CJP EXPLORATION INC.

PO Box 219 14579 Government Road Larder Lake, Ontario P0K 1L0, Canada Phone (705) 643-1122 Fax (705) 643-2191 CJP EXPLORATION INC. Spectrometer Survey Over the SHEBA PROPERTY Nouvel Township, Ontario

TABLE OF CONTENTS 1. SURVEY DETAILS...3 1.1 PROJECT NAME... 3 1.2 CLIENT... 3 1.3 LOCATION... 3 1.4 ACCESS... 3 1.5 SURVEY GRID... 4 2. SURVEY WORK UNDERTAKEN...5 2.1 SURVEY LOG... 5 2.2 PERSONNEL... 5 2.3 SURVEY SPECIFICATIONS... 5 3. OVERVIEW OF SURVEY RESULTS...6 3.1 SUMMARY INTERPRETATION... 6 LIST OF APPENDICES APPENDIX A: STATEMENT OF QUALIFICATIONS APPENDIX B: THEORETICAL BASIS AND SURVEY PROCEDURES APPENDIX C: INSTRUMENT SPECIFICATIONS APPENDIX D: LIST OF MAPS (IN MAP POCKET) LIST OF TABLES AND FIGURES Figure 1: Location of... 3 Table 1: Survey log... 5 June 2009 ii

1. SURVEY DETAILS 1.1 PROJECT NAME This project is known as the. 1.2 CLIENT 1.3 LOCATION CJP EXPLORATION INC. 71 9 th Ave. Larder Lake, Ontario P0K 1L0 The is located in Nouvel Township, approximately 25km north of Iron Bridge, Ontario in the Sault Ste. Marie Mining District, District of Sault Ste. Marie. The area prospected covers claims 4217092 and 4217093. Figure 1: Location of 1.4 ACCESS Access to the property is gained from Iron Bridge via highway 546 for approximately 27 km. The property is situated directly to the south of the highway, with portions of its northern boundary extending to the highway.

1.5 SURVEY GRID The area was traversed randomly in conjunction with the prospecting survey. Any assay point had a corresponding GPS waypoint taken for spatial referencing. LARDER CfOPHVSlCS LTG.

2. SURVEY WORK UNDERTAKEN 2.1 SURVEY LOG Date Survey Location Distance Trav-Spectrometeersed Readings November 10, 2008 November 11, 2008 November 12, 2008 November 13, 2008 November 14, 2008 MOB from Larder Lake to Iron Bridge Locate survey area and begin spectrometer traverses. 5 km 4 Continue spectrometer traverses. 6.2 km 2 Continue spectrometer traverses. 7.8 km 6 Demob Iron Bridge to Larder Lake Table 1: Survey log 2.2 PERSONNEL Jason Ploeger of Larder Lake collected all of the Spectrometer and GPS waypoint data. 2.3 SURVEY SPECIFICATIONS The survey was conducted with a Radiation Solutions RS-230 BGO SUPER-SPEC spectrometer. The operator of the spectrometer accompanied a prospecting crew on their traverses. When it was found that the spectrometer read over double background an assay was taken. All data was both electronically noted and written in a notebook.

3. OVERVIEW OF SURVEY RESULTS 3.1 SUMMARY INTERPRETATION 6285 This spectrometer assay was taken on what appeared to be an arkose outcrop. 6286 Assay 6286 taken was acquired at the east end of a 25m long water filled trench. The geology here appears to be argillite, arkose with a large quartz vein. Within the quartz vein appears mineralization consistent with chalcopyrite. 6287 This spectrometer assay was taken from arkose talus at the base of a cliff face. 6288 This spectrometer assay was taken from an outcrop of fine-grained argillite. 6292 This spectrometer assay was taken from an outcrop of medium grained arkose. 6293 This spectrometer assay was taken from an outcrop of fine-grained argillite. 6294 This spectrometer assay was taken from an outcrop of medium grained argillite with granitic clasts. 6295 This spectrometer assay was taken from an outcrop of medium grained argillite with granitic clasts. 6296 This spectrometer assay was taken from an outcrop of medium grained argillite with granitic clasts. 6297 This spectrometer assay was taken from an outcrop of fine-grained argillite. 6298 This spectrometer assay was taken from an outcrop of medium grained argillite. 6299 This spectrometer assay was taken from an outcrop of medium grained argillite.

Assay Number Total (ngyh -1 ) K (%) U (ppm) Th (ppm) UTM 6285 129 0 22.8 1.1 17T 335174 5149641 6286 322 0.1 4.5 23 17T 334921 5149605 6287 60.8 0.4 8.7 2.9 17T 335001 5149271 6288 108 0.8 11.2 13.8 17T 335427 5149225 6292 88.6 0 15.5 1.6 17T 334720 5148938 6293 112 0.5 14.4 10.3 17T 334911 5148626 6294 142 1 13.4 17.3 17T 336215 5149137 6295 138 2.5 13.3 12.4 17T 336340 5148952 6296 102 1.2 13.2 5.6 17T 336147 5148645 6297 171 2.7 12.5 25.3 17T 335583 5148639 6298 205 2.7 14.8 31.1 17T 335504 5148589 6299 125 2.3 8.6 17.6 17T 335299 5148808 Random areas were sampled based of total count compared to background. Generally samples were taken when count reach double the background. A definite pattern was identified as a result, specifically the southern area of claim 421709 was found to be double and sometime triple the background of the area. It is suggested a more detailed scintillometer survey be completed in the specified area. I would recommend a more thorough spectrometer survey to be performed when the cut grid is established.

APPENDIX A STATEMENT OF QUALIFICATIONS I, C. Jason Ploeger, hereby declare that: 1. I am a geophysicist (non-professional) with residence in Larder Lake, Ontario and am presently employed as geophysical manager of Larder Geophysics Ltd. of Larder Lake, Ontario. 2. I graduated with a Bachelor of Science degree in geophysics from the University of Western Ontario, in London Ontario, in 1999. 3. I have practiced my profession continuously since graduation in Africa, Bulgaria, Canada, Mexico and Mongolia. 4. I am a member of the Ontario Prospectors Association, a director of the Northern Prospectors association and a member of the Society of Exploration Geophysicists. 5. I have an interest in some of the properties or securities of CJP EXPLORATION INC. 6. I am responsible for the final processing and validation of the survey results and the compilation of the presentation of this report. The statements made in this report represent my professional opinion based on my consideration of the information available to me at the time of writing this report. Larder Lake, ON C. Jason Ploeger, B.Sc. (geophysics) Geophysical Manager of Larder Geophysics Ltd.

APPENDIX B THEORETICAL BASIS AND SURVEY PROCEDURES Gamma-Ray Spectrometry (GRS) provides a direct measurement of the surface of the earth, with no significant depth of penetration. This at-surface characteristic allows us to reliably relate the measured radioelement contrasts to mapped bedrock, surficial geology, and any alterations associated with mineral deposits. All rocks and materials derived from them are radioactive and they contain detectable amounts of a variety of radioactive elements. A gamma-ray spectrometer is designed to detect the gamma rays associated with these radioactive elements, and sorts them by their respective energies. It is this sorting ability that distinguishes the spectrometer from instruments that measure only total radioactivity. Why do we need to know about K, U, Th? Potassium (K), uranium (U) and thorium (Th) are the three most abundant, naturally occurring radioactive elements. K is a major constituent of most rocks and is the predominant alteration element in most mineral deposits. Uranium and thorium are present in trace amounts, as mobile and immobile elements, respectively. As the concentrations of these different radio elements vary between different rock types, we can use the information provided by a gamma-ray spectrometer to map the rocks. Where the 'normal' radioelement signature of the rocks is disrupted by a mineralizing system, corresponding radioelement anomalies provide direct exploration guidance. Ground surveys do not require a corresponding airborne survey. They are easily conducted by one person as a reconnaissance survey or more formally using a series of grid lines. The resulting geochemical information provides an important additional layer of information significantly improving bedrock and surficial mapping and ore vectoring. The Gamma-ray Energy Spectrum The primary acquisition data set is a multichannel gamma-ray energy spectrum. The area from 0 to 0.4 MeV is not used and consists of counts created by Compton scattering. For geological mapping, the K 40 (potassium), Bi 214 (uranium) & Tl 208 (thorium) peaks are of interest. During the aerial survey, the full spectrum of counts is recorded once per second, using a 256-channel histogram. During postflight data processing, the counts for the radioelement s of interest (K 40, Bi 214, Tl 208 ) are accumulated. The summation includes the counts for a range of energies (a 'window' or 'region of interest') centered on each peak. The accumulated count rates are then converted to equivalent ground concentrations of potassium, uranium & thorium using a set of calibration constants that are a characteristic of each spectrometer system.

APPENDIX C RS-230 BGO Super Spec Gamma Spectrometer Handheld Gamma-Ray Spectrometer Specifications Memory: - Internal Data Storage memory - Assay + 1024 channel Spectra: 128 samples Data Input / Output: (Using supplied RS-Analyst software) -USB -Bluetooth -GPS link via Bluetooth Temperature Range: -20 to +50 degrees Celsius Control: -Single one button, Thumb activated Alarm: -Audio via miniature speaker -Variable audio threshold set point -Audio proportional to count rate Weight: 4.5 lb (2.04 kg) including batteries RS-230 Size & Package Style -10.2 x 3.2 x 3.8 (259 mm x 81. mm x 96 mm) -1 mm aluminum outer case -In a flashlight configuration with side support strap and handle Display:

-128 x 64 pixels, 1 1/8 x 2 3/8 -Graphic LCD display with white backlight and automatic dimming Readout: -Search Mode: Counts in CPS from 0 to 65,535 and Histogram chart -Assay Mode: Display in %K, ppm of U & Th Energy Response: 30 kev 3000 kev Internal Sampling: 20 readings per second Batteries: -Internal battery pack module (4xAA) easily replaceable -Rechargeable or Alkaline (optional) -Life: 8 + hours at 20 degrees C The performance of the 6.3 in 3 (103 cm 3 ) higher density Bismuth Germanate (BGO) detector is an equivalent of a 21 in 3 (390 cm 3 ) Sodium Iodide (Nal) commonly used with larger portable units and approximately more than 3 times the same size NaI crystal. The spectrometer is auto-stabilizing on the naturally occurring (K, U, & Th) radioactivity and does not require any test sources.

APPENDIX D LIST OF MAPS (IN MAP POCKET) Posted profiled TFM plan map (1:2500) 1) CJP-SHEBA-SPECTROMETER TOTAL MAPS=1

333500 334000 334500 335000 335500 336000 5148500 5149000 5149500 5150000 5150000 5149500 5149000 5148500 X 6285 - Spectrometer Assay Location with Assay Number CJP EXPLORATION INC. SHEBA PROPERTY Nouvel Township, Ontario SPECTROMETER ASSAY LOCATION PLAN MAP Readings Taken On Ground Readings Taken On Rock Station Seperation: varies during GPS traverse Traverses Performed November 11 to 13, 2008 333500 334000 334500 335000 335500 336000 Scale 1:5000 100 0 100 200 300 (meters) RS-230 BGO SUPER SPECTROMETER Spectrometer Operated by: C Jason Ploeger Processed by: C Jason Ploeger, B.Sc. Map Drawn By: C Jason Ploeger, B.Sc. June 22 - June 25, 2009 CJP-SHEBA-SPECTROMETER