rpt on spectral ip & mag survs happy face prop madoc … · location map is shown hi figure l...
TRANSCRIPT
31C11SW2007 2.23257 MADOC 010
HAPPY FACE PROPERTYMADOC PROJECT
MADOC TWP., ONTARIOREPORT ON
JVX SPECTRAL IP/RESISTIVITY Z MAGNETOMETER SURVEYS
MARCH 2002 CANDOR VENTURES CORPORATION
PROVINCIAL RECORDING OFFICE - SUDBURY
R E C E f v. E D
A.M.APR 1 8 2002
P.M.
JVX Ltd.
RECEIVED
APR 18 2002 .
8EOSCIEMCF ASSESSMENT l Of f ICE (
REPORT
ON
IP/RESISTIVITY & MAGNETOMETER SURVEYSCONDUCTED ON THE
HAPPY FACE PROPERTY
MADOC PROJECT
MADOC TWP.
EASTERN ONTARIO
NTS: 31 C/12
For: Candor Ventures Corp.Suite 3062 Toronto St.,Toronto, ONM5C 2B6Tel: (416) 363-4376Fax: (416) 363-4606Attention: Paul Chamois
By: JVX Ltd.60 Wilmot Street West, Unit #22 Richmond Hill, Ontario L4B 1M6 Tel: (905)731-0972 Fax: (905)731-9312 Contact: Blame Webster
JVX Ref: 2-8 April 2002
J VX
TABLE OF CONTENTS
1. INTRODUCTION................................................................................................................ .. .1
2. SURVEY SPECIFICATIONS AND PRODUCTION SUMMARY.......................... ———— .. —— .2
3. PERSONNEL, —— .... ——— ....................... ——— ..... —— ............................................ ———— .... —— ...5
4. FIELD INSTRUMENTATION....... __ ........ —— ....... ———— -. ———— ....... ——— ~ ——————— 6
4.14.2 IP RECEIVER ..................................................................................................................................6
4.2.1 Z)j;jo7e-Djpofev4rray................................................................................................................54.3 MAGNETOMETERS..................................................................................................................-....-?
5. DATAPROCESSING......................~..............~.......................~..................~.............................."". 8
5.1 IP/RESISTTVTTY......................................................................................................................"5.2 MAGNETICS............................................................................................................................---^53 DIGITAL DATA.......................................................................................................................-.......^
6. INTERPRETATION METHODOLOGY ___ .. — ........... — ...... ——— .. ————————— .. — .9
6.1 ip/RESismviTY......................................................................^
7. DISCUSSION OF RESULTS.................... — ......................... —————————————— . — .. — 11
8. SUMMARY AND RECOMMENDATIONS . —— . — ...................... ———————————— . —— .....13
J VX
LIST OF FIGURES
Figure l: Location MapFigure 2: Grid Location l Claim Map
LIST OF TABLES
Table 1: Specifications for the IP/Resistivity Survey ........................................................2Table 2: Specifications for the Magnetometer Survey.......................................................2Table 3: Daily Production Summary ..................................................................................3Table 4: Production Summary for the IP/Resistivity Survey.............................................3Table 5: Production Summary for the Magnetometer Survey ...........................................4
LIST OF APPENDICES
Appendix A: Instrument Specification Sheets Appendix B: Plates
J VX__________________LIST OF PLATES
HAPPY FACE GRID
Plate l: Compilation map, Scale l: 2500
Dipole-Dipole with 'a' spacing of 25 metersPlate 2: Chargeability, Resistivity, Metal Factor
Pseudosection, L600 W, Scale 1: 2500 Plate 3: Chargeability, Resistivity, Metal Factor
Pseudosection, L400 W, Scale 1:2500 Plate 4: Chargeability, Resistivity, Metal Factor
Pseudosection, L200 W, Scale 1:2500 Plate 5: Chargeability, Resistivity, Metal Factor
Pseudosection, LO E, Scale 1: 2500 Plate 6: Chargeability, Resistivity, Metal Factor
Pseudosection, L200 E, Scale 1: 2500 Plate 7: Chargeability, Resistivity, Metal Factor
Pseudosection, L400 E, Scale 1:2500 Plate 8: Chargeability, Resistivity, Metal Factor
Pseudosection, L600 E, Scale l: 2500 Plate 9: Chargeability, Resistivity, Metal Factor
Pseudosection, L200 S, Scale 1: 2500
Dipole-Dipole with 'a'spacing of 50 metersPlate 10: Chargeability, Resistivity, Metal Factor
Pseudosection, L400 E, Scale 1: 2500 Plate 11: Chargeability, Resistivity, Metal Factor
Pseudosection, LO N, Scale 1:2500 Plate 12: Chargeability, Resistivity, Metal Factor
Pseudosection, L200 N, Scale 1: 2500 Plate 13: Chargeability, Resistivity, Metal Factor
Pseudosection, L400 N, Scale 1:2500
Plan MapsPlate 14: Total Field Magnetic Contours, Scale l: 5000Plate 15: Total Field Magnetic Profiles with Postings, Scale l: 5000Plate 16: Filtered Apparent Chargeability and Resistivity Profiles
with Postings, Scale 1: 5000 Plate 17: Filtered Metal Factor Profiles with Postings, Scale l: 5000
JVX
1. INTRODUCTION
JVX Ltd. conducted Time-Domain Spectral Induced Polarization (IPyResistivity and Magnetometer surveys from Febuary 26 to March 7, 2002 on the Happy Face Property, Madoc Property Candor Ventures Corp. The east side of the property is adjacent to Hwy 62 from Madoc. The west side of the property is accesible from O'Hara road. The location map is shown hi Figure l and the grid/claim location map is shown hi Figure 2.
The purpose of these surveys was to map sulphide mineralization.
The Happy Face Property, covered by the present survey, includes the following claims:
1230910 1230911
"VTtwfoc*
' '"' HALIBURTON
\WSST...,\rmn Ym st l
l Like "SJ"" ( Mipta LM( A Sl.PTO ^^ l
J)*, H k/"" t Maynooth ' ^(Kr\^^
-**~*ZSQ^^t^\-*K-N - Mte S A^TTJ ^""
E*—/-. ^ Omp*^ \"sri '""••isaia^p^g^i
SURVEYAREA-
LOCATION MAP
CANDOR VENTURES CORPORATIONHAPPY FACE PROPERTY
MADOC PROJECTMadoc Twp., Eastern Ontario
NTS 31 C/12 GROUND GEOPHYSICAL SURVEY
Scale: l : 859,000
Survey by JVX Ltd. February-March 2002 Figure l
SOOT 400W 200W 200E 400E 600E 800E
H
H
H
0
h
H
H
100 2C
metres
H
h H
1230910
h H
h H
H 300
^
h f
—
— — — —
I-
- — — —
h
1230911
H
h 4-
—— l
4-
l
+ -
-N-
600W 400W 200W 200E 400E 800E 800E
JVXJVX LW., ref. 2-8. Maich2002
GRID 7 CLAIM MAP
CANDOR VENTURES CORPORATION
HAPPY FACE PROPERTYMADOC AREA, MADOC TWP., ONTARIO
NTS31Cfl2
GROUND GEOPHYSICAL SURVEY Figure 2
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2. SURVEY SPECIFICATIONS and PRODUCTION SUMMARY
EP/RESISTIVITY
Transmitter
Receiver
Transmit Cycle Time
Receive Cycle Time
Number of Potential Electrode Pairs
Electrode Spacing
Station Spacing
Number of Lines Surveyed
Survey Coverage
Scintrex IPC-7/2.5 kW
Scintrex IPR-12
2 sec
2 sec
6
25 m (50m on the second pass of 400E)
25 m (50m on the second pass of 400E)
7 lines, l base line,3 tie lines
10,725 m
Table l: Specifications for the IP/Resistivity Survey
Instrument-base station
Sensor Type
Instrument-rover
Sensor Type
Station Spacing
Number of Lines Surveyed
Survey Coverage
Scintrex Envimag
Proton Precession
GSM-19
Overhauser
12.5m
7 lines,! base line,3 tie lines
10.6125km
Table 2: Specifications for the Magnetometer Survey
JVX
Date
25-Feb
26-Feb27-Feb27-Feb28-Feb28-Feb1-Mar1-Mar2-Mar2-Mar3-Mar3-Mar
4-Mar
5-Mar6-Mar
7-Mar
Survey Type and Interval Line Type
Line From Station
To Station
Distance ) (m)
Alex Jelenic, Tim Charlebois and Robin Webster mobilize from JVX office
IP Dipole-Dipole (25m)IP Dipole-Dipole (25m)IP Dipole-Dipole (25m)IP Dipole-Dipole (25m)IP Dipole-Dipole (25m)IP Dipole-Dipole (25m)IP Dipole-Dipole (25m)IP Dipole-Dipole (25m)IP Dipole-Dipole (25m)IP Dipole-Dipole (25m)IP Dipole-Dipole (25m)Rain delay 1.5 hoursIP Dipole-Dipole (25m)IP Dipole-Dipole (25m)IP Dipole-Dipole (25m)
LineLineLineLineLineLineLineLineLineLineLine
LineLineTie
600E600E400E400E200E200EOEOE200W200W400W
400W600W200S
625NON650N125N650NSOON650N3 SON700N350N750N
150N725N700E
ON475S125N625S300N625S350N650S350N25S150N
25S508100E
625475525750350925300
1000350375600
175775600
Pick up IP wire. And Magnetometer SurveyIP Dipole-Dipole (50m)IP Dipole-Dipole (50m)IP Dipole-Dipole (50m)IP Dipole-Dipole (50m)IP Dipole-Dipole (50m)
TieTieBaseLineLine
400N200NON400E400E
750E750E700E508SOS
OEOEOE650N650N
Magnetometer Survey and demobilize to JVX Office. Total IP Coverage
750750700700
10.725km
Table 3: Daily Production Summary
; c •^••'^:, ii- ?.:,'U^ ^SSIP/RESISTJVITY^SHAPPY
^^Line;p
600W400W200W
OW200E400E400E600E200S
ON200N400NTotal
'^': :;: '';?:|*5iirye;y;^:fl.fSvfj r Configuration '1'
25 m dipoles25 m dipoles25 m dipoles25 m dipoles25 m dipoles25 m dipoles50 m dipoles25 m dipoles25 m dipoles50 m dipoles50 m dipoles50 m dipoles
•^lifprotti^^i- /'V--^^ '"w^- ' . f.*' v*(
^::iStati6nfcS725N750N700N650N650N650N508
625N700E700E750E750E
FACEl*ROPERTY^Aly"i,*.: ;;;.. ': v :: ' .-
fevSStafion^l50825825S650S62586258650N475S100E
OEOEOE
^Distance Jim^rn7757757251300127512757001100600700750750
10.725 km
SNO-'iOf:^'' Readings
Table 4: Production Summary for the IP/Resistivity Survey
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MAGNETICSLine
600W400W200W
OE200E400E600E
ON200N400N200STotal
From Station
ON25SON
612.5S600S
612.5S400S650S
ONON
125N
To Station725N725N
687.5N675N650N675N
612.5N700N725N
712.5N700N
Distance (m)725750
687.51287.51250
1287.51012.51350725
712.5825
10.6125 km
No. of Readings
58605610410110382109595847
837
Table 5: Production Summary for the Magnetometer Survey
VX
3. PERSONNEL
Alex Jelenic (Geophysicist)Mr. Jelenic operated the IP R-12 receiver and was responsible for field logistics and overall
data quality of the surveys conducted. Mr. Jelenic also prepared sections l through 6 of this report.operated the IPR-12 receiver for the duration of the survey. Mr.
Tim Charlebois (Geophysical Assistant)Mr. Charlebois assisted with the day-to-day field operations.
Robin Webster (Geophysical Assistant)Mr. Hume operated the IPC-7 transmitter and carried out the magnetometer survey.
Two field assistants were also engaged hi the IP Survey.
John Gilliatt (Senior Geophysicist)Mr. Gilliatt processed and plotted the data and prepared sections 7 and 8 of this report.
Dagmar Piska Se Vaso Lvmberis (Draftspersons):Ms. Piska and Ms. Lymberis drafted the figures/plates and assembled this report.
Slaine Webster (President):Mr. Webster provided overall supervision of the survey.
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4. FIELD INSTRUMENTATION
JVX supplied the geophysical instruments specified in Appendix A.
4.1 IP Transmitter
The Scintrex IPC-7/2.5 kW Time Domain Transmitter powered by an eight-horsepower motor generator was used. The transmitter generates square wave current output with a period of 2, 4, 8, or 16 seconds. Stabilization circuitry ensures that the output current is
automatically controlled to within tO.1% for up to SW/o external load or 10"Mi input voltage variations. Voltage, current and circuit resistance are presented on both analog and digital displays.
4.2 IP Receiver
The Scintrex IPR-12 Time Domain Receiver was used. This unit samples the voltage decay curve as measured by the potential electrodes at ten points in time. Readings are repeated until they converge to within a tolerance level, and the data are stored hi solid-state memory.
4.2.1 Dipole-Dipole Array
The dipole-dipole survey configuration was used. This array consisted of as many as 9 mobile electrodes: two current electrodes G i and 62 and as many as seven potential electrodes(Pi to P^ connected to the receiver by means of the "Snake"). The potential electrodes consisted of stainless steel rods. The spacing between the electrodes was maintained at 25 meters for all north-south lines as well as tieline 200S. Electrode spacing of 50 metres was used for the baseline, tielines 200N and 400N as well as line 400E.
.d
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43 Magnetometers
Magnetic data were collected at 12.5-m intervals along gridlines using the GEM SYSTEMS GSM-19 proton precession magnetometer..
A Scintrex ENVIMAG proton precession magnetometer was used as a base station. The base station was located in a quiet magnetic area at line 400W and 725N. The base station was employed to monitor the diurnal variations in the earth's magnetic field.
A base station malfunctioning occur while surveying the baselines and tielines on March 7th . Tie-points located on line 400E at 200N and line 600E at 400N were used to correct the raw data.
JVX
5. DATA PROCESSING
5.1 IP/Resistivity
After being transferred to a field computer at the end of each survey day, the data were examined, corrected, and organized by the instrument operator.
The data were sent by e-mailed to the head office of JVX in Richmond Hill, Ontario. They were processed and results were plotted on the following printers as was necessary:
. HEWLETT PACKARD DESIGNJET 750C 36 inch colour plotter * MINOLTA Laser printer
The processing procedure is outlined below:
1) JVX in-house software was used to spatially reference the tune-domain data. Spectral tau and M-IP were calculated - in addition to chargeability and apparent resistivity. The spectral parameters describe the shape of the IP decay curve, giving information about:
* the grain size (indicated by the parameter tau),* the magnitude of the chargeable source (indicated by M-IP),* the variability of grain size (indicated by c).
The spectral parameters were calculated internally in the IPR-12 and with JVX software. This software works on IPR-11 format data and it also varies the spectral value c, whereas the IPR-12 circuitry uses a fixed value for c. JVX's extensive experience with this process provides more reliable interpretative results. In-house software was used to convert the time slices from IPR-12 windows to IPR-11 windows. The MO slice was extrapolated based on the approximate straight-line character of the Log-Lin decay curve. This estimation proved satisfactory for our purposes, based on sensitivity analyses done on a test data sample.
2) The GEOSOFT IP software was used to generate colour and black and white pseudosections of the apparent resistivity, apparent chargeability and normalized chargeability ("Metal Factor") data at a scale of l :2500..
3) Profiles and Postings of the Filtered Apparent resistivity, Apparent Chargeability and Metal Factor were produced using the GEOSOFT MAPPING software at a scale of 1:5000.
4) The Compilation Map was produced in AutoCAD at a scale of l :5000.
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5.2 Magnetics
1) Plan map and Profiles and Postings Map of the magnetics data were generated using the GEOSOFT Mapping package at a scale of l :5000.
5 J Digital Data
Two (2) copies of the digital data has been provided with this report. A readme file has been included that provides details on the survey area and a description of the data. The data has been stored in separate zipped files for each of the seventeen (17) plates. All of the files are GEOSOFT format files with the exception of the Plate l zip file. This file contains an AUTOCAD (Ver. 14) plot of the compilation map. A copy of this report is also included.
6. INTERPRETATION METHODOLOGY
JVX uses its many years of experience hi geophysical interpretation to extract the most accurate information from the data. The procedures involved are simplified and outlined hi the following section.
6.1 IP /Resisitivity
The IP and resistivity data are interpreted using the following procedure:
1) Chargeability anomalies are picked on the pseudosections and classified using the following scheme as a guide:
Very Strong (? 30 mV/V) and well defined
Strong (20 to 30 mV/V) and well defined
Moderate (10 to 20 mV/V) and well defined
Weak (5 to 10 mV/V) and well defined
Very Weak (3 to 5 mV/V) and poorly defined
x x x x Extremely Weak ^3 mV/V) and very poorly defined
The peak of the anomaly provides a qualitative indication of the depth to the top of the anomalous source and the location of the centre of the body. Where possible, the
JVX __ _location and dipole number of the peak are written beside the anomaly bar.
2) Resistivity anomalies are picked on the pseudosections and classified using the following scheme as a guide:
no symbol VH(n) Very High (? 25 000 ohm m) highly silicified
no symbol H(n) High (^10 000 ohm m) probably silicified
no symbol WH(n) Weak High (^ 10 000 ohm m) relative increasecompared to surrounding material
SL(w) Strong Low — strong decrease in resistivity
ML(n) Medium Low — medium decrease in resistivity
WL(n) Weak Low — weak resistivity decrease relative to surrounding material, where n is the dipole number at which the anomaly peak is located.
3) The anomalies from steps 1) and 2) are marked on the compilation map.
4) Zones of high chargeability are interpreted base on resistivity and geometrical information. There are then correlated with any additional geophysical and/or geological data.
10
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7. DISCUSSION OF RESULTS
Results of the geophysical surveys have been plotted as described in the previous section and are included in Appendix B of this report. Anomalous geophysical zones and trends have been identified and transferred(North-South lines only) to a compilation map.
The IP/Resistivity survey has outlined a total of eight (8) anomalous zones. All of the IP zones occur in southeast or west sections of the grid. Conductive overburden (clay minerals in swamp) "masked" IP responses from the bedrock in the northeast section. The amplitude of the chargeable sources range from weak to very strong.
The Magnetic survey shows moderate to strong relief on the grid. There appears to be a general increase in magnetic values from the northeast to southwest. A chain of moderate magnetic highs is observed trending east-west near the northern boundary on lines 200W to 200E. Another chain of moderate magnetic highs occurs in close proximity to the baseline on lines 200W to 600E. It is possible that these magnetic highs represent a folded unit with a northwest-southeast trending fold axis. A larger survey area would be needed to properly evaluate this possibility. The highest magnetic values occur near the south end of lines O to 400E as well as the south end of lines 600W to 400W.
A brief discussion of the IP zones is provided below.
IP-1 - IP-1 represents a very strong chargeable source near the north end of line 600 W. It is associated with a weak resistivity low and flat magnetics.
IP-2 - This zone occurs on line 200W and represents a moderate chargeability feature. The zone exhibits a strong correlation with a weak resistivity low. In addition, the zone is associated with low magnetic values on the south edge of moderate magnetic trend. The zone could represent the eastern extension of IP-1.
IP-3 - This is a one-line, moderate chargeability anomaly centred at 400N on line 600W. A very strong resistivity high appears to be positioned on the north edge of the zone. The top of the chargeability zone and resistivity high do not appear to outcrop. The chargeability zone correlates with a weak magnetic high.
IP-4 - IP-4 is a four-line anomalous zone extending from the west boundary on line 600E to line 0. The zone consists of weak to moderate chargeable sources with the highest chargeability values occurring on line 400 W. On this line, the zone is generally associated with high to very high resistivities. A weak, narrow resistivity low coincides
J V Xwith the northern chargeability source located at 250N. On lines 400W and 600W the zone is coincident with high magnetics.
IP-5 - This zone is located on lines O and 200E and consists of weak chargeable sources that are coincident with high to very high resistivities. The zone is associated with moderate magnetic values.
IP-6 - IP-6 is is a broad, two-line zone that appears to trend west-southwest/east- northeast. Chargeability sources are weak to moderate and associated with high to very high resistivities.. The zone is associated with moderate to strong magnetics.
IP-7 - This zone is located on lines 400E and 600E south of IP-6. On line 600E the chargeable source is near surface and moderate. On line 400E the chargeable source is weak and located on the south flank of a broad resistivity high. The zone coincides with generally moderate magnetic values.
IP-8 - This zone is located near the southern edge of the grid on lines O to 400E. The zone is broad on lines O and 200E, consisting of two to three chargeable sources. On line 400E, the zone consists of a poorly defined weak source. On lines O and 200E the northernmost sources are associated with resistivity highs. The zone coincides with moderate to high magnetics. The highest magnetic values occur on line O coinciding with the strongest chargeabilities.
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8. SUMMARY AND RECOMMENDATIONS
Several chargeability zones have been outlined by the IP/Resistivity surveys. The strongest chargeability zones occur in zones IP-1 to IP-4 hi the the western section of the grid. These zones would have the potential for hosting sulphide mineralization and should be considered the highest priority for ground follow-up. Bedrock IP responses could not be obtained below a broad swamp in the northeastern section of the property. Numerous magnetic highs are observed on the grid. Magnetic values are highest along the south and west boundaries of the grid. In addition, a folded unit could occur in the northern section of the property as indicated by moderate magnetic highs in this region.
If there are questions with regards to the surveys or this report please call the undersigned.
Respectfully submitted,
JVX Ltd.
John Gilliatt Senior Geophysicist
fSlaine WebsterPresident
13
APPENDIX A
and Com mutated DC Resistivity Transmitter System
FAN EXHAUST START CROUIMD Tirv/lER i Of
Function
3"he IPC-7/2.5 kW is a medium power transmitter system designed for time do main induced polarization or commutated DC resistivity work. It is the standard power transmitting system used on most surveys under a wide variety of geophysical, topographical and climatic conditions.
The system consists of three modules: A Transmitter Console containing a transformer and electronics, a Motor Generator and a Dummy Load mounted in the Transmitter Console cover. The purpose of the Dummy Load is to accept the Motor Generator output during those parts of the cycle when current is not transmitted into the ground, in order to improve power out put and prolong engine life.
The favourable power-weight ratio and com pact design of this system make it portable and highly versatile for use with a wide variety of electrode arrays.
Features
Maximum motor generator output, 2.5 kW; maximum power output, 1.85 kW; maximum current output, 10 amperes; maximum voltage output, 1210 volts DC.
Removable circuit boards for ease in servic ing.
Automatic on-off and polarity cycling with selectable cycling rates so that the op timum pulse time (frequency) can be selected for each survey.
The overload protection circuit protects the instrument from damage m case of an overload or short in the current dipole cir cuit.
The open loop circuit protects workers by automatically cutting off the high voltage in case of a break in the current dipole circuit.
Both the primary and secondary of the transformer are switch selectable for power matching to the ground load. This ensures maximum power efficiency.
The built-in ohmmeter is used for checking the external circuit resistance to ensure that the current dipole circuit is grounded properly before the high voltage is turned on. This is a safety feature and also allows the operator to select the proper output voltage required to give an adequate current for a proper signal at the receiver.
The programmer is crystal controlled for the very high stability required for broadband (spectral) induced polarization measurements using the Scintrex IPR-11 Broadband Time Domain Receiver.
Technical Description of IPC-7/2.5 kW Transmitter System
Complete 2 5kW induced polarization system including motor-generator, reels with wire, tool kit porous pols. simulator circuit, copper sulphate IPR-8 receiver dummy toad, transmitter, electrodes and clips
IPC-7/2.5kW transmitter console with lid and dummy load
\ T T
T T T T
Time Domain Wavetorm
Transmitter Console
Maximum Output Power
Output Current
Output Voltage
Automatic Cycle Timing
Automatic Polarity Change
Pulse Durations
Voltage Meter
Current Meter
Period Time Stability
Operating Temperature Range
Overload Protection
Open Loop Protection
Undervoltage Protection
Dimensions
Weight
Shipping Weight
1.85 kW maximum, defined as VI when cur rent is on, into a resistive load
10 amperes maximum
Switch selectable up to 1210 volts DC
T:T:T:T; on:off:on:off
Each 2T
Standard: T zz 2,4 or 8 seconds, switchselectableOptional: T z; 1,2,4 or 8 seconds, switchselectableOptional: T z; 8.16,32 or 64 seconds, switchselectable
1500 volts full scale logarithmic
Standard: 10.0 A full scale logarithmic Optional: 0.3, 1.0. 3.0 or 10.0 A full scale linear, switch selectable
Crystal controlled to better than .01 "/o
-30 0 C to *55"C
Automatic shut-off at output current above 10.0 A
Automatic shut-off at current below 100 mA
Automatic shut-off at output voltage less than 95V
280 mm x 460 mm x 310 mm
30 kg
41 kg includes reusable wooden crate
Motor Generator
Maximum Output Power
Output Voltage
Output Frequency
Motor
Weight
Shipping Weight
2.5 kVA, single phase
110 VAC
400 Hz
4 stroke, 8 HP Briggs ^ Stratton
59 kg
90 kg includes reusable wooden crate
222 Snidercroft Road Concord Ontario Canada L4K 1B5
Telephone: (416) 669-2280 Cable: Geoscint Toronto Telex: 06-964570
Geophysical and Geochemical Instrumentation and Services
l PR-12 Time Domain Induced Polarization/Resistivity Receiver
Specifications
Inputs1 to 8 dipoles are measured simultaneously.
Input Impedance16 Megohms
SP Bucking±10 voll range. Automatic linear correction operating on a cycle by cycle basis.
Input Voltage (Vp) Range50 uvolt to 14 volt
Chargeability (M) RangeO to SOOmillivolt
Tau Range1 millisecond to 1000 seconds
Reading Resolution of Vp, SP and MVp, 10 microvolt; SP, 1 millivolt; M, 0.01 millivolt/volt
Absolute Accuracy of Vp, SP and MBetter than 1 070
Common Mode RejectionAt input more than 100db
Vp Integration Time10070 to 800Xo of the current on time.
IP Transient ProgramTotal measuring time keyboard selectable at 1, 2, 4, 8, 16 or 32 seconds. Normally 14 windows except that the first four are not measured on the 1 second timing, the first three are not measured on the 2 sec ond timing and the first is not measured on the 4 second timing. (See diagram on page 2.) An additional transient slice of minimum 10 ms width, and 10ms steps, with delay of at least 40 ms is keyboard selectable.
Transmitter TimingEqual on and off times with polarity change each half cycle. On/off times of 1, 2, 4, 8, 16 or 32 seconds. Timing accuracy of ±100 ppm or better is required.
External Circuit TestAll dipoles are measured individually in sequence, using a 10 Hz square wave. The range is O to 2 Mohm with O.lkohm resolution. Circuit resistances are dis played and recorded.
SynchronizationSelf synchronization on the signal received at a keyboard selectable dipole. Limited to avoid mistriggering.
FilteringRF filter, 10 Hz 6 pole low pass filter, sta tistical noise spike removal.
Internal Test Generator1200 mV of SP; 807 mV of Vp and 30.28mV/V of M.
Analog MeterFor monitoring input signals; switchable toany dipole via keyboard.
Keyboard17 key keypad with direct one key access to the most frequently used functions.
Display16 lines by 42 characters, 128 x 256 dots, Backlit Liquid Crystal Display. Displays instrument status and data during and after reading. Alphanumeric and graphic dis plays.
Display HeaterAvailable for below -15'C operation.
Memory CapacityStores approximately 400 dipoles of infor mation when 8 dipoles are measured simultaneously.
Real Time ClockData is recorded with year, month, day,hour, minute and second.
Digital Data OutputFormatted serial data output for printer and PC etc. Data output in 7 or 8 bit ASCII, one start, one stop bit, no parity format. Baud rate is keyboard selectable for stan dard rates between 300 baud and 51.6 kBaud. Selectable carriage return delay to accommodate slow peripherals. Hand shaking is done by X-on/X-off.
Standard Rechargeable Batteries Eight rechargeable Ni-Cad D cells. Supplied with a charger, suitable for 110/230V, 50 to 60 Hz, 10W. More than 20 hours service at *25"C, more than 8 hours at -30'C.
Ancillary Rechargeable BatteriesAn additional eight rechargeable Ni-Cad D cells may be installed in the console along with the Standard Rechargeable Batteries. Used to power the Display Heater or as back up power. Supplied with a second charger. More than 6 hours service at-30'C.
Use of Non-Rechargeable Batteries Can be powered by D size Alkaline batter ies, but rechargeable batteries are recom mended for longer life and lower cost over time.
Operating Temperature Range-30'C to H-50'C
Storage Temperature Range-30'C to *50'C
DimensionsConsole: 355 x 270 x 165 mm Charger: 120 x 95 x 55mm
WeightsConsole: 5.8 kgStandard or Ancillary RechargeableBatteries: 1.3 kgCharger: 1.1 kg
Transmitters available IPC-9 200 W TSQ-2E 750 W TSQ-3 3 kW TSQ-4 10kW
In Canada
222 Snidercroft Rd. Concord, Ontario Canada, L4K1B5
In the U.S.A.
85 River Rock Drive Unit f 202 Buffalo, N.Y. U.S.A. 14207
l PR-12/94
Tel.: (905) 669-2280 Fax: (905) 669-6403 Telex: (905) 06-964570
Tel.: Fax:
(716)298-1219 (716)298-1317
ENVI GEOPHYSICAL^SIEM,Total Field Operating Range20,000 to 100,000 nT (gammas)
Total Field Absolute Accuracy: 1 nT
Sensitivity:0. l nT al 2 second sampling rate
TuningFully solid state. Manual or automatic keyboard selectable
Cycling (Reading) Rates0.5, l or 2 second sensor, 172m (20 inch) staff extender and processor module
Gradiometer OptionIncludes a second sensor, !X2m (20 inch) staff extender and processor module
VLF OptionIncludes a VLF sensor and harness assembly
'WALKMAG' Mode0.5 seconds for walking surveys, variable rates for hilly terrain
Digital DisplayLCD 'Super Twist', 240 x 64 dots graphics, 8 line x 40 characters alphanumerics
Display HeaterThermostatically controlled, for cold weather operations
Keyboard Input17 keys, dual function, membrane type
Notebook Function32 characters, 5 user-defined MACRO'S for quick entry
Standard MemoryTotal Field Measurements: 28,000 readings Gradiometer Measurements: 21,000 readings Base Station Measurements: 151,000 readings VLF Measurements: 4,500 readings for 3 frequencies
Expanded MemoryTotal Field Measurements: 140,000 readings
Gradiometer Measurements: 109,000 readings Base Station Measurements: 750,000 readings VLF Measurements: 24,000 readings for 3 frequencies
Real-Time ClockRecords full date, hours, minutes and seconds with l second
resolution, ± l second stability over 24 hours
Digital Data OutputRS-232C interface, 600 lo 57,600 Baud, 7 or 8 data bits, l start,
l stop bit, no parity format. Selectable carriage return delay (0-999 ms) to accommodate slow peripherals. Handshaking is done by X-on/X-off. High speed Binary Dump
Analog Output0-999 mV full scale output voltage with keyboard selectable range of
l, 10, 100, 1000 or 10,000 full scale
Power SupplyRechargeable 'Camcorder' type, 2.3 Ali, Lead-acid battery 12 Volts al 0.65 Amp for magnetometer, 1.2 Amp for gradiometer External 12 Volt input for base station operations Optional external battery pouch for cold weather operations
Battery Charger110 Volt-230 Voll, 50/60 Hz
Operating Temperature RangeStandard: -40' to 60"C
Dimensions 8t WeightConsole: 250mm x 152mm x 55mm
10" x 6" x 2.25" 2.45 kg (5.4 Ibs) with rechargeable battery
T.F. sensor: 70mm x 175mm2.75"d x 7"l kg (2.2 Ibs) (sensor)
Gradiometer sensor and staff extender 70mm x 675mm
2.75"dx26.5"1.15 kg (2.5 Ibs) (sensor)
T.F. staff: 25mm x 2ml"d x 76".8 kg (1.75 Ibs)
VLF sensor Head: l40mm x 130mm5.5"dx5.1"-9kg (2 Ibs)
VLF Electronics Module: 280mm x 190mm x 75mm
H" x 7.5" x 3"
1.7kg (3.7 Ibs)
SCIMTREXHead Office222 Snidercroft Road, Concord, Ontario, Canada L4K l B5Tel.: (905) 669-2280 - Fax: (905) 669-6403 - Telex: 06-964570
In the U.S.A.525 Fort Worth Drive, Suite 216, Denton, Texas U.S.A. 76201
Tel.: (817) 591-7755 * Fax:(817)591-1968In Australia1031 Wellington St., West Perth, West Auslralia 6005
Tel.: (619) 321-6934 - Fax: (619) 481-1201
MAGNETOMETERS
GSM-19 PROTON MAGNETOMETER/VLFProton MagnetometerA/LF System
Features:* Omnidirectional Magnetometer with VLF.* Remote control for observatory and air
borne base station applications.* Streamlined grid coordinate system with
"end of line" quick change capability.* 128kb basic memory, expandable to 2MB.* Programmable RS-232 high-speed data
transfer to 19.2kb.* 50 and 60Hz filter, user selectable.* Automatic tuning and base station syn
chronization.
GeneralThe GSM-19 is a state-of-the-art magnetometer/VLF system that delivers quality data and the extensive capabilities required to perform a broad spectrum of applications. Whether the application calls for detailed ground surveys, or remotely controlled magnetic observatory measurements, you can count on the GSM-19 system to meet your goals.
The proton magnetometer can be equipped with gradiometer or VLF options, and is upgradable to an Overhauser Magnetometer.
Simultaneous GradiometerMany mining, environmental, and archaeological applications call for high-sensitivity gradiometer surveys. The GSM-19 meets these needs in several ways. For example, simultaneous measurement of the magnetic field at both sensors eliminates diurnal magnetic effects.
"Walking" Magnetometer/GradiometerThe "Walking" option enables acquisition of nearly continuous data on survey lines. Data is recorded at discrete time intervals (up to 2 readings-per-second) as the instrument travels along the line.
Omnidirectional VLFWith the omnidirectional VLF option, up to three stations of VLF data can be acquired without orienting. Moreover, the operator can record both magnetic and VLF data with a single stroke on the keypad.
Remote Control OperationWhen used during observatory, marine, and airborne base station applications, this option allows users to set parameters and initiate measurements from a computer terminal using standard RS-232 commands. A real-time transmission capability is provided to allow data quality monitoring while marine or vehicle borne surveys are in progress.
Automatic TuningTuning is automatic in all modes of operation with initial preset. An override option is also provided for manual arid remote modes. Tuning steps are 1,000 gammas wide.
Adaptability to High GradientsIn standard instruments, a gradient in the magnetic field across the sensor volume can shorten the decay time of the proton precession signal. However, the GSM-19 monitors the signal decay, and calculates the optimal time interval for measurement. Warning messages appear on the display when the measuring interval becomes too short.
GSM-19Proton MagnetometerA/LF System
BHBHBMBBBHEHBBHH JHtmLaliBiBBmglHmaimBIII^
___Specifications^^^
PerformanceResolution: O.OlnT
Relative Sensitivity: 0.2nT
Absolute Accuracy: InT
Range: 20,000 to 120,OOOnT
Gradient Tblerance: Over T.OOOnT/m
Operating Temperature: -400C to +60 C
Operating ModesManual: Coordinates, time, date and reading stored automatically at min. 3 second interval.
Base Station: Time, date and reading stored at 3 to 60 second intervals.
Mobile: Time, date and reading stored at coordinates of fiducial.
Remote Control: Optional remote control using RS-232 interface.
Input/Output: RS-232 or analog (optional) output using 6-pin weatherproof connector.
Storage CapacityManual Operation: 8,000 readings standard. 131,000 optional.
Base Station: 43,000 readings standard, 700,000 optional.
Gradiometer: 6,800 readings standard, 110,000 optional.
Dimensions and WeightsDimensions: Console: 223 x 69 x 240mm. Sensor: 170 x 71mm diameter cylinder.
Weight: Console: 2.1kg. Sensor and Staff Assembly: 2.2kg
Standard ComponentsGSM-19 console, batteries, harness, charger, case, sensor with cable, connector, staff, and instruction manual.
Ordering InformationDescription Order NumberGSM-19 Proton Mag . .. . . . . 350-170-0039Gradiometer Option ... .... 350-170-0042VLF Option. . . .. . . . .. . . . . . 350-170-0069Memory Upgrade, 128kb . ,. 350-170-0063Analog Output.. . . ..... . . . 350-170-0040Remote Option . . . . . ... . . . 350-170-0043
85 Product Catalog, Vol. 4, Number 1 Terraplus: Sales, Rentals, Training, and Repair Service
APPENDIX B
ONTMUO MINISTRY OF NORTHERN DEVELOPMENT AND MINES
Transaction No:
Recording Date:
Approval Date:
Client(s):
400236
Survey Type(s):
W0290.00533
2002-APR-18
2002-MAY-08
Work Report Summary
Status: APPROVED
Work Done from: 2002-FEB-12
to: 2002-MAR-07
CANDOR VENTURES CORP.
IP LC MAG
Work Report Details:
Claim*
SO 1230910
SO 1230911
External Credits:
Reserve:
Perform Perform Approve
36,478 36,478
314,527 314,527
321,005 321,005
SO
Applied Applied Approve
31,200 31,200
52,400 52,400
53,600 53,600
Assign
50SO
so
Assign Approve Reserve
0 35,278
0 512,127
SO 517,405
Reserve Approve Due Date
35,278 2003-NOV-05
512,127 2003-NOV-05
517,405
31 7,405 Reserve of Work Report*: W0290.00533
317,405 Total Remaining
Status of claim is based on information currently on record.
31C11SW2007 2.23257 MADOC 900
2002-Jun-18 11:43 Armstrong-d Page 1 of 1
Ministry ofNorthern Developmentand Mines
Date:2002-JUN-12
Ministere duDeveloppement du Nord et des Mines Ontario
GEOSCIENCE ASSESSMENT OFFICE 933 RAMSEY LAKE ROAD, 6th FLOOR SUDBURY, ONTARIO P3E 6B5
CANDOR VENTURES CORP. 306-2 TORONTO ST., TORONTO, ONTARIO M5C 2B6 CANADA
Tel: (888) 415-9845 Fax:(877)670-1555
Dear Sir or Madam
Submission Number: 2.23257 Transaction Number(s): W0290.00533
Subject: Approval of Assessment Work
We have approved your Assessment Work Submission with the above noted Transaction Number(s). The attached Work Report Summary indicates the results of the approval.
At the discretion of the Ministry, the assessment work performed on the mining lands noted in this work report may be subject to inspection and/or investigation at any time.
If you have any question regarding this correspondence, please contact STEVEN BENETEAU by email at [email protected] or by phone at (705) 670-5855.
Yours Sincerely,
Ron GashinskiSenior Manager, Mining Lands Section
Cc: Resident Geologist
Paul Emile Chamois (Agent)
Assessment File Library
Candor Ventures Corp. (Claim Holder)
Candor Ventures Corp. (Assessment Office)
Visit our website at http://www.gov.on.ca/MNDM/LANDS/mlsmnpge.htm Page: 1 Correspondence 10:17009
Oo
M O O
MINING LAND TENURE
MAP
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1 Moderate
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200E 400E 600E BOOKPLATE 1
CANDOR VENTURES CORPORATIONHAPPY FACE PROPERTY
MADOC AREA, MADOC TWP. .ONTARIONTS 31 C/12
COMPILATION MAPJVXw w,*w
JVX Ltd., ref. 2 - 8, March 2002
Metal Factor(mhos/m)
1+00 N 1+50 N 2+00 N 2+50 N 3+00 N 3+50 N 4+00 N 4+50 N 5+00 N 5+50 N———l————i————h-
6+00 N 6+50 N
0.080 0.43 0.14 0.14 0.090 0.17 0.24 -0.0100 0.39 0.040 0.53 _ _ 0,71 0.34 0.090 0.080 O.OM 0.11 ^2.7
0.020 0.53 0.17 0.070 0.060 Q.20 0.29 0.090 0.10 0.080 0.57 l 0.37 0.23 0.030 -0.030 O.OM 0.01mI l 2 H -
. 3.7 - 6.6 ^
— a—-^ i.i 0.31 0.15
11=1
0-2
0=3 -0.020 0.020 0.030 0.10 0,040 0.070 0.49 0.490 0.15 0.020 ' 0.94 -^. 0.61 0.15 0.030 -O.D30 -0.070 O.OM 0,44 H 2.8 —- 1.9 ^~ 0.93 r 0.45 - 0.66 l 0.17__ l
11=4 -0.060 0.0100 -0.030 0.060 0.070 0.050 0.30 0.21 0.20 0.040 0.20 \\JJ2j ] 0.23 0.020 0.030 -0.090 -0.14 O.M "--- 1.5 0;92 ". . ^ 0.87 0.74 0.030 0.080
0=5 O 0.11 0.090 O.OSO O.OBD 0.11 0,070 0.37 O.OM 0.37 0.36 ^ J.58 0.040 0.020 0.050 -0.22 0.53 ^XTT\ O.Bo' .. 0.53 \ 0.89 .' ,0.37 0.39
0=6 0.20 O.OHO 0.040 0.04J) 0.1J 0.0(0 O.OSO 0.090 0.44 0.60 0.13 0.10 0.040 0.040 0.11 -0.030 /S.8 ' 3.8^ 0.46 0.63 0.47 0.10
Apparent Chargeability (mV/V, 690ma-1050ms)
0=1
11=2 11=3 11=4 11=5 11=6
1+00 N 1+50 N
—— I P - 42+00 N 2+50 N 3+00 N 3+50 N
IP - 34+00 N 4+50 N 5+00 M
I P - l
5+50 NT^T •n^T T^T •n^T 0=2
6+00 N 6+50 N————i——i——i——i——i-
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t Kl^. 10 14 li f^4.1 ; 1.1 iii -0.50 f/// 4.2 ^-v, 5.6
\ J / \ ^21 ' 9.4 '15 IR x 12 14 II 14
, 3.1 -—— 3.5
t.3 i L6
4.0 2.8
-0.53 ^ ' 29 " 58 12 ^ 17
Apparent Resistivity (ohm—m)
1+00 N 1+50 N 2+00 N 3+Sfl N 3+00 N 3+50 N 4+00 N 4+50 N 5+00 N 5+50 N 6+00 N 6+50 N11(2) vir(3)
Metal Factor (mhos/in)
11=1
0=2
11=3
11=4
11=5 11=6
Apparent Chargeability (mV/V, ti90ms-1050rae)
11=1 11=2 0=3 0=4
11=5 11=6
Apparent Resistivity(ohm-m)
11=1 11=2 0=3 0=4 0=5 0=6
250? — 1407 , 7884 s 1578 1216 784- 2291 -- 3032 - 6366 2986 , 877 338 338-^235
6622
WL , 2835 3348^^. 4253 ^ 1404 - 45BD^X 20-.. ... ^
3191 -^ I34S 431! 7Be9^--Mm^N; 2443 — 2125 ,- ^451 7012 — 6431 ^-1522 j 2728 — 4724 ^ 5035 4302 4253 ' 8710 \ 2310 (( Ull ^ ̂ 768 ——- (02, 358' ( 1366 1110_rxNsJ i ( i/ x\YAr-\u x^^\\\\fr \( yx^^^^N \ -— i \\\\^---^^~~^\\^ '9672 --7738 2591 ^ 6178 ( 141———15X"))) 1M \\ 4011 717S Y 26K)l) UtS 1879 , 7910 ^ 35X -O- 7712 4161 4053 — 4891 j 1104 — 1253 — 1466 \ 686 ——— 732 \ 1542\\ //////crJ) \ s//// y/Jf/ifi, ^.\/////// X^N f—- -^
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1764'" 7086 9541 * 19K ' 7694 - UK ' JTI^^ IIK"^ 3387 3682 •'"" -—"* \ ™ TW l S!W v\ 1U* - ut 1fJ3 V
Line 600 WDipole-Dipole Array
a s 25.0 M o n
plot point
Resistivity and Chargeability Anomalies
- Very strong
-Strong
- MediumSJo
xxxx xxxx
Weak
•Very weak
•Extremely weak
25Scale 1:2500
25 50 75 100 125 150
(meters)
Plate 2
CANDOR VENTURES CORPORATIONINDUCED POLARIZATION SURVEY
HAPPY FACE PROPERTY MADOC AREA. MADOC TWP.. NTS 31 C/12
Date: 02/03/15 Scintrex IPR-12 Rx(2 sec), IPC-7 Tx(2 sec)
JVX Ltd., re/. 2-3, March 2002
Metal Factor (mhog/m)
1+00 N 1+50 N 2+00 N 2+50 N 3+00 N 3+50 N 4+00 N 4+50 5+00 N 5+50 N 6+00 N 6+50 N 7+00 N Metal Factor (mhoa/m)
11=2
11=3
n=4
n=5 O 0.10 -0.19 0.23
11=6 0.0100 0.060 -0.050 0.57 D. l B
0.020 0.16 0.14 0.080 0.13 -^ 1.1 ^ 0.1(1 0.020 O.OSO 0.060 0.14 0.39 0.28 \\ 3.1 -^. 1.4 --— 1.4 * ,- 0.41 0.51 0.28 0.39 0.26 O.K 0.28 0.34 11=1W — A^ ;'AVU M ///(r-^m ;0.030 0.070 D.1B O.flflO 0.090 (( V4 j), 0.11 0.060 0.020 0.070 0.030 0.14 0.26 f^ 1.5 — : 0.59 AlV 12 2-* 0.57 O.S6 0.29 0.13 0.18 0.09* 0.12 0.20 [1=2^^^ f y Js -^jjfej^a*-- v i
-0.070 0.11 0.14 0.24 0.16 0.1B ~ 0.22 0.050 0.040 0.080 0.040 0.030 0.19 '( 1.6 J.3S ^"^ -42 0.81 0.24 0.17 0.070 0.080 -0.030 0.10 11=3- ^
0.20 0,23 0.05D 0.14 0.11 0.10 0.050 0.050 0.22 0.080 -0.0100 0.080 0.51 - 0.23 -18 -37 -0.82 - 0.70 - 0.20 0.070 0.030 0.080 O
0.15 0.080 0.040 0.22 0.20 0.17 0.070 0.11 0.12 -0.17 -2.8 -2.1 -0.09o' '\ f7i[ ^ 0.10 0.040 O.fllOO 0.080
0.18 0.020 0,020 0.19 0.31 0.47 0.36 -0.53 0.060 0.080 -0.050 - ^ i.l - -0.51 -0.12 " ' 0.19 0.070 0.12 0.020
11=4
11=5 a=6
Apparent Chargeability (mV/V, 690ms 1050ms)
11=1
11=2
11=3 11=4
11=5 11=6
Apparent Resistivity
11=1
11=2
11=4
1+00 N 1+50 N
/P - 42+00 N 3+50 N 3+00 N 3+50 H 4+00 N 4+50 N———L — -L 5+00 N 5+50 N
^T6+00 N 6+50 N | 7+roN Apparent Chargeability
(mV/V, 69[)ras-1050ms)1.9 v v^Jl ,— 13 14
-0.94 /i 9.6 *C 7.4 ) 15 -~.
16 __ 17 y 12 10 .
( 23 3 17 V. 13 2.5 II.'' J 9.6 "CTjy 15 \__14 t 23 J 17 V. 13 11 \ \ 2.3 ___ 2.6
-2.3*5^/7.3 ( 13 96 17 17 ^.. 15 19 14 .8.9 \\ 1.2.-^ 1.S -\ 2.3 X" 5.1 ——' \3T -20 T 4.1 " 2.1 — 1.5 ^- 2.2 2.1 J J, -0.13 0.40
l ^ 1.8 3.6 , 1.8 -2* -39 -2.L ^ 4.3 V^ 1-4'
li -^ l/ \ B.o o.r X N\72 ^S 1.8 \ 3.2 O -1.4 -12 -7.4 -0.38^X3.7X \ v \\\4 "4\ i ")i15 12 x 17 - 9.9 7.7 "* -2.6 ^ 2.5 4 ' m' -0.74
1.8^; 0.34 0.0100
3^ [2.7 I/O'OM 0.49
-2.S 0.73^- 2.1 ' 3.1 - 1.4'^ 0.23
2.6 n=l n=2
n=3
11=4
n.-5 n~G
I+OON I+SON 2+00 N 2+50 N __ ^ 3+00 N 3+50 N 4+00 NVH(1)
4+50 N-i- 5+00 N 5+50 N 6+00 N 6+50 N 7+00 N —h--—.n=l n-2
8531 25M */ 451 i 117 194—-. 124 N 297 - 698 4DO 489 283— 744- 1199 819 718 11=1
Apparent Resistivity(ohm-m)
x 5M -^211!.,^- B531 258! t, 451 ii l A \VvVr~\_c~^,\\Wi ) \ v27K L ME l j 3387 \ 8994 ) 1794 -4 ""' -^y/c ^ i v^
aiK -'^- 1IKC-- 3428 4834 l 1247
J
880 3290 ~~ 2750 l L 399 388
2934 X I3K . -,, J "\^~J \
3398 4142 "~- B9?8 ^^.^
8233 ^ 3893 f 2769 A 15K ^). 9073 IS* T3K i^ ZBI 41K l /."MM ^ 9671 i "l 1735 ^ 2800 ) )" 704 ^^ 7B3
17S ^ 8799 \ 2960 ' 3B46 ^^A\V UK 151 .
301 201^ 6516 2966 3450^^1855 ~ 7153 ^ 63K 681 ^ ' 8283 5453 2133" 2191 ^' 483 " 5013 4716 ~" 1438" ' 634 546 608 10M ' 4617 1191 1014
1124 11=2 11=3
11=4
11=5 11=6
Line 400 WDipole-Dipole Array
a = 25.0 Moo
plot point
Resistivity and Chargeability Anomalies
.ii..^.i,11 .........-Very strong
- Strong
Medium toLO O
25
• - - Weak
•-- Very weak
• -••Extremely weak
Scale 1:2500O 25 50 75 100 125 150
—i a(meters)
Plate 3
CANDOR VENTURES CORPORATIONINDUCED POLARIZATION SURVEY
HAPPY FACE PROPERTY MADOC AREA. MADOC TWP.. NTS 31 C/12
Date: 02/03/15 Scintrex IPR-12 Rx(2 sec), IPC-7 Tx(2 see)JVXLtd., re/. 2-8, March 2002
Metal Factor (mhos/m)
1+00 N 1+90 N 3+00 N 2+50 N 3+50 N 4+00 N 4+50 N-i————i——i——i————t——p——i——i——P——i- 5+00 N 5+50 N e-KJON 8+50 N
0.0(0 0.22 0.21 0.14 0.19 0.1B 0.22 0.12 0.13 O.OSC O.OM 0,10 0.10 0.17 0.1* 0.13 t ^ 1.1 i 0.2fi 0.10 0.3B O.flfiO 0.020 0=1
Metal Factor (mhos/m.)
\11=1
n-2 O.OM 0.16 0.15 0.12 D.ll 0.13 Oi3 0.14 0.17 O.I S 0.060 0.040 0.18 0.12 0.10 0.15 0.47 , OJ3 , 0.080 O.OSO 0^4 0.020
0=3 0.30 0.040 O.I! 0.12 0.13 0.060 0.17 0.17 0.14 0.24 0.11 0.060 0,090 0.11 0.10 9.040 0.41^ IU2~ " 0.10 0.050 0.090 0.030
11=4 0.25 O.OM O.MO 0.15 0.16 0.13 0,10 0.13 0.21 0.12 D.15 0.12 0.15 -0.0100 -0.32 0.060 0.21 ' 0.56 OJBO 0.030 O.OM 0.090
11=5 0.15 0.12 0.060 0.030 0.18 O.JB 0.21 O.OM 0.14 -0.0100 0.030 0.15 0.24 -0.77 -0.72 0.070 0.20 0.20 0.10 0.020 -0.12 0.050
11=6 -0*5 0.070 0.10 0.060 0.030 0.14 0.29 (1.12 0.070 O.K -&X 0.040 O.M -1.2 0.040 O.S7 0.33 0.050 0.080 -0.10 0.0100
11=2
11=3
u-4
11=5
11=6
Apparent Charge ability (mV/V, 690ms-1050ms)
1+00 N 1+50 N
IP-42+00 N 2+50 N StOON Jf 50 N 4+00 N 4+50N"5=3" H———*~——t-
IP-25+00 N 5+50 N 6+00 H 6+50 N Apparent Chargeability
(mV/V. 690ma- 1050ms)
n=^
11=3 11=4 11=5 11=6
^ 7.4 -. 3.74.1 5.7
5 \
3 2.56 6.4 5.5 5.1 3.8 4Jx3.3 s M M 5.5 , 4.9 4.2
4.7 f^~. 1.6 14 8.3 J 5.2 ^-2.7
-0.17 -3.2 H S.Z, - , -5.4 l J 0.81
-8.4 -W 4.1 ^ 6.8 / 3.3 4.33.0 4.9 10 x 6.9 6.7 62 S.( -^ 4.8 4.2 f -0.14 1.3
4,1 ' 5.3 6.6 3.4 4.4-4.7 ixx 5.3
0=2 0=3 0=4 0=5 0=6
Apparent Resistivity (ohm-m)
1+00 K 1+50 N 2+00 N 2450 N 3+00 N J+50N i+flO N
H(3)11=1
4+50 NH————-————h-
&+OONt, . ,'
5+50 N 6+00 N 6+50 N'n^T H(i7 VH(1)
Apparent Resistivity(ohm-m)
11=1
11=2
11=3
11=4
11=5
11=6
3224
1124^ 2537 3043 -^ 2389 1899 , 3(30 42*2s* S S S^ -^ \ ^—^ \ tiff'
1453 2456 5904 4415 \ 2120 2*30 — 3015 — HW l 1ZI C 1BE
\709v ,2H2 ; 4)05 "7889 ^3259 — 3004 2275 ZOU 7330 X^l-J^* '5724 J 'l4*2"^~3aB
4262 -- 528J v 3833 ( 2028 ~ 2111 X 40*0 7M7 4111 — 2504 ^M)' 7 "*502
2525 —
492 ' 7324 60K
3531 26K
3701 x 1846 2311 3887 , iBVBv^ -X N \ f J f ) J l3344 1894 ^ 3*37 J IMS
3304 - 1739\ 2H9 . ( 10J6 l 40B3 3802v \
3489
MMi .(^iJU.VVVMl
III" ) SS48 — 3912
VO"~ 2980 — 5756^- MU
^.ISft'^ 5K5 ^. 4221 V Iffif ^ "42M 4090 fljSl \ f 131
IK ^ '1*88 — 1(86 8559 5442 1886 2778
0=4 0=50=8
25
Line 200 WDipole-Dipole Array
uo
na
a = 35.0 M o oplot point
Resistivity and Chargeability Anomalies
' Very strong•Strong
•Medium
•Weak
•Very weak
tohti O
xxxx xxxx .... - - - - -Extremely weak
Scale 1:2500O 25 50 75 100 125 150
ia^s^ti(meters)
Plate 4
CANDOR VENTURES CORPORATIONINDUCED POLARIZATION SURVEY
HAPPY FACE PROPERTY MADOC AREA, MADOC TWP., NTS 81 C/12
Date: 02/03/15 Scintrex IPR-13 Rx(2 sec), IPC-7 Tx(2 sec)
Ltd., re/. 2-8, March 2002
Metal Factor(mhog/m)
5+00 S 4+50 S 4+00 S 3+50 S 3+00 S 2+60 S 2+005 1+50 S 1+00 S 0+50 S 0+00 0+50N 1+00 N 1+50 N 2+00 N 2+50 N 3+OON 3+50 N 4+00 N 4+50 N 5+00 N 5+50 N 6+00 N
0=1
0=2
0=3
0=4
11=5 11=6
D.BB ^ — U —— . 12 -I.* y .
O 0.050 0.20 -OJE 0.12 0.12 0.12 050 0.070 0.13 0.070 0.070 0.040 0.040 0.17 0.030 0.10 0.080 0.040 0.080 0,060 0.080 0.070 0.030 0.13 0.34 0.35 " ~ 0.43 -- 0.52 "^ 0.87 . . 0.74 0.9t , __ 12 X.41
0.4* 0.21 0.11 0.17 0.39 0.13 0.050 0.020 0.14 0.19 0.070 0.050 0.020 0.21 -0.16 -1.39 0.080 0.13 -0.020 0.070 0.07D 0.070 0.060 0.070 0.050 0.13 0.030 0.090 0-060 0.080 0.050 0.090 0.080 0.040 0.090 0.080 0.24 0.37 0.25 0.23 0.45 " 0.48 f 1.00 -' 0.53 " OJ4l \ ' f
Ojo 022 o.l4 0.12 0.19 0.19 0.060 0.040 0.070 0.19 0.15 0.030 0.020 0.080 0.12 -0.0100 -0.090 0.060 0.12 -0.040 0.000 0.030 O.OBO O.OBO 0.090 0.17 0.020 0.060 0.040 0.040 0.11 O.OM 0.11 0.040 0.020 0.06* 0.13 0.26 0.29 0.13 0.19 028 0.68 ~ 0.60 0.13^ x
013 ou o.l5 0.14 D.I l 0.070 0.030 0.13 0.11 0.1* 0.10 0.020 0.030 0.14 0.14 0.10 -0.040 0.060 0.070 0.050 0.020 0.050 0.000 0.10 0.33 0.030 0.070 0.040 0.030 0.050 0.10 0.080 O.OBO 0.020 O.MO 0.1B 0.15 0.22 0.17 0.14 0.090 0.39 "~ 0.47 0.1B
0.11 O.OBO 0.1E 0.17 0.090 0.040 0.060 0.1D 0.12 0.10 O.OBO 0.040 0.030 O.OBO 0.080 0.090 0.19 -0.080 D.MO 0.040 O 0.050 0.060 0.10 0.33 0.0*0 O.OBO 0.050 0.030 O.OM 0.040 OJO 0.040 0,040 DJMO 0.05* 0.17 0.15 0.14 0.26 0.090 0.41 0.16 0.12
IP - 8Apparent Chargeability
(mV/V, 690ms-1050ms)
5+00 s 4+50 S 4+00 S 3+50 S 3+00 S 2+50 S
Possible Deep Sourae
3+00 S 1+50 S 1+00 S 0+50 S 0+00
IP - 50+50 N 1+00 N 1+50 T)
0 = 1
0=2
0=3
0=4
0=6 4 4^ 3.3-N 1.1 2.8
IP - 42+00 N 2+50 N 3+OON 3+50 N 4+OON 4+50 N 5+00 N 5+50 N 6+00 N'n^r
i^T Masking
44 4.4
7.1 9.7 10 10 7.9
3,9 f 8,9 6,3 . 11 W 9!5viO B.J
11=5 4.3 6.4 5.1 10 11 9.3 9.1
- S
l1.4 12 j 0.68
0.74
6.5 - 4.5 S B.3 9.4
4.9 x 7.6 4.7 -~ 7.2 4J3
0.5 ; 3.9 3.5 7 7.7 4J 3.8 \ 7.6 , 44 11
91 4J1 4.5^ *J 4.7 4.3 4.4 ^ TJv 4.6 4 l 5.9 7 U'/.H l 1J 2J \- 1.2 1.5 —" 1,4 1.4 .
7.5-^8.7 5,3 /T\ U 4.5 42 4.4 7.6 5.2 ^ 4J 3J/ /U U\ 2 8,8 \\ I.—^ 1.4 1.4 0.97 x ' 0.50
5.6 7.S" 9 l S.5 4 j 5.Sl\ 4.1 4.4 \ 8JX 5.9 2.7,——-Z ^ IS 1.4 \ 2.1 ^3 \ V OK^ 1.1 —— 0.97 x 0.57s s—*. /,/N/ V \\\1/ //——^ ^~^—J \ \ v_ \ - - -\s aa it rnis-10 8.J 5J v 4.1 5
5.3 13 ' 2.6 1.1 1.6 1.8 It
1.6 2.2 U l 0.4J - 0.53
Apparent Resistivity(ohm-m)
5+00 S 4+50 S 4+00 S 3+50 S 3+00 S 3+50 S 2+00 S 1+50 S 1+00 S 0+50 S 0+OG 0+50 N 1+00 N 1+50 N 2+00 N 2+50 N 3+00 N 3+50 N 4+OON 4+50 N 5+00 N 5+50 N f+OON
1778 y 13K/ , IB71 - 1319 -^ ITl— 8237 . 4013 3153 — S084 2888 - 920 -^~ 142 1271306—2402 , 04*5171__ Iffi 9311 , 40732211 — 2092 — 1655
1978 4756 ^ 3698 —- 2434
i2123 s' 4407 ^ 0391 82542946 43*7 \ 133* — 1818 / 3893
O. 49,
2833 2784 6232 1(120 3539 3883 -i 1380 4MB 8682 8934 6888 8801
2789 6777 9401 8733 7425\4511 - O39 9021 7588 - 1353 101
41(1 7493 111 31K K14 12342910 r^ *S36
3797 I'm ^ tm ^ 3ZM
0=311=40=5 15B5 4MB 3709 6865 ^ 7899 ~ 8686 —— Uf
991 X 4006 6605 5530
1286 /. 3111 4993 ( 9075 ^ 5309 — 4J75
5807 5609 ~ 6609
, MI )) -"2000 ^"iS ̂ ah 1570 ^ffiu " ///7 1———————-! \ r\\ V . .30K '5148 6594 ~~ 4484 ' 2010 ^ 1372 x 5758
l ^ 181 —S 223 V 141 108 ' ^ 182
311 \ 136 X 192 -—— 215
S87 i { 2078 \S 520 -^*W ) 205 161 ' j'm
__^ 1253 N 2185N^ 762 ( 282 206 ^ 385
— lot* — eat -\ 2ssf\\ 4—1 ' 1490 1019 1107 — 1008 —— 836 - x 2531 x^ 427 ' 276 '"^ 433
Metal Factor (mhoa/m)
0.35 0.29 0.39 0.34 t21 0.060 1.070 0.0*0 0.10 0.10 0.17 0.22 0.15 0.1* (L27 0.38 0.15 0.37 0.23 0.21 0.19 0.070 0.040 0.020 0.060 0.17 0.040 0-41 0.080 0.040 0.040 0.050 0.11 0.11 0.10 0.16 0.47 D.BB ^ — U —— . 12 -I.* 0.77 x2.2 - 1.4 l* n^l
0.37 0.17 0.16 0.41 0.27 0.11 0.020 0.050 0.17 0.10 0.10
0=3 11=4 0=5 0=6
Apparent Chargeability(mV/V, 690ma-1050ms)
0=1
0=2
0=3
0=4
11=5 0=6
Apparent Resistivity(ohm-m)
11=1 0=3
11=3 0=4
11=5 0=6
line ODipole-Dipole Array
a. = 35.0 M go
plot point
jteaistivity and Chargeability Anomalies
1 ......... Very strong
——————......... -strong
—— — — ......... Medium------- •••••••••Weak
..................Very weak
xxxx XXM ••----•Extremely weak
towi o
25 OScale 1:2500
25 50 75 100 125 150
(meters)
Plate 5CANDOR VENTURES CORPORATIONINDUCED POLARIZATION SURVEY
HAPPY FACE PROPERTY MADOC AREA. MADOC TWP., NTS 31 C/12
Date: 02/03/08 Scintrex IPR-12 Rx(2 sec), IPC-7 Tx(2 sec)
JVX Ltd., re/. 2-8, March 2002
Metal Factor(mhos/m)
5+OOS 4+50 S 4+00 S 3+50 S a+00 s 2+50 S 2+00 S 1+50 S 1+00 S 0+50 S 0+00 0+50 N————i——i——i——i——i——i——i——i——i- 1+00 N 1+50 N 2+00 N 2+50 (f 3+00 N 3+50 H 4+00 N 4+50 N 5+00 N 5+50 N 6+00 N
11=1
11=2
11=3
0.48 O.QSO 0.13 0.10 0.14 0.21 O.IT 0.27 0.24 0.20 0.20 0.12 0.14 0.25 0.21 0.27 0.010 0.18 0.16 0.070 0.040 0.0100 0.030 0.17 0.17 0.080 0.030 0.020 0.090 0.080 0.20 0.52 x 1-—^ U v 2,6 0.85 ~ 1.7 __ 1.6 1.4 1.4 ^,1 , 0.760.21 0.13 0.090 0.15 0.070 0.13 O.lt 0.11 0.14 0.13 0.13 0.10 0.10 0.14 0.11 0.27 0.20 0.050 0.060 0.060 0.090 0.020 0.020 0.11 0.12 0.030 0.11 0.020 0.060 0.010 0.22 0.19 0.39 - OJ8 \ 1.7 ^ 1.1 ^^^^ 0.70 - OJl ' 0.58 C" JliT 0.73 - 0.78 - 0.63~ - ' 0.23
0.12 O.OBO 0.13 0.12 0.11 0.080 0.10 0.11 0.070 0.090 0.10 0.080 0.080 0.12 0.070 0.14 0.21 0.12 0.030 0.040 0.090 0.050 0.020 0.090 0.10 O.OM 0.050 0.050 0.080 0.040 fl.48 ^ 0.31 0.13 0.27 , ' 0.90 , -^ 0.60 \^ Ll\ ^ 0.59 0.63 "0.46 -- 0.52 ''1.44 ""OJO 0.12OJO 0.030 0.070 0.17 0.10 0.14 0.0*0 0.080 0.080 0.060 0.070 0.070 0.080 0.14 0.060 0.11 0.11 0.14 0.060 0.020 0.060 0.050 0.0(0 0.000 0.090 0.030 0.080 0.0100 0.18 0.020 0,44'' 0.5?" 7, 0.43 0.10 0.41 ' ' VM 0.40 V 0,94 N 0.54 0.56 0.26 0.27 0.18 -0.070
n-5 0.11 0.070 0.040 O.OW O.J4 0.10 O.OBO O.DBO 0.070 0.010 0.060 0.050 0.070 0.11 00*0 0.10 0.070 0.060 0.070 0.050 0.030 0.050 0.000 0.26 O.OM 0.030 0.560 0.010 0.030 O.OM 0.30 O.M l 0.36 0.20 0.15 D.1B OJS x 0.07 - 0.83 ^ O.M 0.29 0.11 0.060 -0.21 11=6 0.0100 0.060 0.060 0.040 0.0*0 0.14 0.080 0.090 0.060 0.060 0.060 0.040 0.060 0.14 O.OM 0.11 0.070 0.060 0.040 0.080 0.21 0.020 0.030 O.SS O.MO 0.090 0.060 0.030 0.11 -0.040 ' ' l" -^ 0.16 0.62 0.28 ' ' ~12~ ^ 0.11 0.16 -0.19 ~ (USD ' 'Tj! - ^ 0.17 0.26 O.OM -0.11
Apparent Chargeability (mV/V, 690ms~1050ms)
11=1
11=2 n^3 n=4
11=5 11=6
—————— I P - 8———5+00 S 4+50 S 4+00 S 3+50 S 3+00 S 2+50 S 2+00 S 1+50 S 1+00 S 0+50 S 0+00
IP - 50+50 N 1+00 N 1+50 N 2+00 N 2+50 N 3+00 N 3+50 N 4+OON 4+50 N 5+00 N &+50N 6+00 N
masking-
3.8
3,9 4^ i 2,5 - 1,7 - 2.6 2,5 5.3 ^ 3.6 , 2.4
3.4 3.t 4.1 3.7 3.4 4.1
4j ( *m\\.u fi9\ v Y^X^X. L VYWC^X l \4 V^ 0.91 SC 3.2 X 2.7 ———3 k}) L7 C \P '-^L^- V
7js ~O\ [^ —— ij \\^ .jj2 ~ 0.13 ' 'MT^A \ r^\\V -1 s **. an \ I nu
3,6 , 5.1 5.B 7.4 7,2 4.8 -2.5 \ 4
5.3 6.7 7.4 8.4J 5.6 4,8 l— . -~- -— — - — - , -y -- , - - ,* ^
5.4 -—— 4.9 V 5.4 6.7 7.4 6,9 5,3 5,3 \2.3 U 2.7 2.8 12 2 t M~^~~- 3.1 4.7 3.1 2.7 4.6 ' 6.1 f 4.J ] 8.2
4.5 6.8 4.8 6.5 6.3 5.4 8.1 6 4.B 3.3 3.6 J) 2.7 iTj 2.3/3.4 4.7-—-M 3.1 l ^ j 4.5' 6.2 5 3 -——S 65
2,1 v 5.1 8.5 5.6 5.4 ^42 \ 5.7 6.2 5.6 6.3\ 3.5 2.9 2.4 U^S M 4.9 l j W (2.5 j U ^- 6.1 6.2 6 5.8 " ^ 3.1 4.7 ' 54
0.36 ' 3^ |N 7.2 'lO 3.7 4.3^ 5.9 5.6 1,1 *.2 ^ 3.6 1.8 /^4 4 4J 6.5 5 3.5 4.6 "-^1.7^ 4.6 —— Si 7.5 ' "fl^5 Ai 5' 5.4 ^ 3J 4.7^' -l.S"
Apparent Resistivity(ohm-m)
5+OOS (+OON
Metal Factor(mhos/in)
0=2
11=4 0=5 11=6
Apparent Chargeability(mV/V, 690ms-1050ma)
1.1 '-'^ L* LB \ Li IJ! 12 u 1J L4 L3 '-2 1=1 l l 1.7 l J 1.7 \ 1.3 l 1.2 0.98 l J 1.1 S, 0.52 n=2
U^-^lJir l^\.l-9 , 1.4 1.1 1.1 .1.00 0.89 ~ jl.90^, 0.36 n=3
0=4
n=6
11=3 11=3 11=4 11=5 11=6
3+50 N 4+00 N . .'. . i . .'. . t11=1 . .'. . J . .'. . J . .'. .-l
2721 1743 — 5036 964-^ 334 ^ 107 ^ 71 63 , 216 ^ la 14314M 1497 1416 . 1920 ^1938 3340 \ 1716 -857- 1222 ^ 937,, (483 2409 1524 ^ 5463 , 141 , 401714 , 6117 46S6 ^ 7347 -5257 101 123 ^- 155 n=l
4322 3526 ^ 2414 2442 2002 2656 3090 2947 t 1302 -" 2358 1313 — 1695 V 6057I2SS -^ 4103 v 8138 5009
717 568 . 434-^ , .
410S ^ 5727 5362 7071 6370 — 4B19 3249 3199 ~- 2733 ^ 3224 ^ 2838 - 1634 193 —— 203' 231
503 — -. 363 166 287 260 ^ 337
Apparent Resistivity (ohm-m)
45M^
2297 ,. Cm 3844 v 6541 J 3966 l 9416 7335 5722 5671 "~ 5175 3933 2442 1601
1869 's 7718 \ 19K\ "aSO 3731 4358 f tW Mli VS 8SB^. HI ^ 6813 5664 3591 (jail /" 4890 ~~ 4724 8015 x 5114 ^439^ --2412 ' 6801 6234^ [7l X 9321 s K7fl 5555 53,5 \ ,a ltf 12| vv. an 3reo , j,M -- 47W 4575 (gjj tm tm — 7411 - 4519 x 221—- I6K ' 2292" 876
\ lu i mi e zu li 'eta nw —. auao ^v an an f t ami / l^l^/s ™* "^ "^ fx ,,.. -. 7362 5620 11 ill——" 25S '/f 5458 2201 //lll\ 430S\ "
. \\ \ ̂ ^^ \ \\\\ If/// ^-^S// }\~~"^ 2275 ~~ 2250 2156 v \ 101-^ 121^ 7009 — 880S Xffll/, 1294 3410 ̂ 121 J 7961 -^ 8933 — 0104
4741^ 2BAO 3041 .{(26I^\ 9569 ^9826. 8677 — 6742 3332 J/J6I . 77S9 ^ 9S27. /^"A ClS^^^T ^
!3I H 3055 — 3B05 s-2Wt S~ W . ..^ 7// /^^ ^ X /x^\\\\N) \. ,9283 15K ' 4395 417D /' 371 455 VU ' 3to 821 7 - 1281 848 x 225 y 145 151 ' 340 352 522 450
"/^^"xN 1*1- *-' 1M1 MR \ !Bl
Line 200 EDipole-Dipole Array
a = 25.0 M
V plot point
Resistivity and Chargeability Anomalies
• Very strong
xxxx xxxx
-Strong
- Medium
ffeak Very weak
- Extremely -weak
CTlo
Scale 1:250025 50 75 100 125 150" -J L-
(metera)
Plate 6CANDOR VENTURES CORPORATIONINDUCED POLARIZATION SURVEY
HAPPY FACE PROPERTY MADOC AREA, MADOC TWP., NTS 31 C/12
Date: 02/03/08 Scintrex IPR-12 Rx(2 sec), IPC-7 Tx(2 sec)JVXLtd., re/. 2-8, March 8002
Metal Factor(mhos/m)
5+00 S 4+50 S 4+00 S 3+50S 3+00 S 2+50 S 2+00 S 1+50 S 1+00 S 0+50 S 0+00 0+50N 1+00 N 1+50 N 2+00 N 2+50 N 3+00 N 3+50N 4+00 N 4+50 N 5+OON 5+50N B+OOK Metal Factor (mboa/m)
11=1
11=3
11=5
0.24 0.29 0.12 0.84 D.2B 0.12 0.13 0.19 0.030 0.020 0.030 0.030 0.020 0.060 0.090 0.070 0.020 0.44 0.36x l
0.12 0.16 0.13 0.14 O.GO 0.10 0.080 0.30 0.10 0.020 0.030 O.C 0.020 0.050 0.040 0.22 O.OU 0.050 0.24 0.44
0.11 0.11 0.070 0.13 0.11 0.20 0.080 0.12 0.16 0.070 0.040 0.0100 0.050 0.030 0.13 0.12 O.OM 0X100 0.23 0.25 ^ 1.2.^.—— l
2.2 2-1 1.4 1.J
U \ N 8.2 J .1.4 f 0-77 ^ l
0.86 0.3( ~ 0.41 -014 -0,17
~~. 1.9 , U __ 1.3^T— C \1.57 :^- 12 V 1.7 N
~^N \ )0.17 . v 1.1 \, li
^ v\ ^
1.4 1.2 l .^1.5 1.5-_^1.9 s 0.87
0.79 . ^ OM y 0.14 - 0.81 ^ 0.81
13^ 0.87 1.3 V.y^^ u,
7- tM/ 0.49/O- 1-2 -^ VXI ' \
15 0=1^.t.n 0=2
0.51 " 0.42 - 0.57/ 0,33 0.19 048 0=8
O.OM 0.14 D.OSO O.OSO 0^0 0.060 0.1S 0.000 0.080 0.14 0.18 0.030 0.020 O.OSO 0.030 0.12 O.OBO ^ O.BS ^ -0.11 0.060 0.19 0.17 ~ 0.60 jx/1.7 ^ .0-77^ -0.4S -0.41 -0.53 -0.47 -O.ZB OJ+ - : VM ^0.56 . . O.S3- - JJB 0.70 0.040 0.35 0^3 0.1S 0,050 O.Zfl -0.090 0.40
0.070 0.090 0,050 0.050 0.10 0.12 D.050 0.10 0.040 0.070 023 0.080 0.020 0,070 0.020 0.000 0.000 0.64 ^ 0.40 0.050 O.OBO 0.13 0.22 -020 0.11 0.34 -O.W -14 -0.44 -0.73 -0.52 0.13 0.41 0.42 0.47 " 0.37 0.45 0.040 0.15 -0.080 -0.90 -0.1 Z 0.34
0=6 0.060 0.10 0.040 0.070 0.080 0.07(1 0.000 0.040 0.070 0.040 0.13 0.13 0.080 0.10 0.060 0.070 0.73 ' -0.040 0.58 0.10 0.040 0.14 0.17 -0.39 -1.3 -a 041 -0.4S 0.38 HL29 -0.17 053 0.14 0,13 0.10 0.38 0.47 0.40 -1.8 HUB 0.12
11=5 11=6
Apparent Chargeability(mV/V, 690ms-1050ms)
5+00 S 4+50 S
IP-8
4+00 S
IP- 73+00 S 2+50 S
IP - 62+00 S 1+50 S 1+00 S 0+50 S
11=1
0=1
0=2
0=3
0=4
2.1 .__ 2.1
2.7
3.9 3.6
3.7 3.1 3.5 l 1.6
9.2 f"" 10 7.8 7.9
4.8 ^-S 6,1 \ 9.9 .10 7.8 M
6.8 6K 7\^ 9.3 \ 10 ^ 9 0.9
L-l--t.-i.-l
8.8 t.B 7.3 7.5 10 -, 5.4
7.4 8.4 9.7 75 B.fl 9.7 V \4/^ 0.94
9.8 __ 9 9.6 B l ' 0.16
0+00 0+50 N 1+00 N 1+50 N 2+00 N 2+50 N 3+00 H 3+50 N 4+00 ff 4+50 N 5+OON 5+50 N 6+00 N-na asking-
Apparent Chargeability(mV/V, 690ms-1050ms)
0=6 6.6 x 3.8 3.5 ' 2,3 - (J
i^y f^ ̂
1,5 ^ 10 7.0 , 4.3 ^*- i
8.7 ' 11 ^" 9.4 7.7 8.9 ( ,(
Ol79 \ 1J
1.1 \ D.B7 x^ L2
O.H . (1 ' ' OJI4 ^ O.M
U l
/^^SSvV ' ~ ^ ' f \ ' 'i ( 24 \" 0.94 '^ ^0.28 ,l ^1-S, J.86^' -8.33 -OJ9 -OJ* -0.50\TU VV
0.51 8.75 0.87. - 1.3 8 1.9 I.* --2
Mf ~^~*M y' ^0.60 0.0(0 OJ31 x DJH. ^ 1.2 ( 1.8 1.9 f 2.1
(U4 *" U* -0.28 -0.18 0.14
-0.37;N\;\\^:-8.11 ~ 0.14 0.30 -0.78 -1.6 -0.52 -l -0650 -0.53 0.21 , OJt3
'^fc
. . .^. . . .
4 \ l u 1.3 ^^- is 2 12 f o!rT~^! i.i is — u J v -V S~~^ v "^——J i l"' ~\x\ JX0,41 ^1.8^- 0,45 \ 1.1 1.J 1.5 l . . MN ' O l————l —"^ "."----'VA \ ^—" *v -2XlV-~o. M
M -0.63 0.21 fcW '^'.-" OJnf ll4 0' 13 B'™
1-8 1.4 U ^ 1.1 ——. 1.1 - 0.75 0=1v / ^-— --~^x1.5——" 1.5. 1.7V 1.96 1.5 0.96 - 0.89^ , 0.50 i 1,1 n^2
0.87 ^-1.1 'y 0.38 OJO ,' 0.81 11=3
ZA ^ 1.3 v -0^7 -1.2 ''' 2.1 * -E.5 0.72 -0.72 0.7* -Oil -0^8 ' 0.9S ' 0.37 - 0.31 0.23
0.49 0.090 0.28 -024
-0.30 -0.91 -0.27 , '
-J -1.3 OJS
U-4
0=5
0=6
Apparent Resistivity(ohm-m)
5+00 S 4+50 S11=1
4+00 S 3+503 —————u 5=2-^(1) 3+00 S 2+50 S 2+00 S 1+50 S ' 'VHl(l)' 'VHU)' 'VH(I)
1+00 S 0+50 S 0+00 0+50 N 1+00 N 1+50 N 3+00 N 2+50 N 3+00 NVH(I)
H————i————h-3+50N 4+00 N
-H————'————h- 4+50 N 5+OON 5+50 N &+OON Apparent Resistivity (ohm-m)
900
0=2
0=3
0=4
0=5
0=6
wu ——738 , , 4066 , 1348 JOBS -,, 156( 1884 - 5155v\. *// ^ } mr^i//^-—^o^ ' -23H V 1193 S, 2427 2670 l ^548/f l 4077 — 4870,^ 2121
2915 2426 _ 2896 /^1341 ~-~ 1591 ~ 2132 ( IS
ffi 138 185 159 —^. 104 —-. 77 87 148 ~^ tX44K ^2BK^- 361 37K ^ 15K W 06 __ 00 s. 48^ ^- .
131 ) 83 ^ W "^ 82 133 _. 143 ^ ^ 211 227 \ IM f 231 205 ^^ 118 181 197 ; l 57 S J 134 __ 142.
1732 3-1 578 250441 ,VL VSL flll .151
183' 208 ^-- 303 182 191/380 " 270 \- 161 IK S 110 ^— 1S88780 0794030- 1526
105 107 130 129 124 112 349/221^—2K 287 443 332W., 7S19 — 8839^578 581 \ 184* 1337
01 119 142 177 \ 102 160 202 V 385 7 238 237 ,304 339 514 x 3651327 ^ 3W1 f 18K^9178 ~ r 23K ^ 6127 4015 " 141—— H * 116 158 208
4488 f 2584 .4960 , 1853 C 959//^ 6358
5257
131 \ 3952 " 8606 ' 32*4 2250 ^ 4238 7770 151 '263 259 231 242 '345 348 353 N 531 'IB 201 24t
11=1
0=2
0=3
0=4
0=5
0=6
Line 400 EDipole-Dipole Array
tn
a = 25.0 Mo o
plot point
Resistivity and Chargeability Anomalies
-Very strong
-Strong
- Medium
to -J o
xxxx xxxx
- Weak
-Very weak
-Extremely weak
Scale 1:250025 O 25 50 75 _ 100
^m (meters)
125 150
Plate 7
CANDOR VENTURES CORPORATIONINDUCED POLARIZATION SURVEY
HAPPY FACE PROPERTY MADOC AREA. MADOC TWP., NTS 31 C/12
Date: 02/03/04 Scintrex IPR-12 Rx(2 sec), IPC-7 Tx(2 sec)JVX Ltd., re/. 2-8, March 2002
Metal Factor(mhoa/m)
3+50 S 3400 S 2+50 S 2+00 S 1+50 S 1+00 S 0+50S 0+00 0+50N 1+00 H 1+50 N 2+00 N 2+50 N 3+00 N 3+50N 4+00 N 4+50 N 5+OON 5+50 N
11=1 0.1B 0.18 0.17 0.24 0.12 0.27 0.37 -0.0100 0.10 0.14 044 0.20 0.080 0.020 0.0100 0.0100 0.030 0.38 0.50 - . 0.56 s - 12 J.I j—~
n-Z 0.23 0.040 0.33 0.40 0,22 049 0.15 0.070 0.030 Oil 0.17 0.090 0.060 0.040 0.0100 0.0100 0.03) 0.40 041 0.36 "o.tf - \88 0.28
0=3 0.17 D.OBO 0.070 0.44 0.21 0.32 0.15 0.080 0.030 0.12 0.30 0.13 040 0.030 0.030 0.0100 0.0100 0.82 0.84 0.20 0.34 -1.4 0.36 "" 0.71 , 0.48" " 0/67 ,- 0.44 * 0.8! ' 0.4! , 0.57 x " 0.39 0.40 0.51 0.41 0.50 . 049 0.44
,4 -~-^ 8.1 1.5 ^^ 15 s/ 12 ^^f 1-0
"Q^X.jj ^, 0.91 — 0.13 ~" O.SI — 0.83 *
0=4 0.12 0.050 0.12 0.070 -0.25 0.19 0.29 0.060 O
0=5 0.080 0.050 D.OBO 0.11 0.030 -0.70 0.020 0.11 0.020
0.10 0.15 0.30 0.080 0.080 0.040 0.030 0.40 0.27 0.22 0.050 0.3Z -9.2 -0.46 043 0.34 0.21 D.39 ~ 0.44 0.60 0.39 0.15 0.040 0.20 0.39 0.48 0.44
0.12 0.20 0.11 0.030 0.090 0.090 0.070 -- 0.60 0.16 0.22 0.17 0.13 0.28 -7.7 -0.21 0.030 OJ1 0.18 0.35 0.40 0.17 -0.11 0.070 0.10 OJO Oil
0=6 0.19 0.15 0.12 0.10 0.040 -0.43 0.020 O.D40 O.OM O.HO 0.080 0.18 0.090 0.040 0.070 0.070 -^ '.\1 "" 0,96 0.28 0.23 D.34 O.lfi 0.31 -2.4 -0.70 -0.12 0.13 D.08D 0.12 0.090 0.10 O -0.01DO Q.M ^ 0.37 O.S3
Apparent Chargeability (mV/V, 690ms-1050ms)
0=1
0=2 11=3 0=4 0=5 0=8
Apparent Resistivity (ohm-m)
11=1
0=2
0=3
0=4
0=5
0=8
3+50 S 3+00 S
IP- 72+50 S 2+00 S 1+50 S 1+00 S
IP - 6^0*50 S | 0+00
5=1 ~ n=l0+50N 1+00 N 1+50 N 2+Ofl N 2+50 N 3+00 N 3+soN 4+00 N 4+50 N 5+OON 5+50 N
-Masking-
3,8 3.3 5 4.1 /;. -0.11 f,, 19H 13 r 7.1
5-t ^ 5.4 . 3.3 A\14 9.8 l 5.5 3.3 ... _
2.8 ^ 5.1 UN. 3.(-^ (.8 -"~~*.3 j 3.9 3.5 4.6 ——- 5.3 (84 8.5 ^ 10 13
1.9 "i.8\\S B.5. ((f^Sj^^iS 4.1 ^Ut ^*~~-v.7.1 U\ .11 10 IS
0.50 J 1.8—-^ 2.5 ^ 5.6 ^ i1\, -2.B ~" 0.18 \ 5.3 7.5' 92 8.8 l 5.7 7.7 \ It J 9 "-"x 11 •s^/^- \ S l\\ "^\ l f ^,—^ J \ \
1.8 -^ 2.7 34
2.7 L
2S J f2.3 ' 1.1 -2.1 0.57 ^ 8.3 ' 9.5 7.1 SJ 94 8.3
.2.9 i t2 f 1.5 1.2 1.8 ^1.8
8,8 J^S.1, \ LZ^l'r *.M
- 1.1
12 il'- XN i,8 2.5 2.3—— 24 -3.4 -1.5 -0.41 0.44 ' ~ 0.21 0.44 - 00^-^017 -W30 -O.OM IA
3+50 S 3+00 S 2+5&S 2+00 S 1+50 S 1+00 S 0+50 S 0+00 0+50N 1+00 N 1+50 N 2+00 N 2+50 N 3+00 N 3+50 N 4+00 N 4+50 N 5+OON 5+50 NVH(1) VH(1) VH(1) n=l
2833 — 1818 -.6241 5484 5931 1858 UIB ——931^S\\\^P^——-——" l V^-^ ^^-^"\ ~\Sial 'f 12S\V 1000 ^ 348D 4440 2929 2071 — 2*28 -^ 8759 i 25741 1 .vsL j\m^N.... s:.. ... . ^^^\ lv ̂UK 8893
X31(8 ^ 1955 . 2878 /^ 603B ^T}^\\ fi
S\ MT-^: (166 \ 12V (lv.\\yi._ \i
841 x 39E 341 i W///;: 388 344 , K (9 70 __ 60 48 74) r~A \ //f/^/ ^^ C \\\ -_. \———-" ^-^ ^-^311 ( 581J ML f///.Tab Wi-Va~-^\\\ 95 ' 111 ~^^. 89 ___9^^118^^-182 —— Ut -^^232 23!
101 vVV39C 291 411 ^L/MyR^-—497 592 542 NS 78 —^. 118 129 ,-— 152 , 122 S f *" "" ^ w5TX ,la M, S\\ V .~^^.S'SjwZ0S?' V \\N\\ l \ S ^*~~——^*' J
""^^ 33K 351 /^ii? :^fll .i~ 761 ^ 526 715 550 ̂ ^85 ^ 129 ^ 205 -~-. 187 ——- 213 2W -^ 352 334 \ 255 7 415 J57 J54 339 S (OS f Ml
~^ l̂ J ' ''7 236 ^ 304 ^ 251 ^ 407 3J7 322 413 384 379 3(4 /^831 518474 657 823, 633 864
1660 / 3945 ~4848\ 9632 ^725-ir 1241 — 1667 ) ,'7269 Ym] 7828 ^- 4843 l 2231 (f 171f \\ rCV^^N^N \(////// /l l\\\ \\ \\\\lf x , - vx
3881 2920 , 4814 . \JOI ̂ /Y S*4^y 923 \ 4743 f f Sil/ ^161 X 7504 \ 28EB J 7075 { S3I \\ IK \ V401
1874 26S1 2949 5403^4958^479^2594^211 -151 181- 6753 \ 3139 ^ 111- 271^ 111——1(1'^290 525" 099 973 x TOO ' 1339 "fl50 sX^14i 209 ^ 359 344 J30 S72 316 492 412 423 401 ^ 758 544
594
Metal Factor (mhos/m)
l—— aW J.51 0.55 - 0.50 ^ 044 0.48 0.88 n-1
0.67 ~~ ~o!82 ' 0.41 0.38 0.39 ' OJ* | 0.41 'o,54 n=^
11=4
0=5 0=6
Apparent Chargeability . 690ms-1050ms)
1.2 1.7 0.50 - 14 — 0.71 0.84 - O.W 1,1 - 1.7 1.5 1.8f —' N\\ f / f/ io^u 11 11 N^ii u (J'4 /^'5
-* -0.59 OJS O.M " 0.44 ) 1" /f-0.42 9.0*0 O i 0.79 - 0.73
Apparent Resistivity (ohm-m)
US2 357 _ 451 S07 n^l
375 330 l ttH 477 0=2
0=3
11=4
0=5
25
Line 600 EDipole-Dipole Array
H O
sw
na
a = 25.0 M
plot pointo o
Resistivity and Chargeability Anomalies
••Very strong
-Strong
Medium
xxxx
- Weak-Very weak
Extremely weak
to oo o
Scale 1:250025 50 75 100 125 150
jni.ini^, (meters)
Plate 8
CANDOR VENTURES CORPORATIONINDUCED POLARIZATION SURVEY
HAPPY FACE PROPERTY MADOC AREA. MADOC TWP., NTS 31 C/12
Date; 02/03/04 Scintrex IPR-12 Rx(3 sec), IPC-7 Tx(2 sec)JVX Ltd., ret. 2-Bt March 2002
Metal Factor (mhos/m)
2+00 E 2+50 E 3+00 E 3+50 E 4+OOE 4+50 E 5+00 E 5+50 E 6+00 E 8+50 E
0=1 0.050 0.10 0.020 D.D60 0.030 0.030 0,030 0.030 0,030 O.OM 0.080 0.070 O.OM 0.1S 0.090 0.17 0.090 n^l
0=2 0.060 0.070 0.060 0.030 0.040 0.030 0.040 0.12 0.0100 0.020 0.18 0.050 0.15 0.28 0.010 0.10 0,080 0=2
11=3 0.080 0.090 O.MO 0.080 0.020 0.040 0.040 0.0100 0.020 0.0100 O.D40 0.14 0.080 0-30 0.21 0.10 0.050 11=3
Metal Factor (mhoa/m)
11=4 5.6 \V 0.15 0.050 O.MO D.OBO 0.020 0.090 0.020 0.030 0.020 0.030 0.040 0.1B 0.13 0.2t 0.24 O.MO
11=5 C.OM -r-^2,'V-': 0,0*0 0.070 0.040 0.060 0.050 O 0.030 0.020 0.040 0.030 O.MO 0.22 D.OW 0.49 0.14"SS*T
11=6 0.040 0.26 - 0.060 0.13 0.0*0 D.D40 0.11 0.0100 0.040 0.030 0,060 0.040 0.040 0.060 O.OM 0.0110 0.23
11=4 0=5 11=6
Apparent Chargeability 2+ooj (mV/V, 690ms-1050ms)
11=1 0=2 0=3
11=4 0=5
2-1-50 E 3+00 E 3+50 E 4+00 E 4+50 E 5+00 E 6+50 E•"11=1"
0.8 6 j- B.6 9.3
Apparent Chargeability (mV/V, 690ms- 1050ms)
.i5.7 J 4.7 ) t.2 I 9.Z\\\ ^^~— -24) \\ 4.4 t.3
176.5 -^ 1.5^ 3 5.8 i v 18
8.4 5,3 ^ 5,2 7.4" 8.5 M [ 7.1 / 8.4 ^ 11 , S.S X i 11 11 C 22 J 13^
10 12 15 -^ IB \7.6-
10
6.1 f 9.3 7.8 9* 9.6 f 6.1 ^5.4^^*^11 12 11 XsV. 16i /*-\ ,—^J /^/- 7/ ^^ \5.6 s' " 8.3 Q \lji 4.4 -s (.5 f^ 9.9 14 13 13 ^X™ 6.7 ^\ 16 ^x, 13
5.1 ^"^9.7 ^tB 1 8.4 --"W 4.3 '10 18' x 14 14 ' 5,1^^^3.7 4.1^- 18
0=3 0=3 0=4 0=5 0=8
Apparent Resistivity 2tOOE ,(ohm-m)
2+50 E 3+00 E 3+50 E 4+OOE 4+50 E 5+00 E 5+50 E 6+00 F 6+50 E Apparent Resistivity(ohm-m)
0=1
0=2 0=3
11=4 0=5 11=6
HE 9070 ^ 'i
101 7411 — 'B3W
5533 0572
101 , x 30K --28*
31l' "ltt—t
T\wi i a*
9840 ^^- 10E __ 7202 ^v 211 24E ---
241 -— 301s—^ ^^ ( f—\ -—^-v/"—xj*r^x/' \. f 12K v 7B37 v l 431 \ 21K ___ m. f S4S ) 25K ' 511\^ ^ J\\V - --
2940 \ 7770 ^-101—^ 151 ,.,\U l \ l -^333 ill au 8148 /m
'4887 ' 7078 5106 —" 3B4B
0084 5102 /\\t___ K̂ ^ /'
m' an ^-saiNVBoia — 6432 sssi -~ 4570 /IK \ \\V r-x l l /
3SI 411 ^24X\l 3357 ) 7722 l WU l 9043l i\\n "f 739K 311 ' KM 4766 9160 — 6800
3141 n=l 0=2
0=3
0=4
0=5
0=6
Line 200 SDipole-Dipole Array
to to
a ^ 25.0 M
V plot point
on
Resistivity and Chargeability Anomalies
XXXX X X XX
•Very strong
• Strong• Medium
•Weak
•Very weak
•Extremely weak
Scale 1:250025 O 25 50 75 100 125 150
-l i ^(meters)
Plate 9
CANDOR VENTURES CORPORATIONINDUCED POLARIZATION SURVEY
HAPPY FACE PROPERTY MADOC AREA, MADOC TWP., NTS 31 C/12
Date: 02/03/22 Scintrex IPR-12 Rx(2 sec), IPC-7 Tx(2 sec)JVX Ltd., re/. 2-8, March 2002
ir , , r, , 2+00 E 3+00 E 4+00 E 5+00 E 6+00 E w , , ~ , Metal Factor , . ( ———— h .. , ,...| , ——— f. —— , —— ^ ——— , ——— | ——— l—. \ ——— , ——— | ——— , —— ( — , Metal Factor(mhoa/m) (mhoa/m)
n-j 0.45 - - . OJO 0.81 O.M 0.82 0.0100 0.2B 0.13 n^"^ ~~ -- ^
~*- rf- "^ — —. -"^
n-g 0.21 0.050 0.27 0.46 0.42 -0.12 -0.44 -0.43 nz g
n -Q 0.14 9.090 -0.20 -0.18 0.070 -0.14 -0.33 -2.1 n -oLI — O H — u
n = ̂ -0.070 0.070 -0.33 -3.5 -1.2 -0.29 -0.39 -0.48 n-^
n -BL -0.030 0.080 -0.17 -3.7 -fl -0.83 -0.45 -0.89 n -K.1 1 —— J ±M-~" *J
n^g -0.25 0.11 -0.49 -6.8 -29 -1.8 -1.5 -0.47 n-g
A t /-^ i,-i-* 2+00 E 3+00 E 4+00 E 5+00 E 6+00 E A . ^. , . 1 .. Apparent, Chargeability | i | | i i i ' | i | -i | i | i Apparent Chargeability(mV/V, 690m3-1050ms) * ———————————————————————— m askin g ——————————————————————— ̂ (mV/V, 690ms-1050ms)
n j 0.85 ~ — ̂ .^ 1.6 1.8 ^j 1.3 0.95 ,. O.OfiO - \? ——— . 1.1 u -j
n -o 0.71 C 0.15 ^-.^ 0.87 —- -— -^ 1.1 0.97 ' ' -0.68 -1.9 -1.9 ^.--y
n^ 0.48 - - - - - 0.41 -0.65 -0.36 0.19 -0.94 -2.8 -7.4 n-g
n=4 -0.26 0.35 -1.4 -5.1 -2.5 -2,2 -3.4 -3.7 n-4
n^5 -0.21 0.40 -0.92 -8.5 -11 -6.Z -4,8 -7.2 ^-5
n-Q -3.5 0.64 -1.8 -10 -29 -12 -11 -3.9 n-g
Apparent Resistivity i 1 i 1 1 i i 1 1 ' 1 ! i 1 i Apparent. Resistivity(ohm-m) nsl n^4 n=l (ohm-m)
n-l 187 259 288 192 154 -^^^J*L^ ^ \ \N2 n:rl
n -2 339 ^^^— -^ 282—^/ 336 ) 233 233 S .s 550 "~~-~^425 442 ^-^
n-3 347 443 325 ^^ 228 2S8 ^ S m/^" 778 ^ \ 359 n-3
n=4 364 500 ^, 432 7 X 148 ~"\ 218 S S 732 887 774 n-4
n 5 773 ^) 4B4 V 548 1/ J 231 1B2 X X 750 ^ 1085 1053 n 5. f ^ — ̂ 7 ^ ̂ _ li' /r*^ ^1 ^ ^-^ s^^'^ ) J s s /" 1 \n e 1393 l 474 340 -^"^ 153 102 ^ x x 735 x v 751 827 n g
Line 400 N jj B0 ^-^^"
^^-^^
Dipole-Dipole Array joM ^^^^J
a na a 3 -—.' ' '
/ x ^ ^ x x a s 50.0 M
plot point — '^^
^^^^^^^H ^^^^^^^
•-
Wo o
Resistivity and Chargeability Anomalies
......... Very strong
—————— . . . . . . . . . .strong
——— —— •••••••-•Medium
•--- —— •••••••••Teak
xxxx XXX.X- .....••- -Extremely weak
Scale 1:250035 0 35 50 75 100 125 150
(meters)
Plate 13
CANDOR VENTURES CORPORATIONINDUCED POLARIZATION SURVEY
HAPPY FACE PROPERTY MADOC AREA, MADOC TWP., NTS 31 C/ 12
Date: 02/03/07Scintrex IPR-12 Rx(2 sec), IPC-7 Tx(3 sec)JVX Ltd., re/. 2-8, March 2002
Metal Factor (mhoa/m)
2+00 El—— 3 + 00 E 4+00 E 5+00 E 6+00 E+ Metal Factor
(mhos/m)
11=1
11=3
11=4
11=5
11=6
-0.45 0.54x
0.26 0.33
0.020 -0.040 O.D50
0-57x
\
0,25 0.24
0.20
0.48 0.060 -1.4 -0.95
-0.55 -3.2 -1.8 -0.4B
-3.2 -2.5 -0.71
0.030 0.070 -0.020 -0.20 -0.23 -1.5 -1.5 -1.4
-0.13 0.050 0.040
0.15 0.050 0.020 0,060
-0.000
-fl.070 -0.12
-1.2 -1.1
2+00 F Apparent Chargeability |(mV/V, 690m3 -1050ms)
11=1
11=2
11=3
11=4
11=5 -1
n^ 6 1.3 -~ - -
3+00 E——l——— 4+00 EH————i————l————
-0.85
5+00 E
-0.50
n=l
n=2
n=3
11=4
11=5
11=6
6+00 E-I--masking-
Apparent Chargeability (mV/V, 690ms-1050ms)
-O.B3 0.42 ^ ^s \0.41 0.49 0.12 -1.4 -1.5
I.B ^ 0.75
0.12 -0.31
(t \ i
^ so.ie
0.26 0.48 -1.3 -Z.7 -3.1 -2.7
0.51 -4.9 -3.5 -3.6
0.19 0.55 -0.20
0.31
0.33
0.39 fl l
0.10 - -"-"- ' 1.2
-1.6
-Z
-1.2 -2.8 -2.7 -5.2
-l -2.7 -3.5 -5.2
-0.BO
Apparent Resistivity (ohm—m)
2+00 E 3+00 E 4+00 E
-2.8
5+00 E
-2.7
-0.44 nsl
11=2
11=3
11=4
11=5
11=6
6+00 E.'.....li m. m m mn=l
Apparent Resistivity(ohm-m)
11=1
Line 200 N
Dipole-Dipole Arraya na a
a = 50.0 M
plot point
H O
Resistivity and Chargeability Anomalies
xxxx xxxx
Very strong
•Strong
• Medium
Weak
•Very weak
Extremely weak
Scale 1:250025 O 25 50 75 100 125 150^••••g
(meters)
Plate 12
CANDOR VENTURES CORPORATIONINDUCED POLARIZATION SURVEY
HAPPY FACE PROPERTY MADOC AREA, MADOC TWP., NTS 31 C/12
Date: 02/03/07 Scintrex IPR-12 Ex(2 sec), IPC-7 Tx(2 sec)JVXLtd., ref. 2-8, March 2002
Metal Factor (mhoa/m)
2+00 E 3+00 Eh
4+00 E——l——— 5+00 E 6+00 E—l——— Metal Factor(mhoa/m)
0.12 0.48 0.53 -0.020 0.030
n=2
11=3
11=4
11=5
0.070 O.H 0.40 0.26 0.11 0.020
0.040 0.13 0.020 o.u 0.10 0.19 -0.040
0.040 0,22 0.050 0.040 0.070 0.17
0.030 0.19 0.12 0.050 0.033 -O.OZO -O.U
-A 0.06011=6 0.19 0.87 0.11
Apparent Chargeability(raV/V, 690m9- 1050ms)
p i r\ f\ "p| , -|-. 3+00 E
0.040
4+00 E
0.0100 -020
0.020 nsl
11=2
11=3
11=4
11=5
11=6
5+00 E 6+00 E
n=l
n-2
n^3
11=4
11=5
11=6
2+00 E Apparent Resistivity |
1.5 1.2
11=4
1.5
n=lApparent Chargeability
(mV/V, 690ms-1050ms)
n=l
1.1
1.4
3+00 E 4+00 E 5+00 E 6+00 E
(ohm—m) VH(1) VH(1)Apparent Resistivity
(ohm-m)H(4)
11=1 1301 30. m
n=2
Line ON
Dipole-Dipole Arraya na a
en S
toU1
go
a ^ 50.0 M
V plot point
to o
Resistivity and Chargeability Anomalies
xx x x xxxx--
Very strong
•Strong
• Medium
Weak
•Very weak
•Extremely weak
Scale 1:250025 O 25 50 75 100 125 150ar^sig
(meters)
Plate 11
CANDOR VENTURES CORPORATIONINDUCED POLARIZATION SURVEY
HAPPY FACE PROPERTY MADOC AREA. MADOC TWP.. NTS 31 C/12
Date: 02/03/22 Scintrex IPR-12 Rx(2 sec), IPC-7 Tx(2 sec)JVX Ltd., ret. 2-8. March 2002
Metal Factor(mhos/m)
1+00 N 2+00 NH———————h
3+00 N 4+00 N Metal Factor (mhos/m)
0.64
11=2
11=3
11=4
11=5
11=6
Apparent Chargeability(mV/V, 690ms-1050ms)
11=1
11=2
11=3
11=4
11=5
11=6
Apparent Resistivity (ohm-m)
11=1
0.75 0.29 o.oioa 0.95
0.19 -l -0.42 0,33 0.19 0.38
-0.080 -0.80 -1.2 -0,75 -0.28
0,33 -1.1 -' 0.43 -0.25 -0.70
0.17 -1.3 -l -0.29 -1.3
0.080
-0.020
-0.10
0.0100
1+00 N
0.040
2+00 N
-0.29 -0.41
3+00 N
-0.060 ' A -2.7
4+00 N-H————————h- masking
0.73 0.0100
-0.85 -0,56
-0.43 -0.70 -1.4 -1.5 -0.89 0.0100 0.22
-1.5 -1.6
-2.8 -3.1 -1.2 -3.5
-0.32
-0.080 - - ^ -1.7
0.23
1 + 00 N...i.
0.13
2+00 N
-0.99 -1.4
3+00 N
-0.17
4+00 N11=1
306
Z7T
233 '321
269 870
289 228
11=2
n=3
11=4
11=5
11=6
Apparent Chargeability (mV/V, 690m3- 1050ms)
11=1
11=2
n=3
11=4
n=5
-o-6 11=6
Apparent Resistivity (ohm-m)
241
11=1
11=2
n=3
11=4
n=5
11=6
25
Line 400 E
Dipole-Dipole Arrayna
a = 50.0 M
m X
w toUl
o n
V plot point
UJo
Resistivity and j^hargeability Anomalies
Very strong
•Strong
• Medium
Weak
•Very weak
•Extremely weakXXXX XXXX-.
Scale 1:250025 50 75 100 125 150
•L ......J(meters)
Plate 10
CANDOR VENTURES CORPORATIONINDUCED POLARIZATION SURVEY
HAPPY FACE PROPERTY MADOC AREA, MADOC TWP., NTS 31 C/12
Date: 02/03/22 Scintrex IPR-12 Rx(2 sec), IPC-7 Tx(2 sec)JVXLtd., re/. 2-8. March 2002
o o cc
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4- 4-
100Scale 1:5000
O 100 200
05c c en
(meters)
600W 40 O W S 00 W ~20 O E 4 GOE 600E 800EPLATE 14-
CANDOR VENTURES CORPORATIONHAPPY FACE PROPERTY
Madoc Township Madoc Area, Ontario, NTS 31 C/12
TOTAL FIELD MAGNETIC CONTOURSContours: 5 nT, 100 nT k 500 nTBase Field - 54,500 nT removed
Inst: GEM SYSTEMS flSM-19JVX Ltd., ref. 2-8, March 2002
31C11SW2007 2.23257 MADOC 340
80 UEo o
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600W 400W 200W 4 GOE 600E eooEPLATE If)
CANDOR VENTURES CORPORATIONHAPPY FACE PROPERTY
Madoc Township Madoc^rea^ Ontario, ^TS 31 C/12
TOTAL FIELD MAGNETIC PROFILES A: POSTINGS Profile Scale: l em = 1000 iiTProfile Base: 54,500 nT
Inst: GEM SYSTEMS GSM-19JVX Ltd., re f. 2-8, March 2002
31C11SW2007 2.23257 MADOC 350
600W 400W 200W 800EiroCO
oo
.BASELINE
c/:c
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LEGEND
600W
31C11SW2007 2.23257 MADOC
8097.12945.9856.
11470.14362.10985.7458.
5,935.795,326.38
6.756.775.33
Resistivity
Chargeability
iooScale 1:5000
O 100 200
(meters)
400W 200W 200E 4 GOE 600E 800EPLATE 16
360
CANDOR VENTURES CORPORATIONHAPPY FACE PROPERTY
Madoc Township Madoc Area, Ontario, NTS 31 C/12
FILTERED CHARGEABILITY fc RESISTIVITY PROFILESChargeability Profile Scale: l crn ~ 5 mV/V
Resistivity Profile Scale: l cm ^ 5000 ohm-mInst: Scintrcx IPR-12 Kx, IPC-7 Tx (2 sec)
JVX Ltd., re f. 2-8, March 2002
600E 800Eo oCO
o o so
o o
Z o o
O O C'.!
C/3 O O
C/3 O O CO
BASELINE
+
600W
+
-l 00 W 200W
100Scale 1:5000
100 a00 300
(meters)
OOE 40 OK 600E 800E
PLATE 17CANDOR VENTURES CORPORATION
HAPPY FACE PROPERTYMadoc Township
Madoc Area, Ontario, NTS 31 C/12FILTERED METAL FACTOR PROFILESProfile Scale: l cm ^ 5 mhos/rn
Inst: Scintrex IPR-12 Kx, IPC-7 Tx (2 sec)
JVX Ltd., re f. 2-8, March 2002
31C11SW2007 2.23257 MZtDOC 370