RPT ON SPECTRAL IP RESISTIVITY & MAG SURVS FLETT TP · JVX SPECTRAL IP/RESISTIVITY A MAGNETOMETER SURVEYS CONDUCTED ON THE FLETT PROPERTY FLETT TOWNSHIP NORTHEASTERN ONTARIO NTS:

31L13SE2002 2.20895 FLETT 010

REPORTON

JVX SPECTRAL IP/RESISTIVITY A MAGNETOMETER

SURVEYS

CONDUCTED ON THE

FLETT PROPERTY

FLETT TOWNSHIPNORTHEASTERN ONTARIO

NTS: 31 L/13

FOR RANDSBURG INTERNATIONAL GOLD CORPORATION

JVX Ltd.

REPORT

ON

JVX SPECTRAL IP/RESISTIVITY A MAGNETOMETER SURVEYSCONDUCTED ON THE

FLETT PROPERTY

FLETT TOWNSHIP

NORTHEASTERN ONTARIO

NTS: 3 1 L/13

For: Randsburg International Gold Corporation400 Burrard Street, Suite 1400 Vancouver, British Columbia V6C 3G2

Tel: (604)689-8151 Fax: (604)643-1789

Attention: Mr. Stuart Rogers

By: JVX Ltd.60 Wilmot Street West, Unit #22 Richmond Hill, Ontario L4B 1M6 Tel: (905)731-0972 Fax: (905)731-9312 Contact: Blaine Webster

JVXRef: 1-07 February 12, 2001

J VX

31L13SE2002 2 .20895 FLETT 0 10C

TABLE OF CONTENTS

1. INTRODUCTION.....................—.— .......................................................—.—————————I

2. PROPERTYGEOLOGY.............................."...."..........— — — — — —— ..—— -— — —— —— — l

3. SURVEY SPECIFICATIONS AND PRODUCTION SUMMARY...................................——— 2

4. PERSONNEL...................................— ..""..........."...."."........"".".•.•"•.••••"••"•"•"•"•"•"•"•——•• 4

5. FIELD INSTRUMENTATION ......................................."...".........".......———————————5

5.1 I5.2 IP RECEIVER.... ...............................................................••-••••••••••••••••••---•-------••- 5

5.2.7 Pole-Dipole Array... ..............................................••••••••••-••••••••••••-••••-••••••••••••••-•••••••••••- 55.3 MAGNETOMETERS......................................................-....-----— ••••••••••••••••••••••••••••••••-•••••" 5

6. DATA PROCESSING...........— ...— —— .....— — — — — — .....— — — — — — — .— — — — — -76.1 IP/RESISTIVITY ............................................-.-............••••.•.•••••••-•••••••••••••••••••••••••••••••••••••••••••••- 76.2 MAGNETICS....................................................................-.-— -——•—-••——••••-— ••-•- 8

7. INTERPRETATION METHODOLOGY....................".................."".................""""."———— 8

7.1 IP/RESISITIVITY............................— ....— ..............— — •••— -—— -••••••-•"•••••••••••-•••••••••••••" 88. DISCUSSION OF RESULTS ..........................................— —— ——. —— —— ——— —— .-—— — 10

9. SUMMARY AND RECOMMENDATIONS...................................—.———.—————--- 13

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LIST OF FIGURES

Figure l: Location MapFigure 2: Grid Location l C laim Map

LIST OF TABLES

Table 1: Specifications for the Spectral IP/Resistivity Survey................................. .....2Table 2: Specifications for the Magnetometer Survey .................................................2Table 3: Production Summary for the Spectral IP/Resistivity Survey............................ 3Table 4: Production Summary for the Magnetometer Survey ............................... .3

LIST OF APPENDICES

Appendix A: Instrument Specification SheetsAppendix B: "Pole Dipole Array" GeometryAppendix C: Plates

J VX LIST OF PLATES——————————————

Plate l: Compilation map, Scale l: 5000

Plate 2: Chargeability, Resistivity, Spectral M-IP,Tau and "C"Pseudosection, L1625S, Scale 1: 5000



Plate 5: Chargeability, Resistivity, Spectral M-IP, Tau and "C"Pseudosection, L1300S, Scale 1: 5000




Plate 9: Chargeability, Resistivity, Spectral M-IP, Tau and "C"Pseudosection, L900S, Scale l: 5000

Plate 10: Chargeability, Resistivity, Spectral M-IP, Tau and "C"Pseudosection, L800S, Scale l: 5000

Plate 11: Chargeability (0=2) Plan Map, Scale l: 5000Plate 12: Resistivity (11=2) Plan Map, Scale l: 5000Plate 13: Total Field Magnetics Contours Plan Map, Scale l: 5000Plate 14: Residual Magnetics Contours Plan Map, Scale l: 5000

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1. INTRODUCTION

JVX Ltd. conducted Time-Domain Spectral Induced Polarization (IP)TResistivity from February l to 12, 2001 on the Flett Property, Flett Township, on behalf of Randsburg Gold International Corporation. The Flett property is located in the Sudbury Mining Division approximately 60 km north of North Bay in northeastern Ontario. B Zone Grid is located in Dunlop and Shibananing townships approximately 60 km west of Sudbury (N.T.S. 41 1/5). The Ontario Northland Railway passes within 250 metres of the southwest limit of the property. The train from North Bay has a scheduled stop as Bushnell, approximately 6 km southeast of the property. Bost or all-terrain vehicle can provide direct access to the property from Bushnell. Winter access to the property was obtained by travelling south from Temagami along Hwy. 11 for approximately 20 km. And then east along an all-season forestry for approximately 13 km. A series of skidoo trails south from the forestry road provides direct access to the north and western sections of the property. The property location map is shown in Figure l and the grid/claim location map is shown in Figure 2.

The purpose of these surveys was to detect zones that could be favourable for hosting economic Ni-Cu-Co-PGM sulphides.

The Flett Property covers the following claims:

1077207 1077209 1218874 1218875 1218876

1218978 1218979 1218980 1218981

1218984

2. PROPERTY GEOLOGY

The Flett property covers a large portion of the Flett layered mafic-ultramafic complex (hereafter FLC). The layered complex is openly folded and comprised of mafic to ultramafic lithologies including anorthosites, plagioclase-olivine bearing troctolites to feldspathic dunites, and ultramafics.

The FLC i s markedly similar to other mafic (gabbro) - anorthosite-ultramafic layered intrusions recently proven to host PGM rich sulphides and that are situated near the

J VX

1. INTRODUCTION

JVX Ltd. conducted Time-Domain Spectral Induced Polarization (IP)TResistivity from November 23 to December 16, 2000 on the Flett Property, Flett Township, on behalf of Randsburg Gold International Corporation. The Flett property is located in the Sudbury Mining Division approximately 60 km north of North Bay in northeastern Ontario. B Zone Grid is located in Dunlop and Shibananing townships approximately 60 km west of Sudbury (NT. S. 41 1/5). The Ontario Northland Railway passes within 250 metres of the southwest limit of the property. The train from North Bay has a scheduled stop as Bushnell, approximately 6 km southeast of the property. Bost or all-terrain vehicle can provide direct access to the property from Bushnell. Winter access to the property was obtained by travelling south from Temagami along Hwy. 11 for approximately 20 km. And then east along an all-season forestry for approximately 13 km. A series of skidoo trails south from the forestry road provides direct access to the north and western sections of the property. The property location map is shown in Figure l and the grid/claim location map is shown in Figure 2.

The purpose of these surveys was to detect zones that could be favourable for hosting economic Ni-Cu-Co-PGM sulphides.

The Flett Property covers the following claims:

1077207 1077209 1218874 1218875 1218876

1218978 1218979 1218980 1218981 1218983

1218984

2. PROPERTY GEOLOGY

The Flett property covers a large portion of the Flett layered mafic-ultramafic complex (hereafter FLC). The layered complex is openly folded and comprised of mafic to ultramafic lithologies including anorthosites, plagioclase-olivine bearing troctolites to feldspathic dunites, and ultramafics.

The FLC i s markedly similar to other mafic (gabbro) - anorthosite-ultramafic layered intrusions recently proven to host PGM rich sulphides and that are situated near the

SURVEY AREA

Surveyed by JVX Ltd. February 2001

LOCATION MAP RANDSBURG INTERNATIONAL GOLD CORP.

FLEET PROPERTY Fleet Twp., Northeastern Ontario

N.T.S. 31 L/13GROUND GEOPHYSICAL SURVEY

Scale l : 1,600,000

Figure l

GRID 7 CLAIM MAP

RANDttMjnO MTOVtATIONAL OOLD COW.

FLETT PROPERTYIKMP..IIIII ii jam ongo

OROUND OBOPHY8ICAL SURVEYRgurt 2

J VXGrenville Front within a corridor of significant PGM coiicenlialioiis. The ulhei intiusive complexes include the East Bull Lake intrusion approximately 80 km west of Sudbury as well as the River Valley Intrusion located 60 km east of Sudbury. These layered intrusions appear to be emplaced as part of rift-related suite of igneous rocks of Paleo- Proterozoic age. Characteristically the associated base metal abundances are very low with Cu Si Ni rarely exceeding I 07o probably averaging 0.1 to Q.3%.

3. SURVEY SPECIFICATIONS and PRODUCTION SUMMARY

Pole-Dipole Array

TransmitterReceiver

Transmit Cycle TimeReceive Cycle Time

Number of Potential Electrode PairsElectrode Spacing

Station SpacingNumber of Lines Surveyed

HuntecM-472.5kWScintrex IPR-12

2 sec

2 sec

650m50m

9

Table l: Specifications for the Spectral EP/Resistivity Survey

Instrument Sensor Type

Station SpacingNumber of Lines Surveyed

Survey Coverage

Scintrex Envimag A GEM GSM- Proton Precession

12.5m9 lines + l base line

(13900 m + 787.5 m) ^4.7 km

Table 2: Specifications for the Magnetometer Survey

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The production summaries are listed in the following tables:

.. - : ' ',-'i :',*\i,'.::.n--f\!'-? J '.' joil^-W;^:*^- v^to'V^. Avix,-1 - i-Mi.?^^^**

II1511625S1500S1400S1300S1200S1100S1000S900S800STotal

•bwiiaijE^lflifflrateiAftKis50 m dipoles50 m dipoles50 m dipoles50 m dipoles50 m dipoles50 m dipoles50 m dipoles50 m dipoles50 m dipoles

IMMSffit

!a;t!!PliwMl!!i|S:'?;s600 W1350 W.1350 W-1350 W1400 W1400 W1450 W1400 W1400 W

•frr^:SS^,ia-a-ftfi^^xift^^f^''--^''-^ctf^fi,!f''i,ft!if'-"''snv.-^ 'llmî^!iimiieiiaKms^KKiim:-Ai'kKiffMf^^K-^,a*iî^'if' ;lft':iC6';"'!rti:5i;v.:?Stati*)D. . : -'

200 E2000 E'100 E -

750 W150 E

650 W-100 E '

700 W1000 W

'- : '••(in);.': .•'••1

8003350145060015507501550700400

11150

:;'. !iR6iBaiiitgi ;: -1061236259

2582

#169

Table 3: Production Summary for the Spectral IP/Resistivity Survey

1500S1400S1300S1200S1100S1000S900S800S700SBLO

1350 W 1350 W 1350 W 1400 W 1400 W 1450 W 1450 W 1400 W 1400 W 1500 S

2000 E2025 E725 W150 E

675 W150 E

725 W1000W150 E

712.5 S

33503375625155072516007254001550787.5

2692715112459129593312564

146875 1184

Table 4: Production Summary for the Magnetometer Survey

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4. PERSONNEL

John Marsh (Senior Geophysical Technician. Party Chief)Mr. Marsh acted as Party Chief and was responsible for day-to-day field operations and overall data quality. He also generated preliminary field pseudosections of the IP/resistivity data

Ted Lang (Geophysical Technician)Mr. Lang assisted assisted Mr. Marsh with the day-to-day field operations. Mr. Lang alsoperformed the magnetometer surveys

(3) three field assistants were also engaged by JVX.

Dagmar Pi ska Se Vaso Lymberis (DraftspersonsVMs. Piska and Ms. Lymberis assisted with the plots, carried out drafting on thefigures/plates and assembled this report.

John Gilliatt (Senior Geophysicist)Mr. Gilliatt processed, plotted and interpreted the IP/resistivity and magnetics data andwrote this report. He also liaised with the field party chief.

Slaine Webster (President. JVX Ltd.VMr. Webster assisted in the interpretation of the IP/resistivity and magnetics data for thisreport. He also provided overall supervision of the survey.

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5. FIELD INSTRUMENTATION

JVX supplied the geophysical instruments specified in Appendix A.

5.1 IP Transmitter

The Huntec M-4/2.5 kW Time Domain Transmitter powered by an five and one-half- 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 ±0.1 07o for up to 500Xo external load or ± 1007o input voltage variations. Voltage, current and circuit resistance are presented on both analog and digital displays.

5.2 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 in solid-state memory.

5.2.1 Pole-Dipole Array

The pole-dipole survey configuration was used. Typically this array consists of as many as 9 mobile electrodes: one current electrode Ci and as many as eight potential electrodes(Pi to Pg connected to the receiver by means of the "Snake"). The infinity current location C2 was maintained at a large distance from the grid.

The potential electrodes consisted of stainless steel rods to achieve good contact with the ground. Copper piping lowered to the bottom was used to achieve good contact on the frozen lakes.

5.3 Magnetometers

JVX________________________

6. DATA PROCESSING

6.1 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. Initial results were plotted on a* FUJITSU DL 2400 dot-matrix printerThese plots were used to monitor progress and data quality, and were provided to the Client's field representative on a regular basis.

The data were sent by courier or e-mail 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* HEWLETT PACKARD DESIGNJET 350C 24 inch colour plotter* HEWLETT PACKARD 5L Laser printer

The processing procedure is outlined below:1) JVX in-house software was used to spatially reference the time-domain data.

Spectral tait 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 tem),* 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 Package was used to generate colour and black and white pseudosections of chargeability and resistivity data.

3) Plan maps of both chargeability and resistivity data were produced using JVX in- house software and the GEOSOFT MAPPING Package. Additional drafting on these maps was done through AutoCAD.

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6.2 Magnetics

1) Plan maps of the magnetic data were produced using the GEOSOFT Mapping package.

7. INTERPRETATION METHODOLOGY

JVX uses its many years of experience in geophysical interpretation to extract the most accurate information from the data. The procedures involved are simplified for the sake of clarity.

7.1 DP /Resisitivity

The IP and resistivity data are interpreted using the following procedure:

l) Chargeability anomalies are picked on the pseudosections and classified using the following scheme as a guide:

Very Strong O 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 (O 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 location and dipole number of the peak are written beside the anomaly bar.

2) The spectral characteristics of the anomalies are examined. The peak value ofM- IP is noted, and tan is classified according to the following scheme:

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IPR-12/JVX Scheme:

L Long ^10 s)

M Medium (0.5 s to 10s)

S Short (-c 0.5 s)

3) Resistivity anomalies are picked on the pseudosections and classified using the following scheme as a guide:

no symbol VH(n) Very High p 25 000 ohm m) — highly silicified

no symbol H(n) High O l O 000 ohm m) — probably silicified

no symbol WH(n) Weak High ^ 10 000 ohm m) — relative increasecompared to surrounding material

SL(n) Strong Low — strong decrease in resistivity

~~ ~~ ~~ ML(n)Medium Low — medium decrease in resistivity

\VL(n) Weak Low — weak resistivity decrease relative to surrounding material, where n is the dipole number at which the anomaly peak is located.

4) The anomalies from steps l to 3 are marked on the Compilation Map.

5) Zones of high chargeability are interpreted based on resistivity and geometric information.

6) The anomalies are rated according to JVX' past experience.

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8. 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 to a compilation map.

Four (4) main IP anomaly zones were detected by the Spectral IP/resistivity survey. One sub-zone that could be part of IP-1 has also been identified. Four (4) exploration targets have been identified on the compilation map.

The magnetics survey has outlined north-northeast trending magnetic highs. These magnetic zones occur in the western section of the property. Magnetics surveying along line 1500S suggests the eastern sections of the grid are underlain by relatively non magnetic lithologies.

A description of the IP anomaly zones follows:

IP-1

IP-1 represents a broad zone of highly anomalous chargeability responses in the western portion of the grid. The zone is coincident with a broad magnetic high trending to the north-northeast. The zone occurs within the intrusion with the western edge of zone approximately 200 metres east of the contact with the country rocks. Many of the chargeability responses are coincident with resistivity lows and associated with moderate to long lau and high MTPs suggesting that linked sulphide mineralization could be the causative source. Two (2) exploration targets have been identified in this zone.

Anomaly targeting:

T-l: High priority— L1200SMn275WT-l is a very strong chargeability response located in the eastern section of IP-1 on line 1200S. The zone has a strong magnetic correlation that could indicate the presence of magnetite or pyrrhotite. The target is associated with a long tau and high to very high MIP values that would indicate a good probability of coarse-grained mineralization. The target is located on a peninsula in Fanny Lake. The chargeability response is at surface so prospecting can be considered before drilling.

T-2: High priority— L1500MStn625WT-2 is also a very strong chargeability response that is located under Fanny Lake east of a peninsula. The chargeability response coincides with a resistivity low within generally non-resistive units. The peak chargeability response is very near the surface suggesting that water depth in this area is minimal. The IP anomaly is associated with high MIPs and moderate to long taus. Medium to coarse-grain sulphide mineralization is anticipated.

10

J VX____________^^^.^Follow-up dnllmg would have to be conducted in the winter shouldsuggests the zone is dipping eastwards. Modeling of the geophysical data could providesome indication of dip direction and should be considered prior to drilling.

IP-la

IP-la is a weak response located on two lines in the northwest section of Fanny Lake. The zone is associated with elevated resistivities. This could indicate the chargeability response is due to increase resisitivity and not sulphides. The chargeability appears to be increasing to the north so additional coverage in this area would provide additional information on this zone.

IP-2

IP Trend IP-2 is located generally along the baseline between lines 1500 and 1200S. The strongest chargeabilities occur in Fanny Lake near the eastern shoreline. The zone is associated with strong magnetic lineaments and moderate to strong resistivity lows. The zone is only fully defined on line 1500S as only partial coverage is available on lines 1400 through 700S. One exploration target is identified.

T-3: High priority—LI 500SMn2SET-3 i s a very strong chargeability response located immediately east of the baseline on line 1500S in Fanny Lake. The chargeability response is coincident with a broad resistivity low and associated with moderate to high MIPs and long tau. These features could indicate a conductive body is the causative source. A strong magnetic high is flanking the target to the west. The chargeability zone is located within the FLC. Follow-up drilling of this target should be considered. Extending survey coverage to the north could outline the zone nearer the shoreline allowing for drilling from land. Follow- up electromagnetic surveys (i.e. horizontal-loop surveys) should be considered as well.

IP-3

IP-3 consists of two (2) moderate chargeability responses on line 1500S between 900 and 1150E. The westernmost IP response is coincident with a resistivity low and is flanked to the west by a resisitivity high. Both zones are associated with MIP values below 300 mV/V. Values above 300 mV/V usually indicate that some sulphides are present. In addition, this zone appears to be located outside of the intrusion. Prospecting and geochemical analysis of the zone should be considered.

IP-4

11

J VX—LP-4 is located near the eastern limit of line 1500S within a wedge uf llie FLC. T wu———

strong chargeability zones are observed associated with high MIPs and short time constants. A resistivity low that could represent a shear zone separates the two IP zones.

Anomaly Targeting:

T-4: High priority—LISOOS/Stn 1575ET-4 is a strong chargeability response with the peak value occurring at the surface west of a low resistivity zone. The peak MIP value is above 600 mV/V with tau values generally less than 0. l sec. This represents a good target for fine-grained sulphide mineralization. This zone occurs on land so prospecting should be completed prior to drilling.

12

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9. SUMMARY And RECOMMENDATIONS

The Spectral/IP resistivity surveys have successfully outlined numerous chargeability zones with many exhibiting strong to very strong responses. Two (2) of the zones have a strong correlation with magnetic high trends.

A total of four (4) exploration targets were selected based on the results. All targets are considered as high priority for follow-up drilling. Targets T-l and T-4 occur on land allowing for prospecting prior to drilling. Prospecting in vicinity of T-l should determine if the source of the anomalous response is sulphides or magnetite as a strong magnetic high is associated with this zone. T-2 and T-3 are located in Fanny Lake and therefore drilling would be necessary. Additional survey lines north and south of these zones may trace the IP zone onto land where prospecting can be conducted prior to drilling.

If there are questions with regard to the survey please call the undersigned.

Respectfully submitted, JVX Ltd.

John Gilliatt Senior Geophysicist

13

APPENDIX A

and Commutated DC Resistivity Transmitter System

Function

f 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 in case o) 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 pots, simulator circuit, copper sulphate. IPR-8 receiver, dummy load, transmitter, electrodes and clips.

IPC-7/2 5kW transmitter console with lid and dummy load

T T

T T T T

Time Domain Waveform

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 = 2 ,4 or 8 seconds, switchselectableOptional: T = 1 ,2,4 or 8 seconds, switchselectableOptional: T zz 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"C to -t-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 95 V

280 mm x 460 mm x 310 mm

30 kg

41 kg includes reusable wooden crate

Motor Generator

Maximum Output Power 2.5 kVA, single phase

Output Voltage

Output Frequency

Motor

Weight

Shipping Weight

110 V AC

400 H z

4 stroke, 8 HP Briggs X Stratton

59kg

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 volt range. Automatic linear correction operating on a cycle by cycle basis.

Input Voltage (Vp) RangeSOpvoltto 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 "/o

Common Mode RejectionAt input more than 100db

Vp Integration Time100Xo to 800A 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 Test All dipoles are measured individually in sequence, using a 10 Hz square wave. The range is O to 2 Mohm with 0.1 kohm 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 30.28 mV/V of M.

Analog MeterFor monitoring input signals; switchable to any 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 tor 110/230V, 50 to 60 Hz, 10W. More than 20 hours service at -t-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 BatteriesCan 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 *50'C

Storage Temperature Range-30'C to -nSO'C

DimensionsConsote:355 x 270 x 165 mm Charger: 1 20 x 95 x 55mm

WeightsConsole: 5 .8 kgStandard or Ancillary RechargeableBatteries: 1 .3 kgCharger: l A kg

Transmitters available l PC-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

IPR-12/94

Tel.: (905) 669-2280 Fax: (905) 669-6403 Telex: (905) 06-964570

Tel.: (716)298-1219 Fax: (716)298-1317

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 calk 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

HHHDIHHilHJHi

Specifications

PerformanceResolution: O.OlnT Relative Sensitivity: 0.2nT Absolute Accuracy: InT Range: 20,000 to 120,OOOnT Gradient Tolerance: Over V.OOOnT/m Operating Temperature: -40"C 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 ... 350-170-0063 Analog Output............ 350-170-0040Remote Option ..... .... . . 350-170-0043

85 Product Catalog, Vol. 4, Number 1 Terraplus: Sales, Rentals, Training, and Repair Service

ENVIGEOPHYSICALS2SIEM,Total Field Operating Range20,000 lo 100,000 nT (gammas)

Total Field Absolute Accuracy:±1 nT

Sensitivity:0. l nT at 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, 172m (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-deflned 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 readingsGradiometer Measurements: 109,000 readingsBase Station Measurements: 750,000 readingsVLF 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 to 57,600 Baud, 7 or 8 data bits, I 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 Ah, Lead-acid battery 12 Volts at 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 Volt, 50/60 Hz

Operating Temperature RangeStandard: -40* to 60'C

Dimensions S 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"dx7"l kg (2.2 Ibs) (sensor)

Gradiometer sensor and staff extender: 70mm x 675mm

2.75"d x 26.5"1.15 kg (2.5 Ibs) (sensor)

T.F. staff: 25mm x 2mI"dx76".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)

SCIIMTREXHead Office222 Snidercroft Road, Concord, Ontario, Canada L4K. l B5Tel.: (905) 669-2280 - Fax: (905) 669-6403 ' Telex: 06-964570In the U.S.A.525 Fort Worth Drive, Suite 216, Denton, Texas U.S.A. 76201Tel.: (817) 591-7755 * Fax: (817) 591-1968In Australia1031 Wellington St., West Perth, West Australia 6005Tel.: (619) 321-6934 - Fax: (619) 481-1201

APPENDIX B

Cj,

Ci i1 r r r r tno—————*-U~ a i'* c t 't a *ia a - t '* a —JU- q

Apparent Resistivity:

ARRAY GEOMETRY

^ 2tr na(nH-l) Vp/I

where /'a ^ apparent resitivity (ohm.ra)n = dipole number (dimensionless)a = d ipole spacing (m)Vp - primary voltage (mV)I ^ primary current (raA)

Pole-Dipole Array Array Geometry and Formula for Apparent Resistivity

APPENDIX C

?) Ontario {J \J\ I LCII IU .od***.Declaration of Assessment Work Performed on Mining LandMining Act, Subsection M(2) and 66(3), R.S.0. 1890

Transaction Number (office use)

. Q'O03(0.Asseasment Files Research Imaging

itlons 65(2) and 66(3) of the Mining Act. Under section 8 of the Mining Act, work and correspond with the mining land holder. Questions about this coKec and Mines, 3rd Floor, 033 Ramsey Lake Road, Sudbury, Ontario, P3E BBS.

31L13SE2002 2.20895 FLETT 900[ructions: - For work performed on Crown Lands before recording a claim, use form 0240.

- Please type or print in ink. '

Recorded holder(s) (Attach a list if necessary)O,

Lu. { AClient Number

Ires*'/MOO ~ 4*5X2

Telephone Number

VCC Fax Number

ne Client Number

Ires* Telephone Number

Fax Number

Type of work performed: Check (S) and report on only ONE of the following groups for this declaration.Geotechnical: prospecting, surveys, assays and work under section 1 8 (regs)

*kType

e* Work From - formed "2^ Day

ZrPi r\J ooo l To| Month | YMT

ibal Positioning System Data (If available) Township/ Area

D

Day

Physical: drilling stripping, trenching and associated assays

y| Month | Year .200}

^lê-HrMorO-PlanNumber

DOffice

Rehabilitation

UseCommodityTotal S Value of Work Claimed 46. q(o4NTS Reference

Mining DivisionResident Geologist District c

S(JK

Duud

IbuiOLJ

bijLtfi/lease remember to: - obtain a work permit from the Ministry of Natural Resources as required;

- provide proper notice to surface rights holders before starting work;- complete and attach a Statement of Costs, form 0212;- provide a map showing contiguous mining lands that are linked for assigning work;- include two copies of your technical report.

, Person orsme ^^

""" t,o\

companies who prepared the technical report (Attach a list if necessary)

/ X Lrhrf4 j^ -4- l i ' l -rf C4--^"9o ft^^f^**^- HUh ^CS\ \sJ\ l VW i* ^T f* jL L oKTTftlfl'O L^fi /Plfo

ame

ddress

ame

ddresa

Telephone Number

Fax Number CtOS'~*73i'" Q3(7^-

Telephone Number '

Fax Number

Telephone Number

Fax Number

. Certification by Recorded Holder or Agent 'A7 iVe^/A/i e^ l C5 ps* v"**-' - do hereby certify that l have personal knowledge of the facts set forth in

ills Declaration of Assessment Work having caused the work to be performed or witnessed the same during or after Its completion and, to the best of my knowledge, the annexed report Is true.iignature of Recorded Holder or Agent

Kgent's Addre Telephone

RECEIVEDFEB 1 3 2001

HEOSCJFWCF ASSES5MEKT OFFICE______.

O 416 488 8473 GENES IS- 03x87^01

MM. wofk mWr

COlUITindfe

egeg•a12

3

4

S

t

J

t

8

10

11

12

13

14

IS

ig CUlm Number. Or V we* don* en other etgWe ig lend, enow In thle in the location number ited on Ira diirn imp.

TB7*Z7

123*567

1234S66

L2l*ftl7^L2-A^1"?9

(i. i S ^7617.1 3379T([0-1 a8"rV

Column Tot*U

Number of Claim Unit*. For other mMrv tend, let hectare*

IB ra

12

ttli-

Mel 610

t?

Value or work pet formed on (Me cMmorattwr

S2e.*2S0

1 9,882

2.6-75- l

G~0( kUl icr

Q

33^1^

'•* JtawS* laMTA 'JMvn*crte**uVelue of wMk eppliedtoMi

MM

*24,000

S 4,000

0O

feôofe*HO^

3S*oi

1^3 07 .

Value or Work •eelgned lo other

(24.000

0

0

IH&3&OoeO

/Mt3*4

Bank. Valued went tobedlslrtiuled •le Mure del*

13.125

0

KM2

-lz||S- ?o(fe

oo0

"

17131^3E_____. do hereby certify that the above work credits are eligible und

subsection 7 (1) of the Assessment Work Regulation 6/96 for assignment to contiguous claims or for application to the claim where the work was done.

7* 100 f

6. Instructions far cutting back credits that are not approved."7*0.

Some of the credits claimed in this declaration may be cut back. Please check ("O hi the boxes below to show how you wish i prioritize the deletion of credits:

D 1 . Credits are to be cut back from the Bank first, followed by option 2 or 3 or 4 as indicated.Q 2. Credits are to be cut back starting with the claims listed last, working backwards: orD 3. Credits are to be cut back equally over all claims listed in this declaration; orD 4. Credits are to be cut back as prioritized on the attached appendix or as follows (describe):

Note: If you have not Indicated how your credits are to be deleted, credits will be cut back from the Bank first, followed by option number 2 If necessary. ___ ______ ^^

For Office Use Only___________,^——^— Recctvttl Sump D*tmed Approvtd 0*1*

Dal* Approved

Dan Notification S*rt

Told VHu* of Cndl Approved

Approved for Recording by Mining Recorder (Slgnelure)

RECEIVEDMAR o 7:::;

QEOSCIENCE ASSESSMENT _____OFFICE-———1.

MflR 07 '01 14:416 488 0473 PflGE.06

For Office Use OnlyReceived Stamp

0341 (OM7)

Deemed Approved Date

Date Approved

Date Notification Sent

Total Value of Credit Approved

Approved for Recording by Mining Recorder (Signature)

Ontario Ministry ofNorthern Developmentand Mines

Statement of Costs for Assessment Credit

Transaction Number (office use)

ljJOnQ.000.3G)

jrsonal information collected on this form Is obtained under the authority of subsection 6(1) of the Assessment Work Regulation 6/96. Under - •ctlon 8 of the Mining Act, the Information Is a public record. This Information will be used to review the assessment work and correspond with e mining land holder. Questions about this collection should be directed to the Chief Mining Recorder. Ministry of Northern Development and Ines. 6th Floor, 933 Ramsey Lake Road, Sudbury, Ontario, P3E 6B5.

Work TypeUnits of Work

Depending on the type ol work, list the number of hours/days worked, metres of drilling, kilo metres of grid line, number of samples, etc.

Cost Per Unit of work

Total Cost

Associated Costs (e.g. supplies, mobilization and demobilization).

Transportation Costs

Food and Lodging Costs

Total Value of Assessment Work

Calculations of Filing Discounts:

1. Work filed within two years of performance is claimed at 1000Xo of the above Total Value of Assessment Work.2. If work is filed after two years and up to five years after performance, it can only be claimed at SOW of the Total

Value of Assessment Work. If this situation applies to your claims, use the calculation below:

TOTAL VALUE OF ASSESSMENT WORK x 0 .50 Total S value of worked claimed.

Note:- Work older than 5 years is not eligible tor credit. - A recorded holder may be required to verify expenditures claimed in request for verification and/or correction/clarification. If verification anc Minister may reject all or part of the assessment work submitted.

Certification verifying costs:

oPcoTTOTflonAjlarmCafjoi

—— FED 1 3 2001 ——

GEOSCIENCE ASSESSMENT nfnee

ithin 45 days of a is not made, the

l, r rjig- 1 , do hereby certify, that the amounts shown are as accurate as may(please print lull narnp)

reasonably be determined and the costs were incurred while conducting assessment work on the lands indicated on

the accompanying Declaration of Work form as

to make this certification.

(recorded holder, agent, or slat* company position with signing authority)l am authorized

nature Date

OntarioMinistry of Ministere duNorthern Development Developpement du Nordand Mines et des Mines

Geoscience Assessment Office 933 Ramsey Lake Road

April 17, 2001 6th FloorSudbury, Ontario

RANDSBURG INTERNATIONAL GOLD CORP. P3E 6B5SUITE 1400 - 400 BURRARD STREETVANCOUVER, BC Telephone: (888) 415-9845V6C-3G2 Fax: (877)670-1555

Visit our website at: www.gov.on.ca/MNDM/MINES/LANDS/mlsmnpge.htm

Dear Sir or Madam: Submission Number: 2 .20895

Status Subject: Transaction Number(s): W0170.00036 Approval After Notice

We have reviewed your Assessment Work submission with the above noted Transaction Number(s). The attached summary page(s) indicate the results of the review. WE RECOMMEND YOU READ THIS SUMMARY FOR THE DETAILS PERTAINING TO YOUR ASSESSMENT WORK.

If the status for a transaction is a 45 Day Notice, the summary will outline the reasons for the notice, and any steps you can take to remedy deficiencies. The 90-day deemed approval provision, subsection 6(7) of the Assessment Work Regulation, will no longer be in effect for assessment work which has received a 45 Day Notice. Allowable changes to your credit distribution can be made by contacting the Geoscience Assessment Office within this 45 Day period, otherwise assessment credit will be cut back and distributed as outlined in Section #6 of the Declaration of Assessment work form.

Please note any revisions must be submitted in DUPLICATE to the Geoscience Assessment Office, by the response date on the summary.

If you have any questions regarding this correspondence, please contact BRUCE GATES by e-mail at [email protected] or by telephone at (705) 670-5856.

Yours sincerely,

ORIGINAL SIGNED BYLucille JeromeActing Supervisor, Geoscience Assessment OfficeMining Lands Section

Correspondence ID: 15857

Copy for: Assessment Library

Work Report Assessment Results

Submission Number: 2 .20895

Date Correspondence Sent: April 17, 2001 Assessor: BRUCE GATES

First Claim Number1218978

Township(s) / Area(s)FLETT

StatusApproval After Notice

Approval DateApril 14, 2001

Transaction NumberW0170.00036

Section:14 Geophysical IP 14 Geophysical MAG

The revisions outlined in the Notice dated February 28, 2001 have been corrected. Accordingly, assessment work credit has been approved as outlined on the AMENDED Declaration of Assessment Work Form accompanying this submission.

Correspondence to:Resident Geologist Sudbury, ON

Assessment Files Library Sudbury, ON

Recorded Holder(s) and/or Agent(s):Michael OparaTORONTO, ONTARIO, CANADA

RANDSBURG INTERNATIONAL GOLD CORP. VANCOUVER, BC

Page: 1Correspondence ID: 15857

31L13SE2002 2 .20895 FLETT 200Ml HIS FRY OFNORTHERN DFVFI UPMFNIt,HD M INES

PnOVINCUI UINING

RECORDER'S OFFICE

MINING LAND TENURE

MAP

Thnm unthlng In ttak*mliilngrlalms ihauld rairimulri^lhih.prnvlnctel Mlntig Recorder!'OfflcD ollhi MlMitry nf Hnrltiirn DwKopmnTtntri MmotToradaikuial Uifnrmimon onthectatui nl m n Innd* shorn hereon. r bs map.is nnl mlendedrai.niwMialjonnl, survey, or land trtlottAloirniiHian.purposes aslhninlarmjilian.shawi.nn ttM*map isrempiled frn m various sources. CumplnlBnaiiviHid accuracy ara not fluarantead. Addilionit infoimillgn m^.^vitbfi nbtuitiiKl thrutighthe laca) Lands TittaBDr Reaiatry Office, ui tha Mlnnliy of H aim di RubOuiuit.

Ihi: nrurinvtion shown Is derived hem diBHaLdala avalabla in the Provincial Ulnng HHLDrdeis'Onlc* anhatjma nr doivnlnfidlne rrrirn.thaMlnkBliv.ofNoriham.DevitlapinaHtatid Mbiiia WRD.SM.

General.Information and LimitationsCuntacl InforrndtiorcPrnvinr.ini Unirw Racnrd ms'OffJnt T oH FiveWttetGraenMIIUi Cwito Fat 1 |B8U)411 Mil',fVinnnneylaHBRoijil Fax: 1(877)670 1444Sudbuy, ON P3L aH5Homo Pane-wvi.OUV.onxa.HHDMMIHESlLlllOStnliimrtiiJB Mm

MapOCum: NAD 63l*ro|ectmnc u [M (6 depree)1opva)aoliK Pala Sourcn: Land hitormauun OnlaroMintig L and Tanurn SnurtB:.Provlnrl]il Mining Rncorden' Orrlce

Ihbt mjp.mav.nal sham unrB^lsTarM Imd tanivq iwid inlsrRBts hi Ijrd In rhidlng csrtatn patents, leases, oasements..right at wnvs^ttaaitmflfiarilx, licenses,.nr.ntherfnrms ut drsnuEiltoD ot r tehls and InlirHl hom Cha Ci ovn. *|KJ tut Bin bind tanum --m J land uses that marirt or prnWul trm entiy lo stake mlninj claims mar, not be illustrated.

Date ,f Time of Issue Apr 17 2001

TOWNSHIP/AREA

FLETT

11:32h Eastern

PLAN

G-1711

ADMINISTRATIVE DISTRICTS 7 DIVISIONS

Mining Division Sudbury Land Titles/Registry Division NIPISSING

Ministry of Natural Resources District NORTH BAY

TOPOGRAPHIC

Administrative Boundar

FtovnsJi p

LAND TENURE

HrjchoW I'Jttt*

1*1 -jurlace And Mining Wi

^jj W l^ln 3 Rights Onfe

natural. Âft Ppalmg

MyorO Lifio

CotTi m undation. Line

i hi on 2 Cuiilrul

J7, urm:^ Ariij Mining R ighls

J3j Surface R i.ghls Or v

ty M run B Night? Only

LJoncB of Occirp al Inn

LJ use* not Spfrciilcd

l^J Surlacs Anct Mminfl Rl^hli

llj SurfocB Highls Only

^J yrifig Riahts Qr,^

FI L.ndU.*f™*

J^J Order In. CauncJI

IJ^J Water PO-iMSr Lease Aggreeirtfnt

t

l Mining C lalfn

LAND TENURE WITHDRAWALS

i.frttiii Dicposrtion r.T*^ h/pe*

SijrfaOK^did Wining Rigtili. Wilhdra rr\ Surf i'? i R iyHs, Orli, W t^JiiwiMining H i^hrl* Onlr.VVJihdnvun

Order In C ouncU UHlhdrawal Typo* 5ur'|-*4nd Mining nigr-t* wilhdriwi 9ui f.o* Righls Only 'iV lhdr*ivr, Mirvrg BlgM* flnij W'Hhorav-r

IMPORTANT NOTICES

LAND TENURE WITHDRAWAL DESCRIPTIONS

IMPORTANT NOTICESflma undn iHiich tplclH rgeulMloni, limitations or HindHKini flcutthal *9O normal prmpamng,

and mliwr^ development jcthritlat.

800E 900E 1000E 1100E 1200E 1300E 1400E1600W 1500W 1400W 300W 1200W 1600E 1700E 1800E 1900E 2000E 2100ElOOW 1000W

72X8980

,rm i i i 11

H(2) - High Reasfivtty, 11=2 VH{1) - Vwy High Resistivity, 11=1

- w to f I' s . ^" ' ' x- T 'rTT/.j-ij.j.LUjTTT'ftrm.i \ i. ~* ;S- t- c . . x. ;

TfTTfTI l l l l M l l l l

Resistivity High (4000-10,000 ohm-m)

i i /rrrn MM f\i

T* l Exploration Target

HP High Prioritycrn Turner* flT.Trn i i i i i.-HH

727887672789792789782-20395

Scale 1:5000O 100 200800E 900E lOOOE 1600E 1700E 1800E 1900E 2000E 2100E

Fanny Lake

Fanny Lake RANDSBURG INTERNATIONAL GOLD CORP

FLETT PROPERTYFLETT TWP., NORTHEASTERN ONTARIO

NTS 31 L/13COMPILATION MAP

JVX Ltd., ref. 1-07, FEBRUARY 200131L13SE2002 2.20895 FLETT

JVX Spectral 'c' (dimensionlese)

JVX Spectral Tau(s)

JVX Spectral MIP(mV/V)

l j t l L

5+00 f 4+00 f 3+00 W 2+flOW 1+00 f 0+00H————i————l

0.20

&+OOW 4+00 f 3+00 W 2+00 ff 1+00 TT 0+00———l————,————i————i————j————,————i

4+00 W 3+00 W 2+00 If 1+00 f 0+00

I p ~ IP - 2

MX Chargeability(mV/V, 890m8-1050ma) 11=6019^=100

5+00 W 4+00 W 3+00 W 2+00 W 1+00 1 0+0011=4 11=2

11=579^=10

Apparent Resistivity(ohm— m)

5+OOT 4+00 f 3+00 W 2+00 W 1+00 f 0+00

84 1838, ,

3644 30S4 AMI 3*15

^ttfl^ 401 J 1 823

' syoi 2240

ZB75 2830- 34

221

JVX Spectral 'c'(dimensionless)

JVX Spectral Tau(9)

JVX Spectral MIP (mV/V)

MX Chargeability (mV/V, 690ms-1050ms)

Apparent Resistivity (ohm—m)

50

Line 1625 S

Pole-Dipole Arrayaa a

a = 50.0 M

plot point

Resistivity and ChargeabilityAnomalies

"'••••••••••Very strong

—————— ......... strong

——— — - .........Medium

— ---- - ••••••••Weak

................. Very weak

xxxx xxxx------'--Extremely weak

Scale 1:500050 100 150 200 250 300"•C

(meters)

Plate 2

RANDSBURG INTERNATIONAL GOLD CORP.JVX SPECTRAL IP/RES SURVEY

FLETT PROPERTY NORTHEASTERN ONTARIO, NTS:31 L/13

Line 1 625 S01/02/12

Ex (2 sec): Scintrex IPR18. Tx ( 2 sec): Huntec M-4JVX ltd. re/, no. 1 -07. FEBRUARY 2001

31L13SE2002 2.20895 FLETT 220

JVX Spectral 'c' (dimensionless)

JVX Spectral Tau(s)


MX Chargeability(mV/V, 690ms-1050ms)

Apparent Resistivity(ohm—m)

31L13SE2002 2.20895 FLETT

T———l——————l———l———l———l———T

l i i i i i l___L j l l l l l l ! j l l j l i l l l l l l l l l i i . l l l J } l l j l .L l l l t l l

Lake / S T a m p Lake / S wamp Lake

13400 W 12+00 IT 11+00 f 10+00 T 9+00 W 8+00 W 7+00 IT 6+00 f 5+00 W 4+00 f 3+00 f 2+00 f 1+00 f 0+00 1+00 E 2+00 E 3+00 E 4+00 E 5+00 E 6+00 E 7+00 E 8+00 E 9+00 E 10+00 E 11+00 E 12+00 E 13+00 E 14+00 E 15+00 E 16+00 E 17+00 E 18+00 E

0.^0 0,30 0*20 O .-Sfi^ÔAO^' 0 .^0

\20 !k2Q /""H^Sl ~"bTio\ &30 OjS6 6)20

^x o.

0.10 0.10

(0.30O D.JO 0.10

ftrBO vO.40__Otlfl -Or20 \X?^*^--'9'^0 l ^30 v5^10 --'N^^^^/ VX — ^r

*-2V~^-~^S 0.20 0.^ QJStJ \

^0?S^ ^ 0120 tfc!ao

13+00 W 12+00 W 11+001 10+00 f 9+00 W 8+00 W 7+00 T a+OOW 5+00 f 4+00 TT 3+00 f 2+00 W 1+00 W 0+00 1+00 E 2+00 E 3+OOE 4+00 E 5+00 E 6+OOE 7+00 E 6+OOE 9+00 K 10+00 E 11+00 E 12+00 E 13+00 E 14+00 E 15+00 E 1B+QOE 17+00 E 16+00 E

13+00 W 12+00 f 11+00 f 10+001 9+OOW 8+00 W 7+001 a+oow 5+00 w 4+00 W 3+00 f 2+00 f 1+00 W 0+00 1+00 E 2+00 E 3+OOE 4+00 E 5+00 E 6+OOE 7+00 E 8+00 E 9+OOE 10+00 E 11+00 E 12+00 E 13+00 E 14+00 E 15+00 E 16+00 K 17+00 E Ifl+OOE

B l 72.5s X 238.6 24B - S "ff*'* 7tt4/^- \

iS^,4 i Je.Qv 26^.4 *asL)J\sup7dzxz-\ iJer\ 185.X 107.9, 183.8 179,

13+00 W 13+00 W

20. B

13+00 W 12+00 W 11+00 W

Near conductor

10+00 f fl+00 W

-Broad Resistivity Low -

8+00 f 7+00 W e+oow 5+00 W 4+00 W 3+00 W 2+00 W

EM Conductor

1+00 W 0+00

Conductor

1+00 E 3+00 E

Geological contact

3+OOE 4+00 E 5+OQE 6+OOE 7+00 EShear zone

13+00 E 14+00 E

4 Shear zone

17+00 E 18+00 E

9ft, vs8Q52^ 8420

2073 igra^^-Mdo y i139*6 9682 xl 8097 y 11599

7Z5B, 16393X 11808 13392

191

2122

706 3197

2791

2422 2440 ±2yf 279

2024 1529 2966

4922 28B3 24S2 1 334

^4047 3333 3261, 2E65^TTT7^\ 21

997 3554 J8B51 l3W\Jl1El 4742

98 1335 '

4225 y37^-~3*

2(/ 410J11516^8023 13332 995

TDO^Sdie 7952 72541 ~ 4176 3161 6973 65S7 ^6678

JVX Spectral 'c'(dimenaionless)

JVX Spectral Tau(s)



Apparent Resistivity(ohm-m)

Line 1500 S

Pole-Dipole Arraya na

a = 50.0 M

plot point

Resistivity and Chargeability Anomalies

•Very strong

Strong

Medium

•Weak

•Very weak

xxxx xxxx - - - - - Extremely weak

50Scale 1:5000

50 __100 150 200 350 300^H_______

(meters)

Plate 3RANDSBURG INTERNATIONAL GOLD CORP.

JVX SPECTRAL IP/RES SURVEYFLETT TWP. PROPERTY

NORTHEASTERN ONTARIO. NTS;31 L/13line 1500 S

01/02/07 Rx (2 sec): Scintrex IPR12, Tx (2 sec): Huntec M-4

JVX Ltd. re/, no. 1 -07, FEBRUARY 2001230

JVX Spectral 'c'(dimeneionless)

JVX Spectral Tau



Apparent Resistivity (ohm-m)

31L13SE2002 2.20895 FLETT

19+001 12+001 11+001 SHOOT 8+001 7+00 W 6+00 IF 5+00 f 4+00 T 3+001 2+00 W 1+00 W

0.30

0.30

1&+OOI 12+001 ll+OOW 10+001 9+001 8+001 7+001 6+ODW 5+001 4+001 3+001 2+001 1+OOW

\i

IJ+OOl 12+00 l 11+001 10+001 9+001 8+001 7+Oflf fl+ooir 5+001 4+00 W 3+00 l 2+001•••••l- - - -H———i———l———i———l———i———l———i-

40.0

S', B

13+001 12+001 11+00 l 10+00 l

1,6 1.5 1.3 1.1 t.O 0.

1.7 1.3 l.ar 0,2

Z.2\ 1 .5 1.3 l 0 .4 O.

1.8 1.5 /0.7 0.4

1.8 l.fll 0.8 0.3

1.3 l7i^ 0.7 0.1

Conductor

12+001 11+001 10+001 9+001 a+ooi 7+001 6+001 5+001 4+001

2407 1832—— ,

4302

~H(6)

tO -1394 J875 2786

JBO \302

2303 \1244 1073 1379

1=1"3+001-1- -'^-i——-~ 2+001

2339 1689 2264 2022

3774^^8878 15*i 1369 2538

3 1956\ 1187 90 18:

2548 17fl3v 1136 1315

aWjK()53E——-OOOB ' 4617^

6 J 79


JVX Spectral Tau




240

50

Line 1400 S

Pole-Dipole Arraya aa

a = 50.0 M

plot point


Very strong

-Strong

- Medium

Weak

-Very weak

xxxx xxxx-"--- ••••Extremely weak

Scale 1:500050 100 150 200 250 300

•dL b. (meters)

Plate 4



Line 1400 S01/02/12

Rx (2 sec): Scintrex IPR12. Tx (2 sec): Huntec M-4JVX Ltd. ref. no. 1-07, FEBRUARY 2001


JVX Spectral Tau00


MX Chargeability {mV/V, 690ms- 1050ms)


13+00 f 12+00 f 11+00 f 10+00 W H-00 f

0.20

0.20 0.20

moot 12+oow ii+oow lo+oow SHOOT

0.03

(JX(3 0/03

0733

moot 12+00 f i i+oo w 10+00 f

13+00 T 12+00 f 11+00 W 10+00 W

-JiO 0.9 j

1.3 LIN O.B -lo.l

i.e i.oi.e 1.3 1.2'

moo i 12+00 wH———i———l— 11+00 W——f— Ji l — J- Jfc. .n^J

2281 2434 2745 lOB* 2482

""3433 34?V 2197 Sitfl

4O05 Ee^r 4149 4H8J4 1312-

3341 4B3S—x*698 181r \

9+00 ir

IP~ iw-oow

JVX Spectral 'c'(dimension! ess)

jvx Spectral Tau


MX Chargeability, 690ms-1050ms)

10+00 W 9+00 fL-J., J

H(6)Apparent Resistivity

(fihm—in)

Line 1300 S

Pole-Dipole Arraya na a

x x a = 50.0 M

plot point


xxxx xxxx-

Very strong

•Strong

•Medium

Weak

• Very weak

•Extremely weak

31L13SE2002 2.20895 FLETT 250

Scale 1:500050 O 50 1 00 150 200 250 300^•*-"-a

(meters)

Plate 5


FLETT PROPERTY NORTHEASTERN ONTARIO. NTS:31 L/13

Line 1300 S01/02/12

Rx (2 sec): Scintrex IPR12, Tx (2 sec): Huntec M-4JVX Ltd. ret. no. 1-07, FEBRUARY 2001


JVX Spectral Tau(s)


MX Chargeability(mV/V, 690ms-l050ms)


l l l l l l l l l l l 1. ..-I——L-.... l lShoreline Top of

hill

l l i l l

Shoreline Shoreline

l l l l l l l l -l . L . l . i l l————————l————l————l————l————l————————l————l————l————i————l————L.

Lake

13+00 f 12+00 W 11+00 W 10+00 f 9+00 f 8+00 f 7+00 f 6+00 W &+OOW 3+OOW 2+00 W i+oo ir o+oo

13+00 W 12+00 f 11+00 W 10+00 T 9+00? B+OOW 7+00 W 8+001 5+00 f 4+00 f 3+00 ff 2+00 W 1+00 f——l——l——1- 0+00

O.OT——0.03

13+ODff | 12+00 f 11+00 ff 10+00 ff 9+00 ff 8+00 ff———H————i————1————i————h————————l————i————l————p————l————i————*————*-

7+00 W 6+00 f &+OOW 4+00 f 3+00 ff 2+00 f i+oo ir 0+00

19.5

I P - 2

0+00

0.8 0.* 0.1^ J.I 0.6

O 0.7 0.8 0.4 0.

Z.4 j 1.7 1.2

2 fi 1 .4

l.B 1.4 1.3 1.4 1.3 1.5

1.7 1.3 1.5 ^.3 ^ 1.8


JVX Spectral Tau


MX Chargeability(mV/V. 690ms-1050ms)

13+00 W 12+00 w 11+00 ir 10+00 W 9+00 f 8+00 W fr+001 4+00 ff 3+00 ff 1+00 f 0+00 Apparent Resistivity(ohm—m)

120

31L13SE2002 2.20895 FLETT 260

Line 1200 S

Pole-Dipole Arrayna

a = 50.0 M

plot point


Very strong

•Strong

Medium

Weak

-Very weak

xxxx xxxx- . -.... -. -Extremely weak

50Scale 1:5000

50 100 150 200 250 300"S." bd (meters)

Plate 6



line 1200 S01/02/11

Rx (2 sec): Sciatrex IPR12, Tx (2 sec): Huntec M-4 JVX Ltd. ret. no. 1-07, FEBRUARY 2001


JVX Spectral Tau




31L13SE2002 2.20895 FLETT

l l l l l i l l I.I l l l II

13+00 W 12+00 f utm w 10+00 w 9+00 w e+oof

O.BO QrtO

^-9r3D O RO SÔ

0130 /~ O4^ \ O.-CT 0)20 0.20

13+00 W 12+00 f 11+00 W 10+00 W &+OQ I 8+00 W

0.&L-

13+00 f 12+00 W 11+00 W——t——i——i—•"*" —^——'——\——'——i——'——h- 10+00 W 9+00 ir B+OOf

43.4

231.6

IP - la IP -13+00 f 12+00 WL - i--A,-.j--^——i——i——'——^

13+00 f 12+00 f 11+00 W—l - , Jl ~ f ,1=110+00 H 9+00 W B+OO f'n(6) L----Liitr J

ase*-—was ieae -.ata 4806 Naesa aaei

4383 34YZ 1547 180:

2130 2117 1617

2769 l\ 3540 ' 240B 1841


JVX Spectral Tau


11+00 W 10+00 W 9+00 f B+OO W MX Chargeability (mV/V, eflOms-1050ms)


Line 1100 S

Pole-Dipole Arraya na a

I±La = 50.0 M

plot point


' Very strong

•Strong

•Medium

Weak

•Very weak

xxxx xxxx.... - - - - - -Extremely -weak

50Scale 1:5000

50 100 150 200 250 300iB" I- (meters)

Plate 7

RANDSBUKG INTERNATIONAL GOLD CORP.JVX SPECTRAL IP/RES SURVEY


line 1100 S01/02/12

Rx (2 sec): Scintrex 1PR12, Tx (2 sec): Huntec M-4JVX Ltd, re/, no. 1-07, FEBRUARY 2001

270


JVX Spectral Tau




l l l l t l l l l l l l l t l l l l l l l l l — l l

Lake South of Hand Lake Cliff Shoreline

144001 13+00 W 12+00 W 11+00 W 10+00 W 9+00 W a+oow 7+00 W 6+001 5+00 TT 4+00 W 3+00 Wl ——— l ——— l 2+00* 1+00 f

s——~v v ^^-—mO.EO [ 0,10\ 0\SO-J I)s30 S~~ itl^h

0.20 0;28 '"IhlO^ 0.4o ^ l 0.10 ' Q.

14+001 13+00 IT 12+00 W 11+00 T 10+00 T 9+00 f 8+00 f 7+00 W 6+00 f 5+00 TT 4+00 W 3+00 f 2+00 W 1+00 W

14+00 W 13+00 f-\———i———r— 12+00 W 11+00 W 10+00 T 9+00 f 8+00 f 7+00 W 6+001 5+00 f 4+00 ir-t——i——i——i——i————i- 3+00 WH———i———l a+pow 1+00 T^————^-——-l

IP - la I P -14+00 f 13+00 IT-i——i——^ 12+00 f 11+00 IT 10+00 T 9+00 W 8+00 f

L, I.—7+00 W 6+00 W fr+oo ir 4+00 W 3+00 W 2+00 W 1+00 f

111=60^,7=10036.S —**.

2.2 2 .3 2 .3

3.8 2.7 2.

JVX Spectral 'c* (dimensionless)

JVX Spectral Tau(s)


MX Chargeability(mV/V, 690ms-l050ms)

288.9 27.5

Near conductor Shear zone

14+00 f 13+00 f-H———i———l——————-H———i———t- 12+00 W 11+00 W 10+00 W 8+00 f 7+00 W 6+00 Wi- -1..-1——

0=1

5+OOT 4+00 W 3+00 WH————'————l————i————l————i————h- 2+00 W 1+00111=1

Apparent Resistivity(ohm—m)

*^,

3670X^3232 2436

(7 4305 ^flBe Z

Line 1000 S

Pole-Dipole Arrayna

a r: 50.0 M

plot point


xxxx rxxx-

Very strong

•Strong

•Medium

Weak

•Very weak

•Extremely weak

Scale 1:500050 O 50 100 150 200 250 300

•d, , . . ..î (meters)

Plate 8



line 1 000 S01/02/U

Rx (2 sec): Scintrex IPR12, Tx (2 sec): Huntec M-4JVX Ltd, ret, no. 1-07, FEBRUARY 2001

31L13SE2002 2.20895 FLETT 280

JVX Spectral 'c' ( dimensionless)

JVX Spectral Tau(s)




13+00 T 12+00 W 11+00 ff 10+00 W 9+00 f

0.40 0130 0 .30 -^0.20^ Q/30 0.30 OiSO ' 0.30

13+00 f 12+00 W 11+00 If 10+00 W 9+00 f

0.30

13+00 1 | | 12+00 f | 11+00 W 10+00 W 9+00 f

J

6 1 ' '297.0

IP - la IP-113+00 W 12+00 W ——•••^••• J——— 11+00 W 10+00 W 9+OOW-± ^ .

M=85?f=0.10 M^


JVX Spectral Tau


MX Chargeability, 690ma-1050ms)

13+00 W———l———i———K 12+00 f 11+00 W 10+00 W 9+00 T11=1

3859


Line 900 S

Pole-Dipole Arrayna

a = 50.0 M

plot point


Very strong

•Strong

•Medium

Weak

•Very weak

xxxx xxxx...... - -Extremely weak

Scale 1:500050 O 50 100 150 300 250 300a"——s

(meters)

Plate 9RANDSBURG INTERNATIONAL GOLD CORP.

JVX SPECTRAL IP/RES SURVEYFLETT PROPERTY

NORTHEASTERN ONTARIO. NTS:31 L/13line 900 S

01/02/12Rx (2 sec): Scintrex IPR12, Tx (2 sec); Huntec M-4

JVX Ltd. ref. no. 1-07, FEBRUARY 200131L13SE2002 2.20895 FLETT 290


JVX Spectral Tau(a)


MX Chargeability(mV/V, 690ms- 1050ms)


13+00 IT 12+00 f——l——,——l——l——l——.

0.40

0.30

13+00 IT 1 2+00 f

13+00 IT 12+00 W

13+00 f 12+00 f t. -- J,M=6F,T=.10 M

JVX Spectral 'c 1(dimensionless)

JVX Spectral Tau


MX Chargeability 7^.03 (rnV/V, 690ms-1050ms)

J&V. ZM

3.o( S.!//

3.9 2 .6

ZA/ l '

l* fi4.6

13+00 f 12+00 fi--'T-'——'——'————^==^ 11=1 i

2147 3241,

00/6423

5851 6826^

5846^ 3367

ilff-Apparent Resistivity

(ohm-m)

Line 800 S

Pole-Dipole Arraya na aK———————t——'——~——————————\——————

a = 50.0 M

plot point


xxxx xxxx

- Very strong

- -Strong

-Medium

1 Weak

-Very weak

- -Extremely weak

Scale 1:500050 O 50 100 1 50 200 250 300

J" 1 l- (meters)

Plate 10



Line BOO S01/02/12

Rx (2 sec): Scintrex IPR12. Tx (2 sec): Huntec M-4JVX Ltd. ret. no. 1-07, FEBRUARY 8001

31L13SE2002 2 .20895 FLETT 300

1500W 1400W 1300W 1200W 1100W l000W 900W——r— 800W 700W GOOW•""~' y----- 500 W lOOW 300W 200W 100W 100E 200E 3 00 E 400E 500E 60 O E ?OOE 800E 900E 1000E 1100E 1200E 1300E 1400E 1500E 1600E 1700E 1800E

c o oo

ffi o o o

COo o

COoo

(SIog

L 800 S

L 900 S

1,800

L 1000 S

L 1100 S

L 1200 S

L 1300 S

L 1400 S

L 15

1500W 1400W 1300TV 1200W l 100W 1000W 900W BOOW 700W 600W fiOOW 400W 300W 200W 100W 100E 200E 300E 400E 500E 600E700E ~'""BOOE~

CDo o

oo o

roo oCO

L 1500 S

o o05

CIo oC/)

900E 1000E 1100E 1200E l300E 1400E 1500E 1600E l700E 1800E

31L13SE2002 2.20895 FLETT 310

Scale 1:5000100 100 200 300

(metors)

Plate 11RANDSBURG INTERNATIONAL GOLD CORP,


NTS 31 L/13CHARGEABILITY (n~a, 50 m)

Contours: l A: 5 mV/V Sciritrex I VR12 K x fe H unt.cc M-4 Tx

JVX Ltd., ref. 1-07, FEBRUARY 2001

1500W 1400W 1300W 1200H 1100W 1000W 900W 800W 7001V 600W 500V 100W 300W 200W 100W 100E 200E 300E 4003 500E 600E 700E 800E 900E 1000E 11 GOE 1200E 1300E 1400E 1500E 1600E 1700E 1800E

o oCO

L 800 S

L 90

o o o

Vio c w

L 1000 S

L 110

1.120.1

O: Oh

Cfio oCO

CD

oo o

ra

o o

L 1500 S

Cio o 100

Scale 1:5000O 100 200 300

(meters)

1500W 1400W 1300W 12001Y 1100W 1000W 900W SOQW 700W 600W 500W

31L13SE2002 2.2089S FLETT 320

400W 300W 200W 100W 100E 200E 300E 400E 500E 600E 7COE 800E 900E 1000K 1100E 1200E 1300E 1400E 1500E 1600E 1700E 1800E

PLATE 1 2RANDSBURG INTERNATIONAL GOLD CORP.


NTS 31 L/13RESISTIVITY (n^2, 50 m)

Contours: 100 Jk 1000 ohm-nScintrex IPR12 Kx &C Huntec M-4 Tx

JVX Ltd., re f. 1-07, FEBRUARY 2001

1600W 1500W UOOW 1300W 1200W 1100W 1000W 900V 8 00 W 700^ eoow 4001V" SOOTY 200W 1001V 100E 200E 300E 400E 5COE 600E 700E 800E 900E 1000E 1100E 1200E 1300E 1400E 1500E 1600E 1700E 1800E 1900E 2000E 2100E

oo ooCO

O! f-!

COo oOD

L 700 S

L 800 S

. L 900 S

COo o

o o

o oCJ

co o o

L 1000 S

L 1100 Ss^.

L 1200 S

L 1300 S

L 1400 S

L 1500 S

o1C

o -

TTTT.tTIT.TT

^ ' — so — 4^.^"i-o-vicp-J-Ji -J^J-i-i ii-J--3 i-J'--! i-J"î— J-J-J-J-J-j-ci-vi-j-vj-j-ffl.ctc:Oii3s^^^*SJ^^^î^to*— ^csîV'

TTTTTTTTTTTT't TTT.TTTT.fFTT TTTT.TTTtT TTTTTTT.T.

TmmfTTTTTTTTYTTYTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT'tTTTTT TTTTTyoyoTTTTTTTrTTTTrTTTTTTTTTTTrTTTTTTTTTT ^

L 1625 S

td

1600W 1500W 1400W 1300W 1200W HOOT 1000VT 900ft 800W 700W 600W 500W 400W 300W 200W 100W 100E 200E 300E 400E 500E 60 OE 700E 800E 900E 1000E 1100E 1200E 1300E 1400E 1500E 1600E 1700E 1800E 1900E 2000E 2100E

31Ll3SE20a2 I .20S95 FLETT 3 30

o o

o o

leoi O~: O

o o'Si

o ooC/j

oCO

o o

COo occ

o oCO

01 o o

ci o ooo

ooGO

100

Scale 1:5000 o 100 aoo 300

(meters)

PLATE 13RANDSBURG INTERNATIONAL GOLD CORP,


NTS 31 L/13TOTAL FIELD MAGNETIC CONTOURS

Contours: 2 0, 1 00 Se 1 000 nTBase Field: 57,000 nT removed

JVX Ltd., ref. 1-07, FEBRUARY 2001

jooz Axvnxaaj 'AO-"pn

tT

u OOO'^S :pPI.i Iu OOOT ?? DOT *OT :

SHIKUNODET/1 IE SIN

NH31SV3H1HON "(HOD ivNOLLVNHaiNi

300TE3006T 3009T300iT ——i——3009T ——i——300ST 300tT 300CT 30051 300H 3000T 3006 3009 300i 3009300C 3002[GOTMOOTMOOf7 MOOS MQQ9 MOOiM009A1006 M.OOOT A100TTAOOCI MOOtT AtOOQT M009T

OOE OOE DOT

ooos'TGOT

CO joo -

co o

•COo

o o

S OOtT

en o o

COo: o -

CO;o:O:C:

CO O Oos

CO o o03

COo o r-

co o o10

———

W C/D '-d

pq

S S^9T l

S 009T l

S OOtI l

U4144114 144 1 144141444414444441444.4^14:44,44144441 1 14144 4 44141 4441441444441114441444^4444.4.4.1.4.14.1.4.4.4.4.4.4.4411^14441411144444144144444111114414144144 j 44444 J.44441444444414444444114444i4411444444441144444444444Ul*.44rUUi444 ci cs ^ ci o ci o cî o cp —i*-— i oates— 0000000^0*— lOi&i i i i i i i ' t t i i i i \

l l 141414144414141114444444414441144444441144-414111411444441441144114144414441114414411141144411444411441144141414444444144144,1414141141444441444114414411444444141441114144

I44444444111114144111411414414444441^4441144414 cdI>^blr^f^c^îX!C^J^î^j?^?ivt•^J^^lf^j(î4Î4î^J^•jt^J'^J' —'—^-^^^tTJe^^rO^Ji^-OT O^-dUtf* so -ô cd to c~j TO ri c^ r^ c^ crj

1414144444=1TTff^Y^

44144441444444411

44t444U.444444444414J414114414441444414i.14

41^444441114114444141144441441414444114444^44144444444444

s oosn

S DOT I T

S 0001 T

S 006 T

S OOiTl 44LV4 4 J14 4444144UU44 441UJUlJ, 4U 414.4411414 U3-4 '4444^444 44'4114414144.44144.1141111411414 411411114 4'41444 444 444'11444 44 A144111 U'4 3^^^c5e\JKC3O"îricJ^cJcJî^ôno^co^cviri^^tD^^^^fflîo-^-^^^w-^Mrû5^ — sôj-îricîn-*-; —— L^ttS-^-iMtM—l—1| -H —l CM CM - CO SO m —l —4 l l 1 l l l l l l t l l J l l l I 1 l l l l l l l l l l t i l l l l f l l l l t l

S 0091

S 00^

CO^ cc

o o

OS O C CO

CIo oCO

o oCO

CO

oCO

ro o oCO

o oCO

lo o o

o o

CQ OoGC

OoCO

o o Od

300T2 3000S 3006T 3009T 300iT 3009T 300ST 300tT 300CT 300ST 300TT 3000T 3006 3009 300A 3009 3005aoot300C 3002300 TOMOOT MOOS MOOGMOOG M009 MOOiMOOSMOOOI MOOT T M0021 MOOCT MOOfT MOOQT M009T

RPT ON SPECTRAL IP RESISTIVITY & MAG SURVS FLETT TP · JVX SPECTRAL IP/RESISTIVITY A MAGNETOMETER SURVEYS CONDUCTED ON THE FLETT PROPERTY FLETT TOWNSHIP NORTHEASTERN ONTARIO NTS:

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