/NOT FOR DISTRIBUTION TO UNITED STATES NEWS WIRE SERVICES OR FOR
DISSEMINATION IN THE UNITED
STATES/
ANNOUNCEMENT TO THE TORONTO STOCK
EXCHANGE
AND AUSTRALIAN SECURITIES EXCHANGE
SUBIACO, Western
Australia,
Aug. 17, 2015 /CNW/ - The Board of
RTG Mining Inc. ("RTG", "the Company") (TSX Code: RTG, ASX
Code: RTG) is pleased to announce significant high grade
gold and copper intercepts in the North Mineralized Zone of the
Mabilo Project in the
Philippines.
Drilling on the North Mineralised Zone commenced in June with
initial drill holes designed to support the revised geological
interpretation. Subsequent drilling on regularised sections has
continued to return excellent results with the new interpretation
in agreement with historically drilled oblique and off section
initial exploration drilling phases.
The intercepts returned from a number of drill hole has
identified multiple high grade zones within magnetite and an oxide
zone extending down to interface with karstic marble and limestone.
Drill hole MDH-111 which is incomplete, has been partially assayed
returned 54.10m at 3.39% Cu and 2.30g/t Au and remains
within mineralised magnetite.
The current resource remains open down dip, down plunge and
along strike in multiple directions, with all mineralisation found
to date being shallow enough to be amenable to open pit mining
techniques.
Highlights of the drilling program include –
- MDH-105 drilled on the Southern most section on the North
Mineralised Zone has successfully determined the down dip
continuation of the new interpretation*.
23.15m at 2.33% Cu and 1.71g/t Au and 21.46g/t Ag from 111.55
meters downhole.
- MDH-106 drilled through the central part of the magnetic model
intersected a wide interval of magnetite skarn*.
57.70m 1.93% Cu and 1.91g/t Au and 11.67g/t Ag from 71.00
meters downhole.
- MDH-107 drilled on the same section as MDH-105 intersected a
wide interval of magnetite skarn*.
38.70m at 2.28g/t Au and 2.25% Cu from 82.40 meters
downhole.
- MDH-111 is the Northern most drill hole drilled to date on the
North Body with mineralisation strike remaining open in a Northerly
direction*.
54.10m and 3.39% Cu and 2.30g/t Au and 14.64g/t Ag meters
downhole.
ABOUT MABILO
The Mabilo Project is located in Camarines Norte Province,
Eastern Luzon, Philippines. It
comprises one granted Exploration Permit (EP-014-2013-V) of
approximately 498 ha and two Exploration Permit Applications
(EXPA-000188-V) of 2,737 ha and (EXPA 0000 209-V) of 498 ha. The
Project area is relatively flat and is easily accessed by 15 km of
all-weather road from the highway at the nearby town of Labo.
Recent drilling has confirmed the re-interpretation of the North
Mineralised Zone. The new interpretation highlights a number of
areas where further drilling has the potential to increase the
current North Mineralised Zone strike (Figure 3). Further
strike extensions towards the North are supported by a number of
small intercepts of magnetite skarn drilled off section and down
structure. Similar to the South Mineralised Zone, further potential
beyond the magnetic model remains untested toward Venida.
MDH-104
MDH-104 was designed to confirm the extension along strike and
down dip of the magnetite skarn mineralization intersected in
MDH-102 (ASX reported 3rd July
2015). Drilling intersected wide fault breccia zone from
94.70 to 159.90 meters (Figure 4). A narrow zone of
silica-pyrite-magnetite skarn breccia (159.90 to 164.60m) and
brecciated magnetite skarn (197.10 to 198.90m) was intersected
within the fault zone. The fault position is analogous to the fault
breccia within the Southern Mineralised Zone. Intercepts are
reported as down hole. Due to faulted geology true widths have not
been determined.
|
MDH-104
|
From
|
To
|
Intercept
(m)
|
Au
ppm
|
Cu
%
|
Ag
ppm
|
Fe
%
|
Mineralisation
|
Recovery
(%)
|
|
162.00
|
164.00
|
2.00
|
3.26
|
2.11
|
10.40
|
13.67
|
Pyrite-Silica
Breccia
overprint
|
60.50
|
|
and
|
197.1
|
198.9
|
1.80
|
1.40
|
2.17
|
5.80
|
53.69
|
Magnetite
Skarn
|
100
|
MDH-105
MDH-105 is located 40m to the South-East of MDH-104 on the next
section (Figure 5). Drilling here intersected magnetite
skarn with moderate to strong pyrite overprint and chalcopyrite
from 111.55 to 133.35 meters. Intercepts are reported as down hole
due to insufficient drilling in this part of the mineralized system
to determine true widths.
|
MDH-105
|
From
|
To
|
Intercept
(m)
|
Au
ppm
|
Cu
%
|
Ag
ppm
|
Fe
%
|
Mineralisation
|
Recovery
(%)
|
|
111.55
|
134.7
|
23.15
|
1.71
|
2.33
|
21.46
|
36.72
|
Magnetite
Skarn
|
77.31
|
MDH-106
MDH-106 was designed to infill and define the true thickness of
the magnetite skarn. A broad interval of fifty seven (57) meters in
approximate true thickness was intersected. Drilling on this
section (Figure 4) follows up on two vertical drill holes MDH-028
and MDH-020, with MDH-020 reporting high grade oxide and chalcocite
near surface (Reported 5th December 2015 to ASX by Sierra Mining)
|
MDH-106
|
From
|
To
|
Intercept
(m)
|
Au
ppm
|
Cu
%
|
Ag
ppm
|
Fe
%
|
Mineralisation
|
Recovery
(%)
|
|
56.00
|
68.00
|
12.00
|
1.21
|
1.45
|
5.15
|
14.14
|
Garnet
Skarn
with
Magnetite
Veins
|
99.17
|
|
including
|
61.00
|
64.00
|
3.00
|
2.59
|
2.71
|
6.92
|
20.82
|
Garnet
Skarn
|
100.00
|
|
and
|
71.00
|
128.70
|
57.70
|
1.91
|
1.93
|
11.67
|
41.89
|
Magnetite
Skarn
|
96.71
|
|
including
|
81.00
|
93.00
|
12.00
|
2.81
|
2.97
|
11.19
|
42.55
|
Magnetite
Skarn
|
100.00
|
|
and
including
|
112.00
|
116.00
|
4.00
|
3.52
|
3.34
|
16.78
|
50.03
|
Magnetite
Skarn
|
87.50
|
MDH-107
MDH-107 intersected a thirty eight point seven meter wide
chalcopyrite-rich magnetite skarn. Mineralization was intersected
from 82.40 to 121.10 meters (Figure 5). Magnetite-skarn is
overprinted with intervals of coarse grained chalcopyrite
responsible for very high grade massive chalcopyrite intervals
including 1m at 27.03% Cu and 15.52 g/t Au from 114m. Drilling is
in the preferred orientation to evaluate true width of mineralised
magnetite skarn which is estimated to be 38.70m.
|
MDH-107
|
From
|
To
|
Intercept
(m)
|
Au
ppm
|
Cu
%
|
Ag
ppm
|
Fe
%
|
Mineralisation
|
Recovery
(%)
|
|
and
|
65.00
|
78.45
|
13.45
|
0.93
|
1.05
|
7.96
|
16.75
|
Oxidized
Garnet
Skarn
|
86.67
|
|
and
|
82.40
|
121.10
|
38.70
|
2.28
|
2.25
|
8.25
|
45.15
|
Magnetite
Skarn
|
100.00
|
|
including
|
88.00
|
93.00
|
5.00
|
1.73
|
1.83
|
4.32
|
40.55
|
Magnetite
Skarn
|
100.00
|
|
and
including
|
114.00
|
115.00
|
1.00
|
15.52
|
27.03
|
46.30
|
31.50
|
Magnetite
Skarn
|
100.00
|
|
and
including
|
115.00
|
116.00
|
1.00
|
15.40
|
1.70
|
12.10
|
49.72
|
Magnetite
Skarn
|
100.00
|
|
and
including
|
116.00
|
119.00
|
3.00
|
2.17
|
2.07
|
4.13
|
53.01
|
Magnetite
Skarn
|
100.00
|
|
and
|
121.10
|
132.20
|
11.10
|
0.84
|
0.64
|
6.60
|
23.13
|
Garnet Skarn
with
Magnetite
Skarn
|
100.00
|
MDH-109
MDH-109 (Figure 5) was designed to test up-dip extent and
continuity of mineralization defined by MDH-107 and down dip
continuity of MDH-045 (Reported to ASX 13th May 2013 by Sierra Mining). Drilling intersected
a relatively thin oxide gold zone followed by copper oxide zone
with strong copper depletion, true with has not been determined due
to the extensive patchy oxidation of primary magnetite.
|
MDH-109
|
From
|
To
|
Intercept
(m)
|
Au
ppm
|
Cu
%
|
Ag
ppm
|
Fe
%
|
Mineralisation
|
Recovery
(%)
|
|
41.70
|
55.30
|
13.60
|
2.51
|
0.10
|
2.36
|
24.25
|
Oxide with
pyritic
overprint.
|
85.22
|
|
including
|
48.00
|
50.00
|
2.00
|
6.82
|
0.02
|
0.85
|
4.57
|
Oxidized
bleached
zone.
|
98.50
|
|
including
|
53.00
|
55.30
|
2.30
|
4.23
|
0.14
|
1.20
|
36.92
|
Pyritic
overprint.
|
50.87
|
MDH-111
MDH-111 (Figure 6) is designed to follow up on a number of
historical drill holes MDH-36, MDH-50, MDH-52 and MDH-54 section
which intersected magnetite and frequently terminated in marble.
The new interpretation infers the historical drilling to be the
interface of skarn with marble. Drilling the correct orientation
has successfully intersected the true thickness of mineralization
with drilling temporarily paused currently within magnetite skarn.
True width has not been determined at this time as the drill hole
is paused within mineralised magnetite skarn.
|
MDH-111
|
From
|
To
|
Intercept
(m)
|
Au
ppm
|
Cu
%
|
Ag
ppm
|
Fe
%
|
Mineralisation
|
Recovery
(%)
|
|
63.00
|
117.10
|
54.10
|
2.30
|
3.39
|
14.64
|
45.83
|
Oxide
and
Magnetite
Skarn
|
84.14
|
|
including
|
65.00
|
70.00
|
5.00
|
3.76
|
3.92
|
10.97
|
26.65
|
Oxide and
Magnetite
Skarn
|
100.00
|
|
and
including
|
86.00
|
95.00
|
9.00
|
1.99
|
6.52
|
27.79
|
35.67
|
Magnetite
Skarn with
|
52.00
|
|
and
including
|
105.00
|
111.00
|
6.00
|
3.33
|
3.83
|
22.79
|
54.78
|
Magnetite
Skarn
|
95.83
|
|
and
including
|
115.00
|
117.10
|
2.10
|
4.29
|
4.78
|
28.23
|
48.48
|
Magnetite
Skarn
|
100.00
|
QUALIFIED PERSON AND COMPETENT PERSON STATEMENT
The information in this report that relates to Exploration
Results at the Mabilo Project is based upon information prepared by
or under the supervision of Robert Ayres
BSc (Hons), who is a Qualified Person and a Competent
Person. Mr Ayres is a member of the Australian Institute of
Geoscientists and a full-time employee of Mt Labo Exploration and
Development Company, a Philippine mining company, and an associate
company of RTG Mining Limited. Mr Ayres has sufficient experience
that is relevant to the style of mineralisation and type of deposit
under consideration and to the activity being undertaken, to
qualify as a Competent Person as defined in the 2012 Edition of the
"Australasian Code for Reporting of Exploration Results, Mineral
Resources and Ore Reserves" and to qualify as a "Qualified Person"
under National Instrument 43-101 – Standards of Disclosure for
Mineral Projects ("NI 43-101"). Mr. Ayres has verified the data
disclosed in this release, including sampling, analytical and test
data underlying the information contained in the release. Mr. Ayres
consents to the inclusion in the report of the matters based on his
information in the form and the context in which it appears.
ABOUT RTG MINING INC
RTG Mining Inc. is a mining and exploration company listed on
the main board of the Toronto Stock Exchange and Australian
Securities Exchange Limited. RTG is focused on developing the
high grade copper/gold/magnetite Mabilo Project and advancing
exploration on the highly prospective Bunawan Project, both in
the Philippines, while also
identifying major new projects which will allow the Company to move
quickly and safely to production.
RTG has an experienced management team (previously responsible
for the development of the Masbate Gold Mine in the Philippines through CGA Mining Limited),
and has B2Gold as one of its major shareholders in the Company.
B2Gold is a member of both the S&P/TSX Global Gold and Global
Mining Indices.
CAUTIONARY NOTE REGARDING FORWARD LOOKING STATEMENTS
This announcement includes certain "forward-looking statements"
within the meaning of Canadian securities legislation. Accuracy of
mineral resource and mineral reserve estimates and related
assumptions and inherent operating risks, are forward-looking
statements. Forward-looking statements involve various risks and
uncertainties and are based on certain factors and assumptions.
There can be no assurance that such statements will prove to be
accurate, and actual results and future events could differ
materially from those anticipated in such statements. Important
factors that could cause actual results to differ materially from
RTG's expectations include uncertainties related to fluctuations in
gold and other commodity prices and currency exchange rates;
uncertainties relating to interpretation of drill results and the
geology, continuity and grade of mineral deposits; uncertainty of
estimates of capital and operating costs, recovery rates,
production estimates and estimated economic return; the need for
cooperation of government agencies in the development of RTG's
mineral projects; the need to obtain additional financing to
develop RTG's mineral projects; the possibility of delay in
development programs or in construction projects and uncertainty of
meeting anticipated program milestones for RTG's mineral projects
and other risks and uncertainties disclosed under the heading "Risk
Factors" in RTG's Annual Information Form for the year ended
31 December 2014 filed with the
Canadian securities regulatory authorities on the SEDAR website at
sedar.com.
Appendix 1: Location of Reported Drill
Holes
|
HOLE
ID
|
Location
|
|
GPS
|
Orientation True
Nth
|
Depth
|
|
Coordinates (UTM
WGS84)
|
|
Prospect
|
|
East
|
North
|
RL
|
Dip
|
Azi
|
E.O.H
(m)
|
|
MDH-104
|
North
|
Resource
|
476021
|
1560166
|
103
|
-55.00
|
50.00
|
222.00
|
|
MDH-105
|
North
|
Resource
|
476048
|
1560136
|
107
|
-55.00
|
50.00
|
185.10
|
|
MDH-106
|
North
|
Resource
|
476053
|
1560193
|
105
|
-55.00
|
50.00
|
170.80
|
|
MDH-107
|
North
|
Resource
|
476084
|
1560161
|
106
|
-55.00
|
50.00
|
163.30
|
|
MDH-108**
|
North
|
Resource
|
476133
|
1560217
|
104
|
-55.00
|
50.00
|
123.60
|
|
MDH-109
|
North
|
Resource
|
476112
|
1560188
|
104
|
-55.00
|
50.00
|
111.20
|
|
MDH-110
|
North
|
Resource
|
476028
|
1560091
|
106
|
-55.00
|
50.00
|
149.1*
|
|
MDH-111
|
North
|
Resource
|
476059
|
1560254
|
103
|
-55.00
|
50.00
|
117.1*
|
|
*Drillhole
on-going
|
|
|
|
|
|
|
|
|
**Drill hole did
not intersect mineralisation
|
All co-ordinates in UTM-WGS84 (51 N). All collars have been
surveyed using handheld GPS and will be subject to professional
survey pickup at a later date using DGPS system.
Appendix 1: JORC Code 2012
Edition Table 1
Section 1 Sampling Techniques and Data
|
|
|
|
Criteria
|
JORC Code
explanation
|
Commentary
|
|
Sampling
techniques
|
-
|
Nature and quality
of sampling (e.g. cut channels, random chips, or specific
specialised 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.
|
-
|
The assay data
reported herein is based on sampling of diamond drill core of PQ,
HQ and NQ diameter which was cut with a diamond core saw. Samples
are generally of 1 m length, although occasionally slightly longer
or shorter where changes in lithology, core size or core recovery
required adjustments; samples are not more than 2 m
length.
|
|
|
|
|
|
|
-
|
Include reference
to measures taken to ensure sample representivity and the
appropriate calibration of any measurement tools or systems
used.
|
-
|
The length of each
drill run is recorded and the recovery for each run calculated on
site and checked again at the core shed. Certified reference
standards and blank samples were submitted to assess the accuracy
and precision of the results and every 20th sample was sawn into
two and the two quarter core samples submitted for analysis
separately as a duplicate sample.
|
|
|
|
|
|
|
-
|
Aspects of the
determination of mineralisation that are Material to the Public
Report.
|
-
|
Half core samples
were cut and sent for analysis by an independent ISO-certified
laboratory (Intertek McPhar Laboratory) in Manila. Samples were
crushed and pulverised (95% <75 μm). Gold was analysed by 50 g
fire assay and the other elements including copper and iron by
ICP-MS (Inductively Coupled Plasma Mass Spectrometry) or ICP-OES
(Inductively Coupled Plasma Optical Emission Spectrometry)
following a four-acid digest.
|
|
Drilling
techniques
|
-
|
Drill type (e.g.
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).
|
-
|
Drilling was by PQ,
HQ and NQ diameter, triple tube diamond coring. The core was not
orientated.
|
|
Drill sample
recovery
|
-
|
Method of
recording and assessing core and chip sample recoveries and results
assessed.
|
-
|
Core recovery is
initially measured on site by trained technicians and by the
supervising geologist. Any core loss is measured, the percentage is
calculated and both are recorded in the geotechnical log for
reference when assessing assay results.
|
|
|
|
|
|
|
-
|
Measures taken to
maximise sample recovery and ensure representative nature of the
samples.
|
-
|
All care is taken to
ensure maximum recovery of diamond core and drillers are informed
of the importance of core recovery. Any areas of poor core recovery
are sampled separately thus assay results can be directly related
to core recovery.
The majority of the mineralisation is in fresh rock
where recoveries are greater than 90%. Most mineralisation occurs
in wide intersections of massive magnetite skarn with relatively
uniform copper and gold grades. Core loss occurs in fracture zones
but is usually not a significant problem i.e. the core lost in
fracture zones is unlikely to have been significantly higher or
lower grade than the surrounding material. In the weathered
hematitic oxidised zones some core loss is unavoidable, but overall
recovery is generally >90% and the core loss is volumetrically
minor in the mineralised zones. In areas of poor recovery, the
sample intervals are arranged to coincide with drill runs, thus
areas of different core loss percentage are specific to individual
samples which can be assessed when interpreting analytical results
and modelled in future resource estimation studies. Where an area
of 100% core loss is identified the sample intervals are marked to
each side of the zone and the zone is designated "No core" and
assigned zero value in the various log sheets and geochemical
database.
|
|
|
|
|
|
|
-
|
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.
|
-
|
There is no
discernible relationship between core recovery and grade. The skarn
bodies are relatively uniform over significant lengths and the
copper and gold grades are not related to clay and fracture zones
which are the main causes of core loss.
|
|
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.
|
-
|
Diamond drill core
for each entire drill hole was logged in significant detail in a
number of logging sheets including a geological log, a structural
log, a geotechnical log and a magnetic susceptibility log for the
entire drill hole. Mineralised and sampled intervals are logged
individually in a separate quantitative mineral log with
percentages of the different copper minerals being recorded. The
logging is appropriate for mineral resource estimates and mining
studies.
|
|
|
|
|
|
|
-
|
Whether logging is
qualitative or quantitative in nature. Core (or costean, channel,
etc.) photography.
|
-
|
Most of the
geological logging is a mixture of qualitative (descriptions of the
various geological features) and quantitative (numbers and angles
of veins and fracture zones, mineral percentages etc.). The
quantitative mineralisation log and the magnetic susceptibility log
are quantitative. Photographs are taken of all core (both wet and
dry) prior to the core being cut.
|
|
|
|
|
|
|
-
|
The total length
and percentage of the relevant intersections logged.
|
-
|
All core, including
barren overburden is logged in the various logging sheets noted
above apart from the quantitative mineralisation log in which only
the mineralised intervals sent for geochemical analysis are logged
in greater detail.
|
|
Sub-sampling
techniques and sample preparation
|
-
|
If core, whether
cut or sawn and whether quarter, half or all core
taken.
|
-
|
All sampling data is
from diamond drill core. Samples are of sawn half core except for
duplicate samples which are quarter core. Half core is bagged and
sent to an ISO-certified independent laboratory for analysis. The
other half retained for reference and/or further
testwork.
|
|
|
|
|
|
|
-
|
If non-core,
whether riffled, tube sampled, rotary split, etc and whether
sampled wet or dry.
|
-
|
Not applicable for
diamond core drilling.
|
|
|
|
|
|
|
-
|
For all sample
types, the nature, quality and appropriateness of the sample
preparation technique.
|
-
|
All core samples were
dried, crushed to 95% <10 mm and a 1.5 kg sub-sample is
separated using a riffle splitter and pulverised to 95% <75 μm.
A 50 g sub-sample is utilised as a fire-assay charge for gold
analysis. The sample preparation technique and sub-sampling is
appropriate for the mineralisation.
|
|
|
|
|
|
|
-
|
Quality control
procedures adopted for all sub-sampling stages to maximise
representivity of samples.
|
-
|
Blank samples and
duplicate samples are submitted routinely to monitor the sampling
and analytical process and to ensure that samples are
representative of in situ material. One in every 20 samples of half
core is sawn again to produce two quarter core duplicate samples
which are submitted to the laboratory separately with different
sample numbers. A blank sample was inserted into sample batches at
every 20th sample.
|
|
|
|
|
|
|
-
|
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.
|
-
|
The magnetite skarn
mineralisation occurs in extensive zones of magnetite skarn with
disseminated chalcopyrite, containing gold. The sample size of
approximately 1 m core length is suitable in respect to the grain
size of the mineralisation.
|
|
|
|
|
|
|
-
|
Whether sample
sizes are appropriate to the grain size of the material being
sampled.
|
-
|
The sample size is
considered appropriate for the material sampled. It is believed
that grain size has no bearing on the grade of the sampled
material.
|
|
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.
|
-
|
All core samples were
analysed at an ISO-certified independent laboratory. Gold was
analysed by 50 g fire assay and the other elements including copper
and iron were analysed by ICP-MS or ICP-OES following a four acid
digest. The sample preparation and assay techniques are of
international industry standard and can be considered
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.
|
-
|
No geophysical tools
were used for any analysis reported herein. Magnetic susceptibility
readings are used in magnetic modelling but are not used to
estimate magnetite or Fe content.
|
|
|
|
|
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|
-
|
Nature of quality
control procedures adopted (e.g. standards, blanks, duplicates,
external laboratory checks) and whether acceptable levels of
accuracy (ie lack of bias) and precision have been
established.
|
-
|
Quality control
completed by RTG included analysis of standards, blanks, and
duplicates. Commercial Certified Reference Materials were inserted
into sample batches every 40th sample. A blank sample
was inserted every 20th sample; the blank sample
material has been sourced and prepared from a local quarry. One in
every 20 core samples is cut into 2 quarter core samples which were
submitted independently with their own sample numbers. In addition,
Intertek conducted their own extensive check sampling as part of
their own internal QAQC processes which is reported in the assay
sheets. A record of results from all duplicates, blanks and
standards is maintained for ongoing QA/QC assessment. Examination
of all the QAQC sample data indicates satisfactory performance of
field sampling protocols and the assay laboratory.
|
|
Verification of
sampling and assaying
|
-
|
The verification
of significant intersections by either independent or alternative
company personnel.
|
-
|
Significant
mineralisation intersections were verified by alternative company
personnel.
|
|
|
|
|
|
|
-
|
The use of twinned
holes.
|
-
|
No twinned holes have
been drilled.
|
|
|
|
|
|
|
-
|
Documentation of
primary data, data entry procedures, data verification, data
storage (physical and electronic) protocols.
|
-
|
Data documentation,
verification and storage is conducted in accordance with RTG's
Standard Operating Procedures Manual for the Mabilo Project. The
diamond drill core is manually logged in significant detail in a
number of separate Excel template logging sheets. Logging is
recorded manually on logging sheets and transcribed into protected
Excel spreadsheet templates or entered directly into the Excel
templates. The data are validated by both the Project Geologist and
the company Database Manager and uploaded to the dedicated project
database where they are merged with assay results reported
digitally by the laboratory. Hard copies of all logging sheets are
kept at the Project office in Daet.
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|
|
|
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|
-
|
Discuss any
adjustment to assay data.
|
-
|
No adjustments have
been made to assay data.
|
|
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.
|
-
|
Drill-hole collars
are initially surveyed with a hand-held GPS with an accuracy of
approximately +/- 5 m. Completed holes are surveyed by an
independent qualified surveyor on a periodic basis using standard
differential GPS (DGPS) equipment achieving sub-decimetre accuracy
in horizontal and vertical position.
|
|
|
|
|
|
|
-
|
Specification of
the grid system used.
|
-
|
Drill collars are
surveyed in UTM WGS84 Zone 51N grid.
|
|
|
|
|
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|
-
|
Quality and
adequacy of topographic control.
|
-
|
The Mabilo project
area is relatively flat with total variation in topography less
than 15 m. Topographic control is provided by DGPS
surveying.
|
|
Data spacing
and distribution
|
-
|
Data spacing for
reporting of Exploration Results.
|
-
|
Drill holes are
planned on a nominal grid with 20 m between drill holes on 40 m
spaced lines.
|
|
|
|
|
|
|
-
|
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.
|
-
|
The drill hole
spacing was designed to determine the continuity and extent of the
mineralised skarn zones. Based on statistical assessment of drill
results to date, the nominal 40 x 20 m drill hole spacing is
sufficient to support Mineral Resource estimation.
|
|
|
|
|
|
|
-
|
Whether sample
compositing has been applied.
|
-
|
No compositing of
intervals in the field was undertaken.
|
|
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.
|
-
|
No bias attributable
to orientation of sampling upgrading of results has been
identified.
|
|
|
|
|
|
|
-
|
If the
relationship between the drilling orientation and the orientation
of key mineralised structures is considered to have introduced a
sampling bias, this should be assessed and reported if
material.
|
-
|
No bias attributable
to orientation of sampling upgrading of results has been
identified.
|
|
Sample
security
|
-
|
The measures taken
to ensure sample security.
|
-
|
Chain of custody is
managed by RTG employees. Samples were stored in secure storage
from the time of drilling, through gathering and splitting.
Remaining core is kept in a secure compound at the Company regional
office in Daet town and guarded at night. Samples are sent directly
from the core shed to the laboratory packed in secured and sealed
plastic drums using either Company vehicles or a local transport
company. A standard Chain of Custody form is signed by the driver
responsible for transporting the samples upon receipt of samples at
the core yard and is signed by an employee of the laboratory on
receipt of the samples at the laboratory. Completed forms are
returned to the Company for filing.
|
|
Audits or
reviews
|
-
|
The results of any
audits or reviews of sampling techniques and data.
|
-
|
The sampling
techniques and QA/QC data are reviewed on an ongoing basis by
Company management and independent consultants.
|
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 Mabilo Project is
covered by Exploration Permit EP-014-2013-V and Exploration Permit
Applications EXPA-000188-V and EXPA-0000209-V. EP-014-2013-V was
issued to Mt Labo Exploration and Development Corporation ("Mt
Labo"), an associated entity of RTG Mining Inc. There is a 1%
royalty payable on net mining revenue received by Mt Labo in
relation to EP-014-2013-V.
Mt Labo has entered
into a joint venture agreement with Galeo Equipment and Mining
Company, Inc. ("Galeo") to partner in exploring and developing the
Mabilo and Nalesbitan Projects. Galeo can earn up to a 36% interest
in the Projects, down to 200 m below surface, by contributing
approximately US$4,250,000 of exploration drilling and management
services for the Projects over a 2 year period.
In November 2013,
Sierra Mining Limited ("Sierra"), a wholly owned subsidiary of RTG,
and Galeo signed a Memorandum of Understanding ("MOU") setting out
proposed changes to the joint venture agreement to remove the depth
limit of 200 m from the agreement and provide for additional
drilling of 5,000 m below 200 m. The MOU also provides for Galeo to
be granted its 36% interest up front with the ability for RTG to
claw-back any interest deemed not earned at the end of the
claw-back period. The amendments to the JV Agreement are subject to
Sierra shareholder approval.
Sierra has also
entered a second MOU with Galeo whereby Galeo can earn an
additional 6% interest in the joint venture by mining the initial
1.5 Mt of waste at Mabilo or Nalesbitan and other requirements
including assistance with permitting. The MOU is subject to a
number of conditions precedent, including Sierra shareholder
approval.
|
|
|
|
|
|
|
-
|
The
security of the tenure held at the time of reporting along with any
known impediments to obtaining a license to operate in the
area.
|
-
|
The tenure over the
area currently being explored at Mabilo is a granted Exploration
Permit which is considered secure. There is no native title or
Indigenous ancestral domains claims at Mabilo.
|
|
Exploration
done by other parties
|
-
|
Acknowledgment and
appraisal of exploration by other parties.
|
-
|
The only significant
previous exploration over the Mabilo project area was a drilling
program at another site within the tenement and a ground magnetic
survey. RTG (or its predecessor Sierra) has reported this data in
previous reports to the ASX and used the ground magnetic survey as
a basis for initial drill siting. Subsequently RTG conducted its
own ground magnetic survey with closer spaced survey lines and
reading intervals which supersedes the historical program. There
was no known previous exploration in the area of the reported
Mineral Resource.
|
|
Geology
|
-
|
Deposit type,
geological setting and style of mineralisation.
|
-
|
Mineralisation at
Mabilo can be defined as a magnetite-copper-gold skarn which
developed where the magnetite-copper-gold mineralisation replaced
calcareous horizons in the Eocene age Tumbaga Formation in the
contact zone of a Miocene diorite intrusion.
|
|
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:
|
|
All relevant drill
hole information has been previously reported to the ASX. No
material changes have occurred to this information since it was
originally reported.
|
|
|
-
|
easting and
northing of the drill hole collar
|
|
|
|
|
-
|
elevation or RL
(Reduced Level – elevation above sea level in metres) of the drill
hole collar
|
|
|
|
|
-
|
dip and azimuth of
the hole
|
|
|
|
|
-
|
down hole length
and interception depth
|
|
|
|
|
-
|
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.
|
-
|
All relevant data has
been reported.
|
|
Data
aggregation methods
|
-
|
In reporting
Exploration Results, weighting averaging techniques, maximum and/or
minimum grade truncations (e.g. cutting of high grades) and cut-off
grades are usually Material and should be stated.
|
-
|
Not reporting
exploration results.
|
|
|
|
|
|
|
-
|
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.
|
-
|
Not reporting
exploration results.
|
|
|
|
|
|
|
-
|
The assumptions
used for any reporting of metal equivalent values should be clearly
stated.
|
-
|
No metal equivalent
grades have been used.
|
|
Relationship
between mineralisation widths and intercept
lengths
|
-
|
These
relationships are particularly important in the reporting of
Exploration Results.
|
-
|
The Mabilo drill have
been drilled both vertically and inclined. The orientation of the
mineralised bodies is based on interpretation of geology from drill
holes supported by magnetic modelling which indicates that much of
the mineralisation is dipping to the southwest.
|
|
|
|
|
|
|
-
|
If the geometry of
the mineralisation with respect to the drill hole angle is known,
its nature should be reported.
|
-
|
The interpreted
orientation of the mineralised bodies is based on magnetic
modelling and drill-hole data and is documented in the report. The
fact that the intersections are in a dipping body and therefore not
true widths has been 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').
|
-
|
No intervals reported
can be assumed to be a true width of the mineralisation.
|
|
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.
|
-
|
Refer to figures
within the main body of this report.
|
|
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.
|
-
|
Not
applicable.
|
|
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.
|
-
|
All meaningful
exploration data concerning the Mabilo Project has been reported in
previous reports to the ASX.
|
|
Further
work
|
-
|
The nature and
scale of planned further work (e.g. tests for lateral extensions or
depth extensions or large-scale step-out drilling).
|
-
|
Drilling is ongoing
at the Mabilo Project which will systematically test magnetic
bodies and step-out targets along strike and between the North
Mineralised Zone and the South Mineralised Zone as well as down-dip
from these zones.
|
|
|
|
|
|
|
-
|
Diagrams clearly
highlighting the areas of possible extensions, including the main
geological interpretations and future drilling areas, provided this
information is not commercially sensitive.
|
-
|
Refer to figures
within the main body of this report.
|
SOURCE RTG Mining Inc.