AZINCOURT ENERGY CORP. (“Azincourt” or the
“Company”)
(TSX.V: AAZ, OTC: AZURF), is pleased to
announce results from the Company’s Winter 2020 phase two drill
program at the East Preston uranium project, located in the western
Athabasca Basin, Saskatchewan, Canada.
The 2020 Winter drill campaign continues to
advance and enhance the prospectivity of the East Preston project.
Three main target areas were drill tested with promising basement
lithologies and graphitic structures intersected along with
associated, anomalous Rare Earth Element (“REE”) mineralization and
favourable alteration. The basement lithologies and litho-tectonic
setting at East Preston are very similar and appear analogous to
the Patterson Lake South-Arrow-Hook Lake/Spitfire uranium deposits’
host rocks and setting, and the recognition of REE mineralization
setting appears to represent a basement mineralizing system similar
to sandstone-hosted REE mineralization associated with uranium
deposition observed at the Wheeler River project in the eastern
Athabasca.
Nine diamond drill holes totalling 2,431 meters
were completed in three zones within a 7km x 2km area. All drill
holes targeted combined electromagnetic ± gravity geophysical and
geochemical anomalies in concert with structural/topographic
discontinuities. East Preston hosts multiple closely spaced
discreet graphitic conductor trends with coincident gravity low
anomalies often indicative of alteration or thicker overburden due
to enhanced glacial scouring over altered, or structurally
disrupted basement.
“We are very encouraged with the results from
the 2020 winter drill program at East Preston,” said Ted O’Connor,
Director and Technical Advisor for East Preston. “We continue to
see the right basement unconformity uranium setting – rocks,
structure and alteration from drilling on the project. The
recognition of what is believed to be a basement analogue to
uranium deposit-related REE mineralization and alteration suggests
that mineralizing fluid systems were active on the project, at the
right time. The winter results combined with the number and strike
extent of the existing, untested prospective conductor corridor
system target areas, ensures that the East Preston project is
advancing as we continue to vector towards our discovery goal,”
continued Mr. O’Connor.
“Drilling continues to show us we are on the
right track at East Preston,” said president & CEO, Alex
Klenman. “The presence of Rare Earth Element mineralization,
similar to Wheeler River, adds to the growing prospectivity of the
project. This data is a positive development that demonstrates East
Preston continues to reveal it has the necessary environment for
uranium deposition,” continued Mr. Klenman.
Numerous untested graphitic conductive corridor
trends remain on the project for additional drill testing. A summer
2020 ground geophysical targeting program is currently being
planned and scoped to support future drill programs based on the
existing property-wide heli-borne VTEM survey interpretation and
results.
Drilling Details
The 2020 winter diamond drilling program at the
Five Island Lakes area comprised a total of 2,431m drilled in nine
holes (Figure 1 – East Preston Drill Hole Location Map, below). The
drilling tested three zones within a 7km x 2km area, with targets
prioritized on basis of combined geophysical and geochemical
anomalies in concert with structural/topographic discontinuities.
All drill holes were analyzed downhole with a Mt. Sopris 2SNA gamma
probe. Representative lithologies and anomalous core samples were
collected and shipped to SRC Geoanalytical laboratories in
Saskatoon for complete geochemical analysis.
Figure 1 – East Preston Drill Hole Location
Map is available
at: https://www.globenewswire.com/NewsRoom/AttachmentNg/7bedbc94-6fd6-43fa-ad62-7ff37640c4d3
The East Preston project lies immediately south
of the interpreted southern edge of the Athabasca Basin, so no
Athabasca sandstone was expected. Overburden thickness ranged
from 15 to 33 m thick, and as expected, no Athabasca sandstone was
intersected.
Results of the drilling confirms interleaved
sequences of moderately to strongly deformed orthogneissic basement
rocks with compositions ranging from granodiorite to diorite,
monzonite to syenite, and gabbro with rare anorthosite. Most areas
of the property have been further intruded by minor 0.5 to 2m
simple pegmatite and/or mafic (+-lamprophyre) dykes, generally at
or near major lithologic contacts. Cohesive deformation fabrics
abound, with ductile mylonitic fabrics the most common, along with
occasional more brittle-cohesive cataclastic fabrics, and rare
brittle fault gouge. In general, the more strongly deformed zones
are associated with increased alteration intensity, with mafic host
rocks exhibiting elevated
chlorite-garnet-biotite+-hematite+-epidote and rare clay, and
intermediate to felsic host rocks altered with elevated
sericite(illite)-chlorite-hematite+-garnet.
Graphite-rich (1-25%) intervals are notable in
most holes with thicknesses ranging from 0.5 to 10m. Not
surprisingly, they are generally found within the most strongly
deformed rock sequences and are invariably associated with vein and
disseminated pyrite (1-20%), and broad halos of moderate to strong
blue and grey quartz alteration. Although graphite-bearing
deformation zones may be found in any lithology, they are
inordinately associated with darker (more mafic) schistose host
rocks. Collectively, these strongly altered and variably
deformed graphitic orthogneisses and schists constitute what
Saskatchewan government geologists coined “pseudopelite” (i.e.
mimicking altered metasedimentary [semi-pelite] paragneiss). This
rock “type” is one of the main uranium hosting units along the
Patterson Lake uranium deposit trend. Additional details by zone
are highlighted below:
A-Zone
The A-zone was tested by three holes (EP20001 to
003) all of which intersected two or more parallel graphite+
pyritic horizons mantled by strong bluish quartz-chlorite
alteration over intervals of 10’s of meters. Drilling in the A-zone
confirms the presence of a basement-hosted north to northeast
trending cohesive fault zone, associated with strong hydrothermal
fluid interactions centred around graphite-rich strata. Anomalous
probe radioactivity was detected bracketing the graphite-rich
horizons in 2 out 3 of the A-zone holes and is also associated with
anomalous REE contents.
B-Zone
The B-zone was tested by holes EP20006 to 009,
with all four holes intersecting similar sequences of graphite-rich
rocks mantled by strong quartz-chlorite alteration. Hole EP20007
encountered significant radioactivity at 281m depth, with a best
count of 2202 counts-per-second (cps) over a 2m intercept averaging
816 cps. Analytical results for this interval returned 3.5 ppm U,
and 587 ppm Th over 4.25m with associated trace element enrichment
(Cu, Zn, Pb, REEs). Drilling in the B-zone confirms the presence of
a second basement hosted northeast trending cohesive fault zone
with a history of strong hydrothermal fluid interactions which
includes the presence of anomalous radioactivity.
The strong chlorite-silica alteration zones
noted at both the A and B-zones that mantle the graphitic rocks
display ductile older structures with later semi-brittle to brittle
reactivation associated with anomalous radioactivity also display
highly anomalous Rare Earth Element (REE) contents. At the B-zone,
Heavy REE (HREE) contents are far more enriched than Light REE
(LREE). HREE examples include Ce (up to 8660 ppm), La (up to 4800
ppm) and Nd (up to 2720 ppm) that are up to 100 times enriched
relative to ‘normal’ background basement values, whereas LREE
examples Sm, Dy, Ho, etc. are enriched 5-10 times background. The
anomalous intervals, sampled over several metres have associated
enrichment in S, B, P2O5, Zr and Th interpreted, from chemical
element associations, to represent some combination of sulphide,
apatitite-xenotime-zircon REE-bearing mineralizing fluids in
silicified and reactivated fault zones. This structural
mineralizing system is interpreted to be post-Athabasca sandstone
deposition and could represent a basement-hosted analogue to the
sandstone-hosted MAW Zone REE mineralization on Denison Mines’
Wheeler River Project in Saskatchewan’s eastern Athabasca.
The MAW Zone is a sandstone-hosted HREE-Yttrium
dominant mineralized system without uranium, associated with
silica-chlorite-dravite alteration, located directly along strike 5
km southeast of the Phoenix Uranium Deposit (>70 Mlbs U3O8 –
Denison Website). The MAW Zone is also surrounded by multiple
uranium mineralized zones and uranium deposits along strike and
along sub-parallel graphitic-structural corridors, which is similar
to the East Preston basement litho-tectonic setting. According to
historical researchers, the Maw Zone REE phosphate mineralization
could represent the distal, near surface expression of the
diagenetic-hydrothermal system above developing unconformity-type
uranium deposits.
The presence of similar HREE mineralization in
basement structures displaying silica and boron enrichment at East
Preston confirms mineralizing basement fluid systems were active
and, although this system is not uranium-bearing, the
litho-tectonic setting and conditions remain highly prospective for
basement-host uranium mineralization discovery in the vicinity.
Follow-up drilling is warranted at both A-Zone and B-Zone conductor
trends as both infill drilling and strike extension testing.
Swoosh Zone
Two holes (EP20004 and 005) tested the Swoosh
zone which is a target of interest due to especially strong surface
geochemical and radon anomalies over a 4km long drainage lineament.
Neither hole intersected significant radioactivity or graphitic
strata, but a number of rubbly sections bounded by
quartz-chlorite+-hematite alteration indicates the presence of late
brittle fault structures in this sparsely tested zone. This zone
returned the best hydrothermal sulphide pathfinder results with up
to 1.5 ppm Ag over 1m and 673 ppm Zn over 1m in hole EP20005. No
immediate follow-up drilling is presently warranted for the Swoosh
area.
Follow-Up Program
Based on the recent drilling results and the
similar geological and structural setting to the prolific Patterson
Lake trend, detailed follow-up drilling is recommended for the
existing A- and B- zones, along with step-out drilling to the
northeast and south along the B-zone trend, to the South zone along
the SW strike extension of the A-zone. The additional target areas
that have yet to be drill tested are also recommended for target
refinement and future drill testing (Figure 2 – East Preston
Project Target Area Location Map with VTEM Interpretation,
below).
Figure 2 – East Preston Project Target Area
Location Map with VTEM Interpretation is available
at: https://www.globenewswire.com/NewsRoom/AttachmentNg/d476305d-0040-4223-a204-bde2b4438a6a
A summer 2020 work program is currently being
planned. Helicopter-supported ground geophysical surveys
including Horizontal Loop Electromagnetic (HLEM) and/or ground
gravity methods are being scoped for completion later this
summer/fall 2020. The surveys will be utilized to refine,
prioritize, and better locate conductive corridors more precisely
in several of the currently untested areas depicted in Figure 2.
Survey planning, layout and specifications will be started ideally
this month, however, with the current COVID-19 travel restrictions
into and out of northwestern Saskatchewan, in particular, there is
presently no indication of potential survey execution timing.
Figure 3: Project Location – Western Athabasca
Basin, Saskatchewan, Canada is available
at: https://www.globenewswire.com/NewsRoom/AttachmentNg/0b2ad860-3d73-4722-9baa-bc827a0a4ef7
About East Preston
Azincourt is currently earning towards 70%
interest in the 25,000+ hectare East Preston project as part of a
joint venture agreement with Skyharbour Resources (TSX.V: SYH), and
Dixie Gold Inc. (TSX.V: DG). Three prospective conductive, low
magnetic signature corridors have been discovered on the property.
The three distinct corridors have a total strike length of over 25
km, each with multiple EM conductor trends identified. Ground
prospecting and sampling work completed to date has identified
outcrop, soil, biogeochemical and radon anomalies, which are key
pathfinder elements for unconformity uranium deposit discovery.
The East Preston Project has multiple long
linear conductors with flexural changes in orientation and offset
breaks in the vicinity of interpreted fault lineaments – classic
targets for basement-hosted unconformity uranium deposits. These
are not just simple basement conductors; they are clearly
upgraded/enhanced prospectivity targets because of the structural
complexity.
The targets are basement-hosted unconformity
related uranium deposits similar to NexGen’s Arrow deposit and
Cameco’s Eagle Point mine. East Preston is near the southern
edge of the western Athabasca Basin, where targets are in a near
surface environment without Athabasca sandstone cover – therefore
they are relatively shallow targets, but can have great depth
extent when discovered. The project ground is located along a
parallel conductive trend between the PLS-Arrow trend and Cameco’s
Centennial deposit (Virgin River-Dufferin Lake trend).
Quality Assurance, Quality Control and
Data Verification
Drill core samples were interval grab samples of
interesting lithologies from 0.7m to 2 m in length, split in half
longitudinally, with one-half of the core retained, and the other
half placed in sealed bags and shipped to SRC Geoanalytical
Laboratories (SRC) in Saskatoon, SK for sample preparation,
processing and ICP-MS multi-element analysis using Total and
Partial digestion, gold by fire assay and boron by fusion. SRC is
an ISO/IEC 17025/2005 and Standards Council of Canada certified
analytical laboratory. The Company’s Qualified Persons for the
drill program, Mr. Jarrod Brown, P.Geo. of TerraLogic Exploration
Inc. and Mr. Ted O’Connor, P.Geo. have verified the data disclosed,
including drilling, sampling and analytical data. The program is
designed to include analytical quality assurance and control
routines comprising the systematic use of standards, blanks and
duplicate samples.
Qualified Person
The technical information in this news release
has been prepared in accordance with the Canadian regulatory
requirements set out in National Instrument 43- 101 and reviewed on
behalf of the company by Ted O’Connor, P.Geo. a director of the
Company, as well as a qualified person.
About Azincourt Energy
Corp.
Azincourt Energy is a Canadian-based resource
company specializing in the strategic acquisition, exploration and
development of alternative energy/fuel projects, including uranium,
lithium, and other critical clean energy elements. The
Company is currently active at its joint venture East Preston
uranium project in the Athabasca Basin, Saskatchewan, Canada, and
the Escalera Group uranium-lithium project located on the Picotani
Plateau in southeastern Peru.
ON BEHALF OF THE BOARD OF AZINCOURT
ENERGY CORP.
“Alex Klenman”Alex Klenman, President
& CEO
Neither the TSX Venture Exchange nor its
regulation services provider (as that term is defined in the
policies of the TSX Venture Exchange) accepts responsibility for
the adequacy or accuracy of this release.
This press release includes “forward-looking
statements”, including forecasts, estimates, expectations and
objectives for future operations that are subject to a number of
assumptions, risks and uncertainties, many of which are beyond the
control of Azincourt. Investors are cautioned that any such
statements are not guarantees of future performance and that actual
results or developments may differ materially from those projected
in the forward-looking statements. Such forward-looking
information represents management’s best judgment based on
information currently available. No forward-looking statement
can be guaranteed, and actual future results may vary
materially.
For further information please
contact:
Alex Klenman, President & CEOTel:
604-638-8063info@azincourtenergy.com
Azincourt Energy Corp.1430 – 800 West Pender
StreetVancouver, BC V6C
2V6www.azincourtenergy.com
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