/a
|
CV13
|
CH22-023
|
CH
|
Land
|
2.96
|
356
|
-30
|
564859.2
|
5927784.0
|
392.7
|
n/a
|
CV13
|
CH22-024
|
CH
|
Land
|
5.81
|
176
|
-10
|
564859.2
|
5927784.0
|
392.7
|
n/a
|
CV13
|
CH22-025
|
CH
|
Land
|
4.93
|
185
|
-20
|
563820.5
|
5928027.6
|
401.3
|
n/a
|
CV13
|
CH22-026
|
CH
|
Land
|
9.22
|
15
|
-20
|
563820.5
|
5928027.6
|
401.3
|
n/a
|
CV13
|
CH22-027
|
CH
|
Land
|
3.5
|
2
|
-10
|
564543.7
|
5927827.8
|
394.5
|
n/a
|
CV13
|
CH22-028
|
CH
|
Land
|
1.63
|
182
|
-25
|
564543.7
|
5927827.8
|
394.5
|
n/a
|
CV13
|
CH22-029
|
CH
|
Land
|
3.77
|
344
|
-8
|
564430.7
|
5927891.8
|
400.2
|
n/a
|
CV13
|
CH22-030
|
CH
|
Land
|
1.09
|
164
|
-25
|
564430.7
|
5927891.8
|
400.2
|
n/a
|
CV13
|
CH22-031
|
CH
|
Land
|
3.14
|
340
|
-20
|
564313.4
|
5927935.4
|
402.1
|
n/a
|
CV13
|
CH22-032
|
CH
|
Land
|
1.2
|
160
|
-5
|
564313.4
|
5927935.4
|
402.1
|
n/a
|
CV13
|
CH22-033
|
CH
|
Land
|
1.73
|
349
|
-15
|
564317.7
|
5927922.5
|
403.6
|
n/a
|
CV13
|
CH22-034
|
CH
|
Land
|
1.46
|
169
|
-25
|
564317.7
|
5927922.5
|
403.6
|
n/a
|
CV13
|
CH22-035
|
CH
|
Land
|
1.62
|
166
|
-10
|
564318.2
|
5927920.4
|
403.4
|
n/a
|
CV13
|
CH22-036
|
CH
|
Land
|
9.27
|
340
|
-10
|
564229.2
|
5927961.3
|
403.6
|
n/a
|
CV13
|
CH22-037
|
CH
|
Land
|
4.82
|
160
|
-5
|
564229.2
|
5927961.3
|
403.6
|
n/a
|
CV13
|
CH23-058
|
CH
|
Land
|
6.73
|
200
|
-20
|
564428.8
|
5927877.0
|
397.6
|
n/a
|
CV13
|
CH23-059
|
CH
|
Land
|
16.7
|
185
|
-25
|
564395.4
|
5927899.8
|
401.0
|
n/a
|
CV13
|
CH23-060
|
CH
|
Land
|
5.11
|
200
|
-10
|
564381.8
|
5927886.9
|
398.6
|
n/a
|
CV13
|
CH23-061
|
CH
|
Land
|
13.41
|
200
|
-15
|
564356.1
|
5927920.0
|
402.7
|
n/a
|
CV13
|
CH23-062
|
CH
|
Land
|
14.86
|
180
|
-15
|
565813.8
|
5928472.6
|
379.6
|
n/a
|
CV13
|
CH23-063
|
CH
|
Land
|
8.47
|
180
|
-21
|
565793.4
|
5928462.2
|
380.7
|
n/a
|
CV13
|
CH23-064
|
CH
|
Land
|
13.9
|
160
|
-15
|
565774.8
|
5928454.4
|
382.6
|
n/a
|
CV13
|
CH23-065
|
CH
|
Land
|
27.92
|
180
|
-15
|
565757.6
|
5928430.0
|
384.6
|
n/a
|
CV13
|
CH23-066
|
CH
|
Land
|
11.93
|
180
|
-10
|
565743.4
|
5928420.7
|
386.2
|
n/a
|
CV13
|
CH23-067
|
CH
|
Land
|
4.52
|
180
|
-15
|
565668.3
|
5928403.0
|
390.8
|
n/a
|
CV13
|
CH23-068
|
CH
|
Land
|
6.21
|
148
|
-18
|
565459.7
|
5928331.7
|
404.0
|
n/a
|
CV13
|
CH23-069
|
CH
|
Land
|
6.77
|
26
|
-36
|
565393.2
|
5928283.7
|
418.1
|
n/a
|
CV13
|
CH23-070
|
CH
|
Land
|
3.66
|
5
|
-5
|
565414.5
|
5928118.5
|
414.7
|
n/a
|
CV13
|
CH23-071
|
CH
|
Land
|
6.43
|
160
|
-25
|
565358.5
|
5928074.7
|
415.8
|
n/a
|
CV13
|
CH24-072
|
CH
|
Land
|
1.71
|
2
|
-5
|
563770.0
|
5928053.0
|
394.0
|
n/a
|
CV13
|
CH24-073
|
CH
|
Land
|
6.32
|
5
|
-2
|
563798.0
|
5928046.0
|
394.0
|
n/a
|
CV13
|
CH24-074
|
CH
|
Land
|
5.92
|
192
|
0
|
563809.0
|
5928065.0
|
398.0
|
n/a
|
CV13
|
CH24-075
|
CH
|
Land
|
9.14
|
193
|
0
|
563872.0
|
5928036.0
|
390.0
|
n/a
|
CV13
|
CH24-076
|
CH
|
Land
|
14.98
|
194
|
-5
|
563868.0
|
5928029.0
|
397.0
|
n/a
|
CV13
|
CH24-077
|
CH
|
Land
|
1.82
|
206
|
-40
|
563952.0
|
5928001.0
|
385.0
|
n/a
|
CV13
|
CH24-078
|
CH
|
Land
|
5.62
|
183
|
-19
|
564022.0
|
5927996.0
|
384.0
|
n/a
|
CV13
|
CH24-079
|
CH
|
Land
|
10.98
|
194
|
-5
|
564098.0
|
5927988.0
|
401.0
|
n/a
|
CV13
|
CH24-080
|
CH
|
Land
|
8.9
|
189
|
0
|
564206.0
|
5927971.0
|
397.0
|
n/a
|
CV13
|
CH24-081
|
CH
|
Land
|
6.4
|
208
|
-2
|
564245.0
|
5927965.0
|
396.0
|
n/a
|
CV13
|
(1) Coordinate
system NAD83 / UTM zone 18N; (2) DD = diamond drill, CH =
channel; (3) DD azimuths and dips presented are those 'planned' and
may vary off collar/downhole.
|
APPENDIX 1 – JORC CODE 2012 TABLE 1 (ASX LISTING RULE
5.8.2)
Section 1 – Sampling Techniques and Data
Criteria
|
JORC Code explanation
|
Commentary
|
Sampling
techniques
|
• Nature and
quality of sampling (eg cut channels, random chips, or specific
specialized industry standard measurement tools appropriate to the
minerals under investigation, such as down hole gamma sondes, or
handheld XRF instruments, etc). These examples should not be taken
as limiting the broad meaning of sampling.
• Include
reference to measures taken to ensure sample representivity and the
appropriate calibration of any measurement tools or systems
used.
• Aspects of the
determination of mineralization that are Material to the Public
Report.
• In cases where
'industry standard' work has been done this would be relatively
simple (eg 'reverse circulation drilling was used to obtain 1 m
samples from which 3 kg was pulverized to produce a 30 g charge for
fire assay'). In other cases more explanation may be required, such
as where there is coarse gold that has inherent sampling problems.
Unusual commodities or mineralization types (eg submarine nodules)
may warrant disclosure of detailed information.
|
• Core sampling
protocols meet industry standard practices.
• Core sampling
is guided by lithology as determined during geological logging
(i.e., by a geologist). All pegmatite intervals are sampled in
their entirety (half-core), regardless if spodumene mineralization
is noted or not (in order to ensure an unbiased sampling approach)
in addition to ~1 to 3 m of sampling into the adjacent host
rock (dependent on pegmatite interval length) to "bookend" the
sampled pegmatite.
• The minimum
individual core sample length is typically 0.3 to 0.5 m and
the maximum sample length is typically 2.0 m. Targeted
individual pegmatite sample lengths are 1.0 to
1.5 m.
• All drill core
is oriented to maximum foliation prior to logging and sampling and
is cut with a core saw into half-core pieces, with one half-core
collected for assay, and the other half-core remaining in the box
for reference.
• Core samples
collected from 2021 drill holes were shipped to Activation
Laboratories in Ancaster, ON, for standard sample preparation (code
RX1) which included crushing to 80% passing 10 mesh, followed by a
250 g riffle split and pulverizing to 95% passing 105 microns. All
2021 core sample pulps were analyzed, at the same lab, for
multi-element (including lithium) by four-acid digestion with
ICP-OES finish (package 1F2) and tantalum by INAA (code 5B), with
any samples returning >8,000 ppm Li by 1F2 reanalyzed for
Li by code 8-4 Acid ICP Assay.
• Core samples
collected from 2022 and 2023 drill holes CV22-015 through CV23-107
were shipped to SGS Canada's laboratory in either Lakefield, ON
(vast majority), Sudbury, ON (CV22-028, 029, 030), or Burnaby, BC
(CV22-031, 032, 033, and 034), for standard sample preparation
(code PRP89) which included drying at 105°C, crush to 75% passing 2
mm, riffle split 250 g, and pulverize 85% passing 75 microns. Core
samples collected from 2023 drill holes CV23-108 through 365 were
shipped to SGS Canada's laboratory in Val-d'Or, QC, for standard
sample preparation (code PRP89).
• Core samples
collected from 2024 drill holes were shipped to SGS Canada's
laboratory in Val-d'Or, QC, or Radisson, QC, for sample preparation
(code PRP90 special) which included drying at 105°C, crush to 90%
passing 2 mm, riffle split 250 g, and pulverize 85% passing 75
microns.
• All drill core
sample pulps from 2022, 2023, and 2024 were shipped by air to SGS
Canada's laboratory in Burnaby, BC, where the samples were
homogenized and subsequently analyzed for multi-element (including
Li and Ta) using sodium peroxide fusion with ICP-AES/MS finish
(codes GE_ICP91A50 and GE_IMS91A50).
• Channel
sampling followed best industry practices with a 3 to 5 cm wide,
saw-cut channel completed across the pegmatite outcrop as
practical, perpendicular to the interpreted pegmatite strike.
Samples were collected at ~1 m contiguous intervals with the
channel bearing noted, and GPS coordinate collected at the start
and end points of the channel.
• All channel
samples collected were shipped to SGS Canada's laboratory in
Lakefield, ON, or Val-d'Or, QC, for standard preparation. Pulps
were analyzed at SGS Canada's laboratory in either Lakefield, ON,
(2017), or Burnaby, BC (2022, 2023, and 2024), for multi-element
(including Li and Ta) using sodium peroxide fusion with ICP-AES/MS
finish.
|
Drilling
techniques
|
• Drill type (eg
core, reverse circulation, open-hole hammer, rotary air blast,
auger, Bangka, sonic, etc) and details (eg core diameter, triple or
standard tube, depth of diamond tails, face-sampling bit or other
type, whether core is oriented and if so, by what method,
etc).
|
• NQ or HQ size
core diamond drilling was completed for all holes. Core was not
oriented. However, downhole OTV-ATV surveys were completed to
various depths multiple holes to assess overall
structure.
• The quality of
the channel sampling allowed the channels to be treated as
horizontal drill holes for the purposes of modelling and resource
estimation.
|
Drill sample
recovery
|
• Method of
recording and assessing core and chip sample recoveries and results
assessed.
• Measures taken
to maximize sample recovery and ensure representative nature of the
samples.
• Whether a
relationship exists between sample recovery and grade and whether
sample bias may have occurred due to preferential loss/gain of
fine/coarse material.
|
• All drill core
was geotechnically logged following industry standard practices,
and include TCR, RQD, ISRM, and Q-Method (since mid-winter 2023).
Core recovery is very good and typically exceeds 90%.
• Channel samples
were not geotechnically logged. Channel recovery was effectively
100%.
|
Logging
|
• Whether core
and chip samples have been geologically and geotechnically logged
to a level of detail to support appropriate Mineral Resource
estimation, mining studies and metallurgical studies.
• Whether logging
is qualitative or quantitative in nature. Core (or costean,
channel, etc) photography.
• The total
length and percentage of the relevant intersections
logged.
|
• Upon receipt at
the core shack, all drill core is pieced together, oriented to
maximum foliation, metre marked, geotechnically logged (including
structure), alteration logged, geologically logged, and sample
logged on an individual sample basis. Core box photos are also
collected of all core drilled, regardless of perceived
mineralization. Specific gravity measurements of pegmatite are also
collected at systematic intervals for all pegmatite drill core
using the water immersion method, as well as select host rock drill
core.
• Channel samples
were geologically logged upon collection on an individual sample
basis.
• The logging is
qualitative by nature, and includes estimates of spodumene grain
size, inclusions, and model mineral estimates.
• These logging
practices meet or exceed current industry standard
practices.
|
Sub-sampling
techniques and
sample preparation
|
• If core,
whether cut or sawn and whether quarter, half or all core
taken.
• If non-core,
whether riffled, tube sampled, rotary split, etc and whether
sampled wet or dry.
• For all sample
types, the nature, quality and appropriateness of the sample
preparation technique.
• Quality control
procedures adopted for all sub-sampling stages to maximize
representivity of samples.
• Measures taken
to ensure that the sampling is representative of the in situ
material collected, including for instance results for field
duplicate/second-half sampling.
• Whether sample
sizes are appropriate to the grain size of the material being
sampled.
|
• Drill core
sampling follows industry best practices. Drill core was saw-cut
with half-core sent for geochemical analysis and half-core
remaining in the box for reference. The same side of the core was
sampled to maintain representativeness.
• Channels were
saw-cut with the full channel being sent for analysis at ~1 m
sample intervals.
• Sample sizes
are considered appropriate for the material being
assayed.
• A Quality
Assurance / Quality Control (QAQC) protocol following industry best
practices was incorporated into the drill programs and included
systematic insertion of quartz blanks and certified reference
materials into sample batches, as well as collection of
quarter-core duplicates (through hole CV23-190 only), at a rate of
approximately 5% each. Additionally, analysis of pulp-split and
coarse-split (through hole CV23-365 only) sample duplicates were
completed to assess analytical precision at different stages of the
laboratory preparation process, and external (secondary) laboratory
pulp-split duplicates were prepared at the primary lab for
subsequent check analysis and validation at a secondary lab (SGS
Canada in 2021, and ALS Canada in 2022, 2023, and 2024). All
protocols employed are considered appropriate for the sample type
and nature of mineralization and are considered the optimal
approach for maintaining representativeness in sampling.
|
Quality of assay
data and laboratory
tests
|
• The nature,
quality and appropriateness of the assaying and laboratory
procedures used and whether the technique is considered partial or
total.
• For geophysical
tools, spectrometers, handheld XRF instruments, etc, the parameters
used in determining the analysis including instrument make and
model, reading times, calibrations factors applied and their
derivation, etc.
• Nature of
quality control procedures adopted (eg standards, blanks,
duplicates, external laboratory checks) and whether acceptable
levels of accuracy (ie lack of bias) and precision have been
established.
|
• Core samples
collected from 2021 drill holes were shipped to Activation
Laboratories in Ancaster, ON, for standard sample preparation (code
RX1) which included crushing to 80% passing 10 mesh, followed by a
250 g riffle split and pulverizing to 95% passing 105 microns. All
2021 core sample pulps were analyzed, at the same lab, for
multi-element (including lithium) by four-acid digestion with
ICP-OES finish (package 1F2) and tantalum by INAA (code 5B), with
any samples returning >8,000 ppm Li by 1F2 reanalyzed for
Li by code 8-4 Acid ICP Assay.
• Core samples
collected from 2022 and 2023 drill holes CV22-015 through CV23-107
were shipped to SGS Canada's laboratory in either Lakefield, ON
(vast majority), Sudbury, ON (CV22-028, 029, 030), or Burnaby, BC
(CV22-031, 032, 033, and 034), for standard sample preparation
(code PRP89) which included drying at 105°C, crush to 75% passing 2
mm, riffle split 250 g, and pulverize 85% passing 75 microns. Core
samples collected from 2023 drill holes CV23-108 through 365 were
shipped to SGS Canada's laboratory in Val-d'Or, QC, for standard
sample preparation (code PRP89).
• Core samples
collected from 2024 drill holes were shipped to SGS Canada's
laboratory in Val-d'Or, QC, or Radisson, QC, for sample preparation
(code PRP90 special) which included drying at 105°C, crush to 90%
passing 2 mm, riffle split 250 g, and pulverize 85% passing 75
microns.
• All drill core
sample pulps from 2022, 2023, and 2024 were shipped by air to SGS
Canada's laboratory in Burnaby, BC, where the samples were
homogenized and subsequently analyzed for multi-element (including
Li and Ta) using sodium peroxide fusion with ICP-AES/MS finish
(codes GE_ICP91A50 and GE_IMS91A50).
• All channel
samples collected were shipped to SGS Canada's laboratory in
Lakefield, ON, or Val-d'Or, QC, for standard preparation. Pulps
were analyzed at SGS Canada's laboratory in either Lakefield, ON,
(2017), or Burnaby, BC (2022, 2023, and 2024), for multi-element
(including Li and Ta) using sodium peroxide fusion with ICP-AES/MS
finish.
• The Company
relies on both its internal QAQC protocols (systematic use of
blanks, certified reference materials, and external checks), as
well as the laboratory's internal QAQC.
• All protocols
employed are considered appropriate for the sample type and nature
of mineralization and are considered the optimal approach for
maintaining representativeness in sampling.
|
Verification of
sampling and
assaying
|
• The
verification of significant intersections by either independent or
alternative company personnel.
• The use of
twinned holes.
• Documentation
of primary data, data entry procedures, data verification, data
storage (physical and electronic) protocols.
• Discuss any
adjustment to assay data.
|
• Intervals are
reviewed and compiled by the VP Exploration and Project Managers
prior to disclosure, including a review of the Company's internal
QAQC sample analytical data.
• No twinned
holes were completed, apart from several holes being recollared
with a different core size or due to premature loss of a hole due
to conditions.
• Data capture
utilizes MX Deposit software whereby core logging data is entered
directly into the software for storage, including direct import of
laboratory analytical certificates as they are received. The
Company employs various on-site and post QAQC protocols to ensure
data integrity and accuracy.
• Adjustments to
data include reporting lithium and tantalum in their oxide forms,
as it is reported in elemental form in the assay certificates.
Formulas used are Li2O = Li x 2.153, and
Ta2O5 = Ta x 1.221.
|
Location of data
points
|
• Accuracy and
quality of surveys used to locate drill holes (collar and down-hole
surveys), trenches, mine workings and other locations used in
Mineral Resource estimation.
• Specification
of the grid system used.
• Quality and
adequacy of topographic control.
|
• Each drill hole
collar and channel end points have been surveyed with a RTK Topcon
GR-5 or RTK Trimble Zephyr 3, except for a minor number of
channels.
• The coordinate
system used is UTM NAD83 Zone 18.
• The Company
completed a property-wide LiDAR and orthophoto survey in August
2022, which provides high-quality topographic control.
• The quality and
accuracy of the topographic controls are considered adequate for
advanced stage exploration and development, including Mineral
Resource estimation.
|
Data spacing and
distribution
|
• Data spacing
for reporting of Exploration Results.
• Whether the
data spacing and distribution is sufficient to establish the degree
of geological and grade continuity appropriate for the Mineral
Resource and Ore Reserve estimation procedure(s) and
classifications applied.
• Whether sample
compositing has been applied.
|
• At CV5, drill
hole collar spacing is dominantly grid based. Several collars are
typically completed from the same pad at varied orientations
targeting pegmatite pierce points of ~50 to 100 m
spacing.
• At CV13, drill
hole spacing is a combination of grid based (at ~100 spacing) and
fan based with multiple holes collared from the same pad.
Therefore, collar locations and hole orientations may vary widely,
which reflect the varied orientation of the pegmatite body along
strike.
• Based on the
nature of the mineralization and continuity in geological
modelling, the drill hole spacing is sufficient to support a
Mineral Resource Estimate.
• Core sample
lengths typically range from 0.5 to 2.0 m and average ~1.0 to 1.5
m. Sampling is continuous within all pegmatite encountered in the
drill hole.
• Core samples
are not composited upon collection or for analysis.
|
Orientation of data
in relation to
geological structure
|
• Whether the
orientation of sampling achieves unbiased sampling of possible
structures and the extent to which this is known, considering the
deposit type.
• If the
relationship between the drilling orientation and the orientation
of key mineralized structures is considered to have introduced a
sampling bias, this should be assessed and reported if
material.
|
• No sampling
bias is anticipated based on structure within the mineralized
body.
• The principal
mineralized bodies are relatively undeformed and very competent,
although have some meaningful structural control.
• At CV5, the
principal mineralized body and adjacent lenses are steeply dipping
resulting in oblique angles of intersection with true widths
varying based on drill hole angle and orientation of pegmatite at
that particular intersection point. i.e., the dip of the
mineralized pegmatite body has variations in a vertical sense and
along strike, so the true widths are not always apparent until
several holes have been drilled (at the appropriate spacing) in any
particular drill-fence.
• At CV13, the
principal pegmatite body has a shallow varied strike and northerly
dip.
|
Sample
security
|
• The measures
taken to ensure sample security.
|
• Samples were
collected by Company staff or its consultants following project
specific protocols governing sample collection and handling. Core
samples were bagged, placed in large supersacs for added security,
palleted, and shipped by third party transport, or directly by
representatives of the Company, to the designated sample
preparation laboratory (Ancaster, ON, in 2021, Sudbury, ON,
Burnaby, BC, and Lakefield, ON, in 2022, Lakefield, ON, in 2023,
Val-d'Or, QC, in 2023 and 2024, and Radisson in 2024) being tracked
during shipment along with chain of custody documents. Upon arrival
at the laboratory, the samples were cross-referenced with the
shipping manifest to confirm all samples were accounted for. At the
laboratory, sample bags were evaluated for tampering. On several
occasions in 2022, SGS Canada shipped samples to a different SGS
Canada facility for preparation than was intended by the Company
(Sudbury, ON, and Burnaby, BC, in 2022).
|
Audits or
reviews
|
• The results of
any audits or reviews of sampling techniques and data.
|
• A review of the
sample procedures for the Company's 2021 fall drill program
(CF21-001 to 004) and 2022 winter drill program (CV22-015 to 034)
was completed by an Independent Competent Person and deemed
adequate and acceptable to industry best practices (discussed in a
technical report titled "NI 43-101 Technical Report on the Corvette
Property, Quebec, Canada", by Alex Knox, M.Sc., P.Geol., Issue Date
of June 27th, 2022.)
• A review of the
sample procedures through the Company's 2023 winter drill program
(through CV23-190) was completed by an independent Competent Person
with respect to the CV5 Pegmatite's maiden Mineral Resource
Estimate and deemed adequate and acceptable to industry best
practices (discussed in a technical report titled " NI 43–101
Technical Report, Mineral Resource Estimate for the CV5 Pegmatite,
Corvette Property" by Todd McCracken, P.Geo., of BBA Engineering
Ltd., and Ryan Cunningham, M.Eng., P.Eng., of Primero Group
Americas Inc., Effective Date of June 25, 2023, and Issue Date of
September 8, 2023.
• Additionally,
the Company continually reviews and evaluates its procedures in
order to optimize and ensure compliance at all levels of sample
data collection and handling.
|
Section 2 – Reporting of Exploration Results
Criteria
|
JORC Code explanation
|
Commentary
|
Mineral tenement
and land tenure
status
|
• Type, reference
name/number, location and ownership including agreements or
material issues with third parties such as joint ventures,
partnerships, overriding royalties, native title interests,
historical sites, wilderness or national park and environmental
settings.
• The security of
the tenure held at the time of reporting along with any known
impediments to obtaining a licence to operate in the
area.
|
• The
Shaakichiuwaanaan Property is comprised of 463 CDC claims located
in the James Bay Region of Quebec. All claims are registered 100%
in the name of Lithium Innova Inc., a wholly owned subsidiary of
Patriot Battery Metals Inc.
• The northern
border of the Property's primary claim grouping is located within
approximately 6 km to the south of the Trans-Taiga Road and
powerline infrastructure corridor. The CV5 Spodumene Pegmatite is
situated approximately 13.5 km south of the regional and
all–weather Trans-Taiga Road and powerline infrastructure corridor,
and is accessible year-round by an all-season road. The CV13
Spodumene Pegmatite is located approximately 3 km west-southwest of
CV5.
• The Company
holds 100% interest in the Property subject to various royalty
obligations depending on original acquisition agreements. DG
Resources Management holds a 2% NSR (no buyback) on 76 claims,
D.B.A. Canadian Mining House holds a 2% NSR on 50 claims (half
buyback for $2M), Osisko Gold Royalties holds a sliding scale NSR
of 1.5-3.5% on precious metals, and 2% on all other products, over
111 claims, and Azimut Exploration holds a 2% NSR on 39
claims.
• The Property
does not overlap any atypically sensitive environmental areas or
parks, or historical sites to the knowledge of the Company. There
are no known hinderances to operating at the Property, apart from
the goose harvesting season (typically mid-April to mid-May) where
the communities request helicopter flying not be completed, and
potentially wildfires depending on the season, scale, and
location.
• Claim expiry
dates range from February 2025 to November 2026.
|
Exploration done
by other parties
|
• Acknowledgment
and appraisal of exploration by other parties.
|
• No core assay
results from other parties are disclosed herein.
• The most recent
independent Property review was a technical report titled "NI
43-101 Technical Report, Mineral Resource Estimate for the CV5
Pegmatite, Corvette Property, James Bay Region, Québec, Canada", by
Todd McCracken, P.Geo., of BBA Engineering Ltd., and Ryan
Cunningham, M.Eng., P.Eng., of Primero Group Americas Inc.,
Effective Date of June 25, 2023, and Issue Date of September 8,
2023.
|
Geology
|
• Deposit type,
geological setting and style of mineralization.
|
• The Property
overlies a large portion of the Lac Guyer Greenstone Belt,
considered part of the larger La Grande River Greenstone Belt, and
is dominated by volcanic rocks metamorphosed to amphibolite facies.
Rocks of the Guyer Group (amphibolite, iron formation, intermediate
to mafic volcanics, peridotite, pyroxenite, komatiite, as well as
felsic volcanics) predominantly underly the Property. The
amphibolite rocks that trend east-west (generally steeply south
dipping) through this region are bordered to the north by the Magin
Formation (conglomerate and wacke) and to the south by an
assemblage of tonalite, granodiorite, and diorite, in addition to
metasediments of the Marbot Group (conglomerate, wacke) in the
areas proximal to the CV5 Spodumene Pegmatite. Several
regional-scale Proterozoic gabbroic dykes also cut through portions
of the Property (Lac Spirt Dykes, Senneterre Dykes). The lithium
pegmatites on the Property are hosted predominantly within
amphibolite's, metasediments, and to a lesser extent ultramafic
rocks.
• The geological
setting is prospective for gold, silver, base metals, platinum
group elements, and lithium over several different deposit styles
including orogenic gold (Au), volcanogenic massive sulfide (Cu, Au,
Ag), komatiite-ultramafic (Au, Ag, PGE, Ni, Cu, Co), and pegmatite
(Li, Ta).
• Exploration of
the Property has outlined three primary mineral exploration trends
crossing dominantly east-west over large portions of the Property –
Golden Trend (gold), Maven Trend (copper, gold, silver), and CV
Trend (lithium, tantalum). The CV5 and CV13 spodumene pegmatites
are situated within the CV Trend. Lithium mineralization at the
Property, including at CV5 and CV13 is observed to occur within
quartz-feldspar pegmatite, which may be exposed at surface as high
relief 'whale-back' landforms. The pegmatite is often very
coarse-grained and off-white in appearance, with darker sections
commonly composed of mica and smoky quartz, and occasional
tourmaline.
• The lithium
pegmatites at Property are categorized as LCT Pegmatites. Core
assays and ongoing mineralogical studies, coupled with field
mineral identification and assays, indicate spodumene as the
dominant lithium-bearing mineral on the Property, with no
significant petalite, lepidolite, lithium-phosphate minerals, or
apatite present. The pegmatites also carry significant tantalum
values with tantalite indicated to be the mineral phase.
|
Drill hole
Information
|
• A summary of
all information material to the understanding of the exploration
results including a tabulation of the following information for all
Material drill holes:
o easting and
northing of the drill hole collar
o elevation or RL
(Reduced Level – elevation above sea level in metres) of the drill
hole collar
o dip and azimuth
of the hole
o down hole
length and interception depth
o hole
length.
• If the
exclusion of this information is justified on the basis that the
information is not Material and this exclusion does not detract
from the understanding of the report, the Competent Person should
clearly explain why this is the case.
|
• Drill hole
attribute information is included in a table herein.
• Pegmatite
intersections of <2 m are not typically presented as they are
considered insignificant.
|
Data aggregation
methods
|
• In reporting
Exploration Results, weighting averaging techniques, maximum and/or
minimum grade truncations (eg cutting of high grades) and cut-off
grades are usually Material and should be stated.
• Where aggregate
intercepts incorporate short lengths of high grade results and
longer lengths of low grade results, the procedure used for such
aggregation should be stated and some typical examples of such
aggregations should be shown in detail.
• The assumptions
used for any reporting of metal equivalent values should be clearly
stated.
|
• Length weighted
averages were used to calculate grade over width.
• No specific
grade cap or cut-off was used during grade width calculations. The
lithium and tantalum length weighted average grade of the entire
pegmatite interval is calculated for all pegmatite intervals over 2
m core length, as well as higher grade zones at the discretion of
the geologist. Pegmatites have inconsistent mineralization by
nature, resulting in some intervals having a small number of poorly
mineralized samples included in the calculation. Non-pegmatite
internal dilution is limited to typically <3 m where relevant
and intervals indicated when assays are reported.
• No metal
equivalents have been reported.
|
Relationship
between
mineralization
widths and
intercept lengths
|
• These
relationships are particularly important in the reporting of
Exploration Results.
• If the geometry
of the mineralization with respect to the drill hole angle is
known, its nature should be reported.
• If it is not
known and only the down hole lengths are reported, there should be
a clear statement to this effect (eg 'down hole length, true width
not known').
|
• At CV5,
geological modelling is ongoing on a hole-by-hole basis and as
assays are received. However, current interpretation supports a
principal, large pegmatite body of near vertical to steeply dipping
orientation, flanked by several subordinate pegmatite lenses
(collectively, the 'CV5 Spodumene Pegmatite').
• At CV13,
geological modelling is ongoing on a hole-by-hole basis and as
assays are received. However, current interpretation supports a
series of flat-lying to moderately dipping (northerly),
sub-parallel trending spodumene pegmatite bodies, of which three
appear to dominate (collectively, the 'CV13 Spodumene
Pegmatite').
• All reported
widths are core length. True widths are not calculated for each
hole due to the relatively wide drill spacing at this stage of
delineation and the typical irregular nature of pegmatite, as well
as the varied drill hole orientations. As such, true widths may
vary widely from hole to hole.
|
Diagrams
|
• Appropriate
maps and sections (with scales) and tabulations of intercepts
should be included for any significant discovery being reported
These should include, but not be limited to a plan view of drill
hole collar locations and appropriate sectional views.
|
• Please refer to
the figures included herein as well as those posted on the
Company's website.
|
Balanced
reporting
|
• Where
comprehensive reporting of all Exploration Results is not
practicable, representative reporting of both low and high grades
and/or widths should be practiced to avoid misleading reporting of
Exploration Results.
|
• Please refer to
the table(s) included herein as well as those posted on the
Company's website.
• Results for
pegmatite intervals <2 m are not reported as they are considered
insignificant.
|
Other substantive
exploration data
|
• Other
exploration data, if meaningful and material, should be reported
including (but not limited to): geological observations;
geophysical survey results; geochemical survey results; bulk
samples – size and method of treatment; metallurgical test results;
bulk density, groundwater, geotechnical and rock characteristics;
potential deleterious or contaminating substances.
|
• The Company is
currently completing site environmental work over the CV5 and CV13
pegmatite area. No endangered flora or fauna have been documented
over the Property to date, and several sites have been identified
as potentially suitable for mine infrastructure.
• The Company has
completed a bathymetric survey over the shallow glacial lake which
overlies a portion of the CV5 Spodumene Pegmatite. The lake depth
ranges from <2 m to approximately 18 m, although the majority of
the CV5 Spodumene Pegmatite, as delineated to date, is overlain by
typically <2 to 10 m of water.
• The Company has
completed preliminary metallurgical testing comprised of HLS and
magnetic testing, which has produced 6+% Li2O spodumene
concentrates at >70% recovery on both CV5 and CV13 pegmatite
material, indicating DMS as a viable primary process approach, and
that both CV5 and CV13 could potentially feed the same process
plant. A DMS test on CV5 Spodumene Pegmatite material returned a
spodumene concentrate grading 5.8% Li2O at 79% recovery,
strongly indicating potential for a DMS only operation to be
applicable.
• Various
mandates required for advancing the Project towards economic
studies have been initiated, including but not limited to,
environmental baseline, metallurgy, geomechanics, hydrogeology,
hydrology, stakeholder engagement, geochemical characterization, as
well as transportation and logistical studies.
|
Further work
|
• The nature and
scale of planned further work (eg tests for lateral extensions or
depth extensions or large-scale step-out drilling).
• Diagrams
clearly highlighting the areas of possible extensions, including
the main geological interpretations and future drilling areas,
provided this information is not commercially sensitive.
|
• The Company
intends to continue drilling the pegmatites of the Property,
focused on completion of the infill drill program at the CV5
Pegmatite as well as testing for extensions along strike, up dip,
and down dip where mineralization remains open. The Company also
anticipates further drilling at the CV13 Pegmatite and the CV9
Pegmatite.
|
Section 3 – Estimate and Reporting of Mineral
Resources
Criteria
|
JORC Code explanation
|
Commentary
|
Database
integrity
|
• Measures taken
to ensure that data has not been corrupted by, for example,
transcription or keying errors, between its initial collection and
its use for Mineral Resource estimation purposes.
• Data validation
procedures used.
|
• Data capture
utilizes MX Deposit database software whereby core logging data is
entered directly into the software for storage, including direct
import of laboratory analytical certificates as they are received.
Collar and downhole deviation surveys are also validated and stored
in MX Deposit database software. The Company employs various
on-site and post initial QAQC protocols to ensure data integrity
and accuracy.
• Drill hole
collar points were validated against LiDAR topographic
data.
• The drill hole
database was further validated by the independent Competent Person
for the Mineral Resource Estimate, including missing sample
intervals, overlapping intervals, and various missing data (survey,
collar coordinates, assays, rock type, etc.)
• All the
analytical certificates since the 2023 MRE were validate against
the assays present in the database for Li and Ta.
• No significant
errors in the database were discovered. The database is considered
validated and of high quality, and therefore sufficient to support
the Mineral Resource Estimate.
|
Site visits
|
• Comment on any
site visits undertaken by the Competent Person and the outcome of
those visits.
• If no site
visits have been undertaken indicate why this is the
case.
|
• Todd McCracken
(Competent Person) of BBA Engineering Ltd., completed site visits
to the Property from April 7 to 11, 2023, and June 4 to 7,
2024.
• Core from
various drill holes from CV5 and CV13 from the 2023 and 2024 drill
program was viewed and core processing protocols reviewed with site
geologists. Drilling was active during the 2023 site
visit.
• Several of the
CV5 and CV13 pegmatite outcrops were visited, and various collar
locations were visited and GPS coordinates checked against the
database.
• Pulp samples
were collected for check analysis from holes selected by the
Competent Person.
• No significant
issues were found with the protocols practiced on site. The
Competent Person considers the QAQC and procedures adopted by the
Company to be of a high standard.
|
Geological
interpretation
|
• Confidence in
(or conversely, the uncertainty of) the geological interpretation
of the mineral deposit.
• Nature of the
data used and of any assumptions made.
• The effect, if
any, of alternative interpretations on Mineral Resource
estimation.
• The use of
geology in guiding and controlling Mineral Resource
estimation.
• The factors
affecting continuity both of grade and geology.
|
• The CV5 and
CV13 geological models were built in Leapfrog Geo using MX Deposit
database, through an iterative and interpretive process by Project
Geologists and VP Exploration, and validated by the Competent
Person.
• The CV5
Pegmatite was geologically modelled as an intrusive for the
principal pegmatite body (1), and as a vein for adjacent lenses
(8). The CV13 Pegmatite was geological modelled as veins for all of
its lenses.
• A combination
of implicit and explicit modelling methods was used, defined by
geologically logged drill intersections, channel samples, and
outcrop mapping, with external geological controls, including
measured contact orientations, cross-sectional polylines, and
surface polyline controls to ensure the model follows geological
interpretation, validation, and reasonable extensions along trend
and dip.
• The CV5
geological model's principal pegmatite was further geochemically
domain modelled using rock types and assays.
• The geological
interpretation of both the CV5 and CV13 geological models are
robust. Alternative interpretations are unlikely to materially
alter the Mineral Resource Estimate.
• Drilling
density is the primary factor in assessing the interpreted
continuity of both grade and geology. The current drill density is
sufficient to support the Mineral Resource Estimate. The
controlling factors on mineralization are not fully understood but
meaningful structural control is interpreted.
|
Dimensions
|
• The extent and
variability of the Mineral Resource expressed as length (along
strike or otherwise), plan width, and depth below surface to the
upper and lower limits of the Mineral Resource.
|
• The CV5 portion
of the Shaakichiuwaanaan Mineral Resource Estimate includes
multiple individual spodumene pegmatite dykes that have been
modelled. However, approximately two-thirds of the overall
Shaakichiuwaanaan Mineral Resource, and vast majority of the CV5
Mineral Resource component, is hosted within a single, large,
principal pegmatite dyke, which is flanked on both sides by
multiple, subordinate, sub-parallel trending dykes. The principal
dyke at CV5 is geologically modelled to extend continuously over a
lateral distance of at least 4.6 km and remains open along
strike at both ends and to depth along a large portion of its
length. The width of the currently known mineralized corridor at
CV5 is approximately 500 m, with spodumene pegmatite intersected as
deep as 450 m vertical depth from surface. The pegmatite dykes at
CV5 trend south-southwest (approximately 250°/070° RHR), and
therefore dip northerly, which is opposite to the host
amphibolites, metasediments, and ultramafics which steeply dip
southerly. The principal dyke ranges from <10 m to >125 m in
true width, and may pinch and swell aggressively along strike, as
well as up and down dip. It is primarily the thickest at
near-surface to moderate depths (<225 m), forming a relatively
bulbous, elongated shape, which may flair to surface and to depth
variably along its length.
• The CV13
portion of the Shaakichiuwaanaan Mineral Resource Estimate includes
multiple individual spodumene pegmatite dykes that have been
modelled, with three appearing to be dominant. The pegmatite bodies
are coincident with the apex of a regional structural flexure where
the west arm trends ~290° and the east arm at ~230°. Drilling to
date indicates the east arm includes significantly more pegmatite
stacking compared to the west, and also carries a significant
amount of the overall CV13 Pegmatite tonnage and grade, highlighted
by the high-grade Vega Zone.
|
Estimation and
modelling
techniques
|
• The nature and
appropriateness of the estimation technique(s) applied and key
assumptions, including treatment of extreme grade values,
domaining, interpolation parameters and maximum distance of
extrapolation from data points. If a computer assisted estimation
method was chosen include a description of computer software and
parameters used.
• The
availability of check estimates, previous estimates and/or mine
production records and whether the Mineral Resource estimate takes
appropriate account of such data.
• The assumptions
made regarding recovery of by-products.
• Estimation of
deleterious elements or other non-grade variables of economic
significance (eg sulphur for acid mine drainage
characterisation).
• In the case of
block model interpolation, the block size in relation to the
average sample spacing and the search employed.
• Any assumptions
behind modelling of selective mining units.
• Any assumptions
about correlation between variables.
• Description of
how the geological interpretation was used to control the resource
estimates.
• Discussion of
basis for using or not using grade cutting or capping.
• The process of
validation, the checking process used, the comparison of model data
to drill hole data, and use of reconciliation data if
available.
|
• Compositing was
done every 1.0 m. Unsampled intervals were assigned a grade of
0.0005% Li and 0.25 ppm Ta. Capping was done after compositing.
Based on the statistical analysis capping varies by lithological
domain.
• On CV5, the
spodumene-rich domain within the CV5 principal pegmatite, no
capping was required for Li2O but
Ta2O5 was capped at 3,000 ppm. For the
feldspar-rich domain within the CV5 principal pegmatite, a capping
of 3.5% Li2O and 1,500 ppm Ta2O5
was applied. For the parallel dykes a capping of 5% Li2O
and 1,200 ppm Ta2O5 was applied.
• For CV13 zones,
it was determined that no capping was required for Li2O,
but Ta2O5 was capped at 1,500 ppm.
• Variography was
done both in Leapfrog Edge and Supervisor. For Li2O, a
well-structured variogram model was obtained for the CV5 principal
pegmatite's spodumene-rich domain. For the CV5 principal pegmatite,
both domains (spodumene-rich and feldspar-rich domains) were
estimated using ordinary kriging (OK), using Leapfrog Edge. For
Ta2O5, the spodumene-rich domain and the
feldspar-rich domain within CV5 principal pegmatite did not yield
well-structured variograms. Therefore, Ta2O5
was estimated using Inverse Distance Squared (ID2). The
remaining pegmatite dykes (8) domains at CV5 did not yield
well-structured variograms for either Li2O and
Ta2O5 and therefore were estimated using
Inverse Distance Squared (ID2), also using Leapfrog
Edge.
• At CV5, three
(3) orientated search ellipsoids were used to select data and
interpolate Li2O and Ta2O5 grades
in successively less restrictive passes. The ellipse sizes and
anisotropies were based on the variography, drillhole spacing, and
pegmatite geometry. The ellipsoids were 100 m x 50 m x 30 m, 200 m
x 100 m x 60 m, and 400 m x 200 m x 120 m. For the first pass
interpolation a minimum of five (5) composites and a maximum of
twelve (12) composites with a minimum of two (2) holes were needed
to interpolate. For the second and third pass a minimum of three
(3) composites with a maximum of twelve (12) without a minimum per
hole was used. Variable search ellipse orientations (dynamic
anisotropy) were used to interpolate for the eight (8) parallel
dykes. Spatial anisotropy of the dykes is respected during
estimation using Leapfrog Edge's Variable Orientation tool. The
search ellipse follows the trend of the central reference plane of
each dyke.
• At CV13,
variography analysis did not yield a well-structured variogram. On
CV13, Li2O and Ta2O5 were
estimated using Inverse Distance Squared (ID2) in
Leapfrog Edge.
• Three (3)
orientated search ellipsoids were used to select data and
interpolate Li2O and Ta2O5 grades
in successively less restrictive passes. The ellipse sizes and
anisotropies were based on the variography, drillhole spacing, and
pegmatite geometry. The ellipsoids were 80 m x 60 m x 10 m, 160 m x
120 m x 20 m, and 320 m x 240 m x 40 m. For the first
pass interpolation a minimum of five (5) composites and a maximum
of twelve (12) composites with a minimum of two (2) holes were
needed to interpolate. For the second and third pass a minimum of
three (3) composites with a maximum of twelve (12) without a
minimum per hole was used. Variable search ellipse orientations
(dynamic anisotropy) were used to interpolate the dykes. Spatial
anisotropy of the dykes is respected during estimation using
Leapfrog Edge's Variable Orientation tool. The search ellipse
follows the trend of the central reference plane of each
dyke.
• Parent cells of
10 m x 5 m x 5 m, subblocked four (4) times in each direction (for
minimum subcells of 2.5 m in x, 1.25 m in y, and 1.25 m in z were
used. Subblocks are triggered by the geological model.
Li2O and Ta2O5 grades are
estimated on the parent cells and automatically populated to
subblocks.
• The block model
is rotated around the Z axis (Leapfrog 340°).
• Hard boundaries
between all the pegmatite domains were used for all Li2O
and Ta2O5 estimates.
• Validation of
the block model was performed using Swath Plots, nearest neighbours
grade estimates, global means comparisons, and by visual inspection
in 3D and along plan views and cross-sections.
|
Moisture
|
• Whether the
tonnages are estimated on a dry basis or with natural moisture, and
the method of determination of the moisture content.
|
• Tonnages are
reported on a dry basis.
|
Cut-off
parameters
|
• The basis of
the adopted cut-off grade(s) or quality parameters
applied.
|
• Open pit
adopted cut-off grade is 0.40% Li2O and determined based
on operational cost estimates, primarily through benchmarking and
an internal trade-off study, for mining ($5.47/t mined for minable
resource, waste or overburden, processing ($14.17/t milled),
tailings management ($2.62/t milled), G&A ($20.41/t milled),
and concentrate transport costs ($287/t mine site to Becancour,
QC). Process recovery assumed a Dense Media Separation (DMS) only
operation at approximately 70% overall recovery based on processing
recovery formula of Recovery % = 75% ×
(1-e^(-1.995(Li2O Feed Grade %) ) )into a 5.5%
Li2O spodumene concentrate. A spodumene concentrate
price of US $1,500 was assumed with USD/CAD exchange rate of 0.76.
A royalty of 2% was applied.
• Underground
adopted cut-off grade for CV5 is 0.60% Li2O and
determined based on the same parameters than the open pit with the
addition of the underground mining cost estimated at 62.95$/t
considering a long hole transverse mining method.
• Underground
adopted cut-off grade for CV13 is 0.80% Li2O and
determined based on the same parameters than the open pit with the
addition of the underground mining cost estimated at 100$/t
considering a mining method that will be aligned with the shallow
dip lenses.
|
Mining factors or
assumptions
|
• Assumptions
made regarding possible mining methods, minimum mining dimensions
and internal (or, if applicable, external) mining dilution. It is
always necessary as part of the process of determining reasonable
prospects for eventual economic extraction to consider potential
mining methods, but the assumptions made regarding mining methods
and parameters when estimating Mineral Resources may not always be
rigorous. Where this is the case, this should be reported with an
explanation of the basis of the mining assumptions made.
|
• Open-pit mining
method is assumed with an overall pit slope ranging from 45° to 53°
considering various sectors, single and double bench.
• No dilution or
mining recovery has been considered.
• Underground
mining method considered is long hole for CV5. Stope size
considered are vertical 30 m in height, 15 m in width and a minimum
of 3 m in thickness.
• The mining
method for CV13 has not been determined but the mining cost used is
higher considering the shallow dip of the lenses in CV13. Stope
dimensions considered are horizontal considering length of 15 m,
7.5 m in width and a minimum height of 3 m.
• The Mineral
Resources are reported as in-situ tonnes and grade.
|
Metallurgical factors
or
assumptions
|
• The basis for
assumptions or predictions regarding metallurgical amenability. It
is always necessary as part of the process of determining
reasonable prospects for eventual economic extraction to consider
potential metallurgical methods, but the assumptions regarding
metallurgical treatment processes and parameters made when
reporting Mineral Resources may not always be rigorous. Where this
is the case, this should be reported with an explanation of the
basis of the metallurgical assumptions made.
|
• The processing
assumptions are based on HLS and magnetic testing, which has
produced 6+% Li2O spodumene concentrates at >70%
recovery on drill core samples from both the CV5 and CV13
pegmatites and indicate DMS as a viable primary process approach
for both CV5 and CV13. This is supported by a subsequent DMS test
on CV5 drill core, which returned a spodumene concentrate grading
5.8% Li2O at 79% recovery.
• For the Mineral
Resource conceptual mining shapes, based on a grade versus recovery
curve of the test work completed to date, an average recovery of
approximately 70% to produce a 5.5% Li2O spodumene
concentrate was used
|
Environmental
factors or
assumptions
|
• Assumptions
made regarding possible waste and process residue disposal options.
It is always necessary as part of the process of determining
reasonable prospects for eventual economic extraction to consider
the potential environmental impacts of the mining and processing
operation. While at this stage the determination of potential
environmental impacts, particularly for a greenfields project, may
not always be well advanced, the status of early consideration of
these potential environmental impacts should be reported. Where
these aspects have not been considered this should be reported with
an explanation of the environmental assumptions made.
|
• The Project's
CV5 Pegmatite is in the early stages of economic
evaluation.
• A conventional
tailings management facility and no material adverse environmental
impediments are assumed.
• No
environmental assessment has been completed for the Project.
However, a Project Description has been submitted to relevant
environmental regulator.
|
Bulk density
|
• Whether assumed
or determined. If assumed, the basis for the assumptions. If
determined, the method used, whether wet or dry, the frequency of
the measurements, the nature, size and representativeness of the
samples.
• The bulk
density for bulk material must have been measured by methods that
adequately account for void spaces (vugs, porosity, etc), moisture
and differences between rock and alteration zones within the
deposit.
• Discuss
assumptions for bulk density estimates used in the evaluation
process of the different materials.
|
• Density of the
pegmatite was estimated using a linear regression function derived
from SG field measurements (1 sample every ~4.5 m) and
Li2O grade. The regression function (SG= 0.0688 x
Li2O% + 2.625) was used for all pegmatite blocks.
Non-pegmatite blocks were assigned a fixed SG based on the field
measurement median value (diabase = 2.94, amphibolite group = 2.98,
metasediment 2.76, wacke = 2.71, ultramafic = 2.95, overburden =
2.00).
|
Classification
|
• The basis for
the classification of the Mineral Resources into varying confidence
categories.
• Whether
appropriate account has been taken of all relevant factors (ie
relative confidence in tonnage/grade estimations, reliability of
input data, confidence in continuity of geology and metal values,
quality, quantity and distribution of the data).
• Whether the
result appropriately reflects the Competent Person's view of the
deposit.
|
• The
Shaakichiuwaanaan resource classification is in accordance with the
JORC 2012 reporting guidelines. All reported Mineral Resources have
reasonable prospects for eventual economic extraction. All reported
Mineral Resources have been constrained by conceptual open-pit or
underground mineable shapes to demonstrate reasonable prospects for
eventual economic extraction ("RPEEE").
• Blocks were
classified as Indicated when 1.) demonstrated geological continuity
and minimum thickness of 2 m, 2.) the drill spacing was 70 m or
lower and meeting the minimum estimation criteria parameters, and
3.) grade continuity at the reported cut-off grade. Blocks were
classified Inferred when drill spacing was between 70 m and 140 m
and meeting the minimum estimation criteria parameters. Geological
continuity and a minimum thickness of 2 m were also
mandatory. There are no measured classified blocks. Pegmatite
dykes or extension with lower level of information / confidence
were also not classified.
• Classification
shapes are created around contiguous blocks at the stated criteria
with consideration for the selected mining method.
• The
classification of the Mineral Resource Estimate is appropriate and
reflects the view of Competent Person (Todd McCracken).
|
Audits or
reviews
|
• The results of
any audits or reviews of Mineral Resource estimates.
|
• The mineral
resource estimate has been reviewed internally by BBA Engineering
Ltd. as part of its regular internal review process.
• There has been
no external audit of the Mineral Resource Estimate.
|
Discussion of
relative accuracy/
confidence
|
• Where
appropriate a statement of the relative accuracy and confidence
level in the Mineral Resource estimate using an approach or
procedure deemed appropriate by the Competent Person. For example,
the application of statistical or geostatistical procedures to
quantify the relative accuracy of the resource within stated
confidence limits, or, if such an approach is not deemed
appropriate, a qualitative discussion of the factors that could
affect the relative accuracy and confidence of the
estimate.
• The statement
should specify whether it relates to global or local estimates,
and, if local, state the relevant tonnages, which should be
relevant to technical and economic evaluation. Documentation should
include assumptions made and the procedures used.
• These
statements of relative accuracy and confidence of the estimate
should be compared with production data, where
available.
|
• The Competent
Person is of the opinion that the Mineral Resource for the CV5 and
CV13 spodumene pegmatites (collectively, the Shaakichiuwaanaan
Mineral Resource) appropriately consider modifying factors and have
been estimated using industry best practices.
• The accuracy of
the estimate within this Mineral Resource is determined by yet not
limited to; geological confidence including understanding the
geology, deposit geometry, drill spacing.
• As always,
changes in commodity price and exchange rate assumptions will have
an impact on the optimal size of the conceptual mining open-pit and
underground shapes.
• Changes in
current environmental or legal regulations may affect the
operational parameters (cost, mitigation measures).
• The Mineral
Resource Estimate is constrained using open-pit and underground
mining shapes to satisfy reasonable prospects for eventual economic
extraction.
|
APPENDIX 2: SOURCES FOR FIGURE 1 (TONNAGE VS GRADE – THE
AMERICAS) & FIGURE 2
(TONNAGE VS GRADE – WORLD)
Company name
|
Stock
Ticker
|
Project
Name
|
Source
|
Liontown Resources
Ltd.
|
LTR
|
Kathleen
Valley
|
ASX announcement dated
April 8, 2021
|
Liontown Resources
Ltd.
|
LTR
|
Buldania
|
ASX announcement dated
November 8, 2019
|
Pilbara Minerals
Ltd.
|
PLS
|
Pilgangoora
|
ASX announcement dated
August 7, 2023
|
Alita Resources
Ltd.
|
n/a
|
Bald Hill
|
Alliance Minerals
Assets Limited March 2019 Presentation
|
Arcadium Lithium
Plc
|
ALTM
|
Whabouchi
|
S-K 1300 Technical
Report dated September 8, 2023
|
Arcadium Lithium
Plc
|
ALTM
|
Galaxy
|
ASX announcement dated
August 11, 2023
|
Arcadium Lithium
Plc
|
ALTM
|
Mt Cattlin
|
ASX announcement dated
November 9, 2023
|
European Lithium
Ltd.
|
EUR
|
Wolfsberg
|
ASX announcement dated
December 1, 2021
|
AVZ Minerals
Ltd.
|
AVZ
|
Manono
|
ASX announcement dated
January 31, 2024
|
Critical Elements
Lithium Corp.
|
CRE
|
Rose
|
TSX Announcement dated
August 29, 2023
|
Atlantic Lithium
Ltd..
|
ALL
|
Ewoyaa
|
ASX announcement dated
February 1, 2023
|
IGO Ltd.
|
IGO
|
Greenbushes
|
ASX announcement dated
December 31, 2023
|
Mineral Resources
Ltd.
|
MIN
|
Wodgina
|
ASX announcement dated
September 22, 2023
|
Albemarle
Corp.
|
ALB
|
Kings
Mountain
|
SEC filing dated
February 15, 2023
|
Mineral Resources
Ltd.
|
MIN
|
Mt Marion
|
ASX announcement dated
February 21, 2024
|
Sociedad Quimica y
Minera de Chile S.A.
|
SQM
|
Mt. Holland
|
Annual Report
2022
|
Leo Lithium
Ltd.
|
LLL
|
Goulamina
|
ASX announcement dated
July 1, 2024
|
Sayona Mining
Ltd.
|
SYA
|
Authier
|
ASX announcement dated
April 14, 2023
|
Sayona Mining
Ltd.
|
SYA
|
NAL
|
ASX announcement dated
April 14, 2023
|
Sayona Mining
Ltd.
|
SYA
|
Moblan
|
ASX announcement dated
April 17, 2023
|
Prospect Resources
Ltd.
|
PSC
|
Arcadia
|
ASX announcement dated
October 11, 2021
|
AMG Critical Materials
N.V.
|
AMG
|
Mibra
|
Euronext announcement
dated April 3, 2017
|
Sibanye Stillwater
Ltd.
|
SSW
|
Keliber
|
JSE announcement dated
February 17, 2023
|
Lithium Ionic
Corp
|
LTH
|
Bandeira
|
Press release dated
April 24,2024
|
Frontier Lithium
Inc.
|
FL
|
PAK + Spark
|
NI 43-101 technical
report dated February 28, 2023
|
Sigma Lithium
Corp.
|
SGML
|
Grota do
Cirilo
|
Press release dated
January 31,2024
|
Piedmont Lithium
Inc
|
PLL
|
Carolina
|
Press release dated
October 21,2021
|
Sinomine Resource Group
Co., Ltd.
|
002738
|
Bikita
|
SZ Announcement dated
April 25, 2023
|
Delta Lithium
Ltd.
|
DLI
|
Mt Ida
|
ASX announcement dated
October 3, 2023
|
Delta Lithium
Ltd.
|
DLI
|
Yinnetharra
|
ASX announcement dated
December 27, 2023
|
Avalon Advanced
Materials Inc.
|
AVL
|
Separation
Rapids
|
PR Newswire press
release dated August 10, 2023
|
Andrada Mining
Ltd.
|
ATM
|
Uis
|
AIM announcement dated
February 6, 2023
|
Global Lithium
Resources Ltd.
|
GL1
|
Manna
|
ASX announcement dated
June 12, 2024
|
Global Lithium
Resources Ltd.
|
GL1
|
Marble Bar
|
ASX announcement dated
December 15, 2022
|
Latin Resources
Ltd
|
LRS
|
Colina
|
ASX announcement dated
May 30, 2024
|
Essential Metals
Ltd.
|
ESS
|
Dome North
|
ASX announcement dated
December 20, 2022
|
Kodal Minerals
Plc
|
KOD
|
Bougouni
|
AIM announcement dated
January 27, 2020
|
Savannah Resources
Plc
|
SAV
|
Mina Do
Barroso
|
AIM announcement dated
June 12, 2023
|
Green Technology Metals
Ltd.
|
GT1
|
Root
|
ASX announcement dated
October 17, 2023
|
Green Technology Metals
Ltd.
|
GT1
|
Seymour
|
ASX announcement dated
November 17, 2023
|
Rock Tech Lithium
Inc.
|
RCK
|
Georgia Lake
|
TSX Announcement dated
November 15, 2022
|
Winsome Resources
Ltd.
|
WR1
|
Adina
|
ASX announcement dated
May 28, 2024
|
Cygnus Metals
Ltd.
|
CY5
|
Pontax
|
ASX announcement dated
August 14, 2023
|
Core Lithium
Ltd
|
CXO
|
Finniss
|
ASX announcement dated
April 11, 2024
|
APPENDIX 3: MRE DETAILS FOR DEPOSITS/PROJECTS NOTED IN FIGURE
1 & FIGURE 2.
Company
Name
|
Project
Name
|
Region
|
Stage
|
Category
|
Tonnage
(Mt)
|
Grade
(Li2O)
|
Liontown Resources
Ltd.
|
Kathleen
Valley
|
APAC
|
Development
|
Measured
|
20.0
|
1.32 %
|
|
|
|
|
Indicated
|
109.0
|
1.37 %
|
|
|
|
|
Inferred
|
27.0
|
1.27 %
|
Liontown Resources
Ltd.
|
Buldania
|
APAC
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
9.1
|
0.98 %
|
|
|
|
|
Inferred
|
5.9
|
0.95 %
|
Pilbara Minerals
Ltd.
|
Pilgangoora
|
APAC
|
Production
|
Measured
|
22.1
|
1.34 %
|
|
|
|
|
Indicated
|
315.2
|
1.15 %
|
|
|
|
|
Inferred
|
76.6
|
1.07 %
|
Alita Resources
Ltd.
|
Bald Hill
|
APAC
|
Production
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
14.4
|
1.02 %
|
|
|
|
|
Inferred
|
12.1
|
0.90 %
|
Arcadium Lithium
Plc
|
Whabouchi
|
Americas
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
46.0
|
1.36 %
|
|
|
|
|
Inferred
|
8.3
|
1.31 %
|
Arcadium Lithium
Plc
|
Galaxy
|
Americas
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
54.3
|
1.30 %
|
|
|
|
|
Inferred
|
55.9
|
1.29 %
|
Arcadium Lithium
Plc
|
Mt Cattlin
|
APAC
|
Production
|
Measured
|
0.2
|
1.00 %
|
|
|
|
|
Indicated
|
10.6
|
1.30 %
|
|
|
|
|
Inferred
|
1.3
|
1.30 %
|
European Lithium
Ltd.
|
Wolfsberg
|
EMEA
|
Development
|
Measured
|
4.3
|
1.13 %
|
|
|
|
|
Indicated
|
5.4
|
0.95 %
|
|
|
|
|
Inferred
|
3.1
|
0.90 %
|
AVZ Minerals
Ltd.
|
Manono
|
EMEA
|
Development
|
Measured
|
132.0
|
1.65 %
|
|
|
|
|
Indicated
|
367.0
|
1.62 %
|
|
|
|
|
Inferred
|
342.0
|
1.57 %
|
Critical Elements
Lithium Corp.
|
Rose
|
Americas
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
30.6
|
0.93 %
|
|
|
|
|
Inferred
|
2.4
|
0.78 %
|
Atlantic Lithium
Ltd.
|
Ewoyaa
|
EMEA
|
Development
|
Measured
|
3.5
|
1.37 %
|
|
|
|
|
Indicated
|
24.5
|
1.25 %
|
|
|
|
|
Inferred
|
7.4
|
1.16 %
|
Tailson JV
|
Greenbushes
|
APAC
|
Production
|
Measured
|
0.7
|
3.00 %
|
|
|
|
|
Indicated
|
397.0
|
1.50 %
|
|
|
|
|
Inferred
|
49.0
|
1.10 %
|
MARBL JV
|
Wodgina
|
APAC
|
Production
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
182.1
|
1.15 %
|
|
|
|
|
Inferred
|
35.3
|
1.19 %
|
Albemarle
Corp.
|
Kings
Mountain
|
Americas
|
Development
|
Measured
|
-
|
0.00 %
|
|
|
|
|
Indicated
|
46.8
|
1.37 %
|
|
|
|
|
Inferred
|
42.9
|
1.10 %
|
MinRes /
Ganfeng
|
Mt Marion
|
APAC
|
Production
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
54.7
|
1.40 %
|
|
|
|
|
Inferred
|
11.4
|
1.05 %
|
SQM /
Wesfarmers
|
Mt. Holland
|
APAC
|
Development
|
Measured
|
71.0
|
1.57 %
|
|
|
|
|
Indicated
|
107.0
|
1.51 %
|
|
|
|
|
Inferred
|
8.0
|
1.44 %
|
Ganfeng
|
Goulamina
|
EMEA
|
Development
|
Measured
|
13.1
|
1.58 %
|
|
|
|
|
Indicated
|
94.9
|
1.42 %
|
|
|
|
|
Inferred
|
159.2
|
1.33 %
|
Sayona Mining
Ltd.
|
Authier
|
Americas
|
Development
|
Measured
|
6.0
|
0.98 %
|
|
|
|
|
Indicated
|
8.1
|
1.03 %
|
|
|
|
|
Inferred
|
2.9
|
1.00 %
|
Sayona Mining
Ltd.
|
NAL
|
Americas
|
Production
|
Measured
|
1.0
|
1.19 %
|
|
|
|
|
Indicated
|
24.0
|
1.23 %
|
|
|
|
|
Inferred
|
33.0
|
1.23 %
|
Sayona Mining
Ltd.
|
Moblan
|
Americas
|
Development
|
Measured
|
6.3
|
1.46 %
|
|
|
|
|
Indicated
|
43.6
|
1.16 %
|
|
|
|
|
Inferred
|
21.0
|
1.02 %
|
Prospect Resources
Ltd.
|
Arcadia
|
EMEA
|
Development
|
Measured
|
15.8
|
1.12 %
|
|
|
|
|
Indicated
|
45.6
|
1.06 %
|
|
|
|
|
Inferred
|
11.2
|
0.99 %
|
AMG Critical Materials
N.V.
|
Mibra
|
Americas
|
Production
|
Measured
|
3.4
|
1.00 %
|
|
|
|
|
Indicated
|
16.9
|
1.07 %
|
|
|
|
|
Inferred
|
4.2
|
1.03 %
|
Sibanye Stillwater
Ltd.
|
Keliber
|
EMEA
|
Development
|
Measured
|
10.2
|
0.96 %
|
|
|
|
|
Indicated
|
3.9
|
1.06 %
|
|
|
|
|
Inferred
|
3.3
|
0.83 %
|
Frontier Lithium
Inc.
|
PAK + Spark
|
Americas
|
Development
|
Measured
|
1.3
|
2.14 %
|
|
|
|
|
Indicated
|
24.7
|
1.59 %
|
|
|
|
|
Inferred
|
32.5
|
1.41 %
|
Sigma Lithium
Corp.
|
Grota do
Cirilo
|
Americas
|
Production
|
Measured
|
45.2
|
1.41 %
|
|
|
|
|
Indicated
|
49.1
|
1.39 %
|
|
|
|
|
Inferred
|
14.6
|
1.37 %
|
Piedmont Lithium
Inc
|
Carolina
|
Americas
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
28.2
|
1.11 %
|
|
|
|
|
Inferred
|
15.9
|
1.02 %
|
Sinomine Resource Group
Co., Ltd.
|
Bikita
|
EMEA
|
Production
|
Measured
|
21.7
|
1.17 %
|
|
|
|
|
Indicated
|
12.5
|
1.09 %
|
|
|
|
|
Inferred
|
6.1
|
1.08 %
|
Delta Lithium
Ltd.
|
Mt Ida
|
APAC
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
7.8
|
1.30 %
|
|
|
|
|
Inferred
|
6.8
|
1.10 %
|
Avalon Advanced
Materials Inc.
|
Separation
Rapids
|
Americas
|
Development
|
Measured
|
4.3
|
1.33 %
|
|
|
|
|
Indicated
|
5.8
|
1.36 %
|
|
|
|
|
Inferred
|
2.8
|
1.38 %
|
Andrada Mining
Ltd.
|
Uis
|
EMEA
|
Development
|
Measured
|
21.0
|
0.72 %
|
|
|
|
|
Indicated
|
17.0
|
0.73 %
|
|
|
|
|
Inferred
|
43.0
|
0.73 %
|
Global Lithium
Resources Ltd.
|
Manna
|
APAC
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
32.9
|
1.04 %
|
|
|
|
|
Inferred
|
18.7
|
0.92 %
|
Global Lithium
Resources Ltd.
|
Marble Bar
|
APAC
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
3.8
|
0.97 %
|
|
|
|
|
Inferred
|
14.2
|
1.01 %
|
Latin Resources
Ltd
|
Colina
|
Americas
|
Development
|
Measured
|
28.6
|
1.31 %
|
|
|
|
|
Indicated
|
38.6
|
1.23 %
|
|
|
|
|
Inferred
|
3.6
|
1.10 %
|
Essential Metals
Ltd.
|
Dome North
|
EMEA
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
8.6
|
1.23 %
|
|
|
|
|
Inferred
|
2.6
|
0.92 %
|
Kodal Minerals
Plc
|
Bougouni
|
EMEA
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
11.6
|
1.13 %
|
|
|
|
|
Inferred
|
20.3
|
1.02 %
|
Savannah Resources
Plc
|
Mina Do
Barroso
|
EMEA
|
Development
|
Measured
|
6.6
|
1.10 %
|
|
|
|
|
Indicated
|
11.8
|
1.00 %
|
|
|
|
|
Inferred
|
9.6
|
1.10 %
|
Rock Tech Lithium
Inc.
|
Georgia Lake
|
Americas
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
10.6
|
0.88 %
|
|
|
|
|
Inferred
|
4.2
|
1.00 %
|
Core Lithium
Ltd
|
Finniss
|
APAC
|
Care &
Maintenance
|
Measured
|
6.3
|
1.41 %
|
|
|
|
|
Indicated
|
21.6
|
1.30 %
|
|
|
|
|
Inferred
|
20.3
|
1.18 %
|
Lithium Ionic
Corp.
|
Bandeira
|
Americas
|
Development
|
Measured
|
3.3
|
1.38 %
|
|
|
|
|
Indicated
|
20.4
|
1.33 %
|
|
|
|
|
Inferred
|
18.3
|
1.37 %
|
Delta Lithium
Ltd.
|
Yinnetharra
|
APAC
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
6.7
|
1.00 %
|
|
|
|
|
Inferred
|
19.0
|
1.00 %
|
Green Technology Metals
Ltd.
|
Root
|
Americas
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
9.4
|
1.30 %
|
|
|
|
|
Inferred
|
5.2
|
1.03 %
|
Green Technology Metals
Ltd.
|
Seymour
|
Americas
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
6.1
|
1.25 %
|
|
|
|
|
Inferred
|
4.1
|
0.70 %
|
Winsome Resources
Ltd.
|
Adina
|
Americas
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
61.4
|
1.14 %
|
|
|
|
|
Inferred
|
16.5
|
1.19 %
|
Cygnus Metals
Ltd.
|
Pontax
|
Americas
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
-
|
-
|
|
|
|
|
Inferred
|
10.1
|
1.04 %
|
Patriot Battery Metals
Inc.
|
Shaakichiuwaanaan
|
Americas
|
Development
|
Measured
|
-
|
-
|
|
|
|
|
Indicated
|
80.1
|
1.44 %
|
|
|
|
|
Inferred
|
62.5
|
1.31 %
|
1. APAC =
Asia-Pacific; EMEA = Europe, Middle East, and Africa; Americas =
North America, and South America
|
ABOUT PATRIOT BATTERY METALS INC.
Patriot Battery Metals Inc. is a hard-rock lithium exploration
company focused on advancing its district-scale 100%-owned
Shaakichiuwaanaan Property (formerly known as Corvette) located in
the Eeyou Istchee James Bay region of Quebec, Canada, which is accessible year-round
by all-season road and is proximal to regional powerline
infrastructure. The Shaakichiuwaanaan Mineral Resource1,
which includes the CV5 & CV13 spodumene pegmatites, totals
80.1 Mt at 1.44% Li2O Indicated, and 62.5 Mt
at 1.31% Li2O Inferred, and ranks as the largest lithium
pegmatite resource in the Americas, and the 8th largest
lithium pegmatite resource in the world. Additionally, the
Shaakichiuwaanaan Property hosts multiple other spodumene pegmatite
clusters that remain to be drill tested, as well as significant
areas of prospective trend that remain to be assessed.
1 Shaakichiuwaanaan (CV5 & CV13)
Mineral Resource Estimate (80.1 Mt at 1.44% Li2O and 163
ppm Ta2O5 Indicated, and 62.5 Mt at 1.31%
Li2O and 147 ppm Ta2O5 ppm
Inferred) is reported at a cut-off grade of 0.40% Li2O
(open-pit), 0.60% Li2O (underground CV5), and 0.80%
Li2O (underground CV13) with an Effective Date of
June 27, 2024 (through drill hole
CV24-526). Mineral resources are not mineral reserves as they do
not have demonstrated economic viability.
For further information, please contact us at
info@patriotbatterymetals.com or by calling +1 (604) 279-8709,
or visit www.patriotbatterymetals.com. Please also refer to the
Company's continuous disclosure filings, available under its
profile at www.sedarplus.ca and www.asx.com.au, for available
exploration data.
This news release has been approved by the Board of
Directors.
"KEN
BRINSDEN"
Kenneth Brinsden, President, CEO,
& Managing Director
DISCLAIMER FOR FORWARD-LOOKING INFORMATION
This news release contains "forward-looking information" or
"forward-looking statements" within the meaning of applicable
securities laws and other statements that are not historical facts.
Forward-looking statements are included to provide information
about management's current expectations and plans that allows
investors and others to have a better understanding of the
Company's business plans and financial performance and
condition.
All statements, other than statements of historical fact
included in this news release, regarding the Company's strategy,
future operations, technical assessments, prospects, plans and
objectives of management are forward-looking statements that
involve risks and uncertainties. Forward-looking statements are
typically identified by words such as "plan", "expect", "estimate",
"intend", "anticipate", "believe", or variations of such words and
phrases or statements that certain actions, events or results
"may", "could", "would", "might" or "will" be taken, occur or be
achieved. Forward-looking statements in this release include, but
are not limited to, statements concerning: the timing of the
preliminary economic assessment, the timing of a feasibility study,
the potential for production, the cost of production and the
potential benefits thereof, the significant potential for further
resource growth at the Property through continued drill
exploration, notably of the potential for connectivity of the
pegmatite body of the CV5 and CV13 spodumene pegmatites, the
Company's position as a leading candidate to provide long-term
spodumene supply to the North American and European markets, the
recoverability of tantalum as a by-product, and the potential for a
series of relatively closely spaced/stacked, sub-parallel, and
sizable spodumene-bearing pegmatite bodies, with significant
lateral and depth extent, to be present near CV5 and CV13 spodumene
pegmatites.
Forward-looking information is based upon certain assumptions
and other important factors that, if untrue, could cause the actual
results, performance or achievements of the Company to be
materially different from future results, performance or
achievements expressed or implied by such information or
statements. There can be no assurance that such information or
statements will prove to be accurate. Key assumptions upon which
the Company's forward-looking information is based include, without
limitation, that proposed exploration and Mineral Resource Estimate
work on the Property will continue as expected, the accuracy of
reserve and resource estimates, the classification of resources
between inferred and the assumptions on which the reserve and
resource estimates are based, long-term demand for spodumene
supply, and that exploration and development results continue to
support management's current plans for Property development.
Readers are cautioned that the foregoing list is not exhaustive
of all factors and assumptions which may have been used.
Forward-looking statements are also subject to risks and
uncertainties facing the Company's business, any of which could
have a material adverse effect on the Company's business, financial
condition, results of operations and growth prospects. Some of the
risks the Company faces and the uncertainties that could cause
actual results to differ materially from those expressed in the
forward-looking statements include, among others, the ability to
execute on plans relating to the Company's Project, including the
timing thereof. In addition, readers are directed to carefully
review the detailed risk discussion in the Company's most recent
Annual Information Form filed on SEDAR+, which discussion is
incorporated by reference in this news release, for a fuller
understanding of the risks and uncertainties that affect the
Company's business and operations.
Although the Company believes its expectations are based upon
reasonable assumptions and has attempted to identify important
factors that could cause actual actions, events or results to
differ materially from those described in forward-looking
statements, there may be other factors that cause actions, events
or results not to be as anticipated, estimated or intended. There
can be no assurance that forward-looking information will prove to
be accurate, as actual results and future events could differ
materially from those anticipated in such information. As such,
these risks are not exhaustive; however, they should be considered
carefully. If any of these risks or uncertainties materialize,
actual results may vary materially from those anticipated in the
forward-looking statements found herein. Due to the risks,
uncertainties and assumptions inherent in forward-looking
statements, readers should not place undue reliance on
forward-looking statements.
Forward-looking statements contained herein are presented for
the purpose of assisting investors in understanding the Company's
business plans, financial performance and condition and may not be
appropriate for other purposes.
The forward-looking statements contained herein are made only as
of the date hereof. The Company disclaims any intention or
obligation to update or revise any forward-looking statements,
whether as a result of new information, future events or otherwise,
except to the extent required by applicable law. The Company
qualifies all of its forward-looking statements by these cautionary
statements.
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SOURCE Patriot Battery Metals Inc.