Fancamp Releases Second Assay Results From the Lac Lamelee South Iron Project Di
posted on
Nov 06, 2012 09:32AM
Resource projects cover more than 1,713 km2 in three provinces at various stages, including the following: hematite magnetite iron formations, titaniferous magnetite & hematite, nickel/copper/PGM, chromite, Volcanogenic Massive and gold.
VANCOUVER, BRITISH COLUMBIA--(Marketwire - Nov. 6, 2012) -Fancamp Exploration Ltd., (TSX VENTURE:FNC) ("Fancamp" or the "Company") is pleased to announce the second series of Iron assay results from the now completed summer-fall NQ diamond drilling program at the Company's wholly owned Lac Lamêlée South Iron Project, located 100 km southwest of Fermont (Quebec) in the heart of the Fermont-Wabush-Labrador City Iron Camp. Drilling during this campaign totaled 12,606.6 meters in 40 drill holes. To date, some 57 holes were drilled totaling 18,220 meters.
Iron assay results are now completed for the first 12 drill holes (LS-12-01 to 12). Assay results for drill holes LS-12-01 to 06 were issued in a Company news release dated October 22, 2012. The best assay intervals for drill holes LS-12-07 to 12 are summarized below*. Assays for the remaining 28 holes are still pending. Quality Assurance and Quality Control protocols are appended.
Diamond Drill Hole # | From (m) |
To (m) |
Core Length (m) |
FeT (%) |
Fe2O3 (%) |
LS12-07 | 125.0 | 267.8 | 142.8 | 32.1 | 45.9 |
including | 246.2 | 267.8 | 21.6 | 37.0 | 52.8 |
LS12-08 | 6.0 | 287.0 | 281.0 | 25.3 | 36.2 |
including | 85.0 | 92.8 | 7.8 | 30.6 | 43.7 |
including | 92.8 | 105.2 | 12.4 | 37.3 | 53.3 |
LS12-09 | 12.0 | 304.45 | 292.45 | 33.9 | 48.5 |
including | 12.0 | 152.0 | 140.0 | 35.8 | 51.2 |
including | 29.0 | 91.0 | 62.0 | 38.5 | 55.1 |
LS12-10 | 270.5 | 308.0 | 37.5 | 22.4 | 32.0 |
332.0 | 398.0 | 66.5 | 30.3 | 43.3 | |
LS12-11 | 27.0 | 177.0 | 150.0 | 35.3 | 50.6 |
including | 27.0 | 125.0 | 98.0 | 39.2 | 56.0 |
LS12-12 | 30.0 | 158.0 | 128.0 | 26.1 | 37.3 |
182.5 | 364.1 | 181.6 | 25.7 | 36.8 | |
including | 188.5 | 208.0 | 19.5 | 32.6 | 46.6 |
including | 264.0 | 284.0 | 20.0 | 33.0 | 47.2 |
* The selected composite assay results are not necessarily representative of the average grades or thicknesses of the mineralized zones or potential resource. Intervals are down-hole lengths and not necessarily true widths of the mineralized zones. Grades are calculated from Fe(T)% sample assays completed by the ALS Laboratory Group. Certain iron formation lithologies contain variable amounts of Iron in silicates which may reduce the recoverable Iron grade.
Mr. Jean Lafleur, M. Sc., P. Geo., the Company's President and CEO, stated, "The 18,220 meters in drilling at the Lac Lamêlée South Iron Project has demonstrated the significant upside potential of the Iron mineralization located a few kilometers west of Arcelor Mittal's Fire Lake Mine operation and Champion Iron Mines Fire Lake North feasibility-stage project. All this exploration work at an all in cost of around $200 per meter drilled."
Mr. Lafleur also added, "While we are awaiting for the remaining Iron assays results, we are constructing the 3-D model of the iron mineralization. PJL Géo-Conseil of Ste-Thérèse (Quebec) has been hired as the independent contractor for the upcoming mineral resources estimates and accompanying technical report on the mineral resources scheduled for completion in Q1-2013."
The Lac Lamêlée South Iron Project
The character of the iron mineralization changes from the northeast to the southwest. Consequently the mineralization has been divided into three structurally distinct zones: the Mountain Pond Zone to the northeast, the centrally located "91-92" Zone, and the Tanguay Zone in the southwest. These three zones span a distance of approximately 2.5 kilometres. The Mountain Pond Zone is comprised of a steeply south dipping, steeply west-northwest plunging, tightly folded to isoclinal syncline with a curvilinear axial plane striking SE to E and dipping steeply to the south-southwest.
Proceeding to the southwest into the "91-92" Zone, the fold is isoclinal and the axial plane strikes W-SW, dipping steeply northwest. At this point the northern limb of the structure appears to transition into leaner iron formations with lower iron grades.
The Tanguay Zone is offset from the "91-92" Zone by a late-stage fault with a horizontal displacement of about 300 metres. This zone appears to be complexly folded as the stratigraphy is repeated in several drill holes. Lithologies generally trend to the southwest-northeast and dip to the northwest at moderate angles.
The drill programs of 2011 and 2012 were designed to calculate resources to vertical depths of 350 metres, however two holes were drilled to vertical depths of 600 meters to 650 meters and intersected equally as rich iron formations as have been tested throughout the drilling campaign.
This news release was prepared, reviewed and approved by Mr. Mike Flanagan, M.Sc.A, P. Geo., the Lamêlée South Project Manager, a Qualified Person under NI 43-101 standards.
Some of the statements contained in this release are forward-looking statements, such as estimates and statements that describe the Company's future plans, objectives or goals, including words to the effect that the Company or management expects a stated condition or result to occur. Since forward-looking statements address future events and conditions, by their very nature, they involve inherent risks and uncertainties.
Quality Assurance, Quality Control Protocols
Drill core boxes arrive at the Fancamp core logging facility on the Lac Lamêlée South Iron Project. Boxes are opened and depth tags are verified for errors. Each box is labeled with embossed aluminum tape stapled to box end. Numbers indicated hole and box numbers as well as "from" and "to" footages. Sampling is continuous through mineralized intervals and intermittent in other lithologies. Within mineralized intervals, samples taken are 2 metres in length of half-sawed core, or up to lithological or structural boundaries. One standard per hole is included within the sampling of mineralized zones up to 250 metres of hole length. Holes deeper than 250 metres contain a second standard. There is one blank sample and one duplicated sample per 80 metres of core. Some 26 samples of varying lithologies have been quartered and sent to the principal laboratory and a second laboratory. Approximately 50 Davis Tube and density test have been conducted on a range of important lithologies. One-half of the sample is returned to the core box with the sample tag number stapled at the down-hole end of the sample interval. The other half is packaged in a plastic bag accompanied by its stapled sample tag number. The sample number is also written with felt pen on the bag.
Core logging is conducted using GeoticLog and Geotic Graph software. Data is transcribed for GEMCOM software. Geology is described using 13 lithological units and several sub-lithologies. Other parameters described in the logs include structure, magnetic susceptibility, rock quality data and mineralization. Rock quality data is described at varying intervals according to their common fracture characteristics, recovered lengths, RQD length (total lengths of sections over 10 centimetres) and number of fractures over the interval. Recovery and RQD percentages are calculated. Mineralization is described as a visual percentage of magnetite and/or hematite and a ratio of magnetite to hematite is generally estimated.
Sample bags are secured with staples and/or cable ties. Sample batches are tabulated for shipping control. Sample requisitions are included in the first bag of each batch. Samples are placed in large rice bags for shipping, all secured with a cable tie. Batches are separated into two groups corresponding to the two drills working on the project. Samples are transported from camp to a shipping depot in Wabush (Newfoundland and Labrador). Batches are placed on pallets and wrapped in plastic to secure the bundles. Samples are shipped by commercial transport to the ALS Laboratory Group facilities in Val-d'Or (Quebec). Shipping waybills are kept for tracking shipments as required.
Core samples received at the laboratory are sorted and verified against the original list to ensure that all samples have been received to check for discrepancies. The samples were entered into the laboratory information management system. The sorted samples are dried in the original sample bags to ensure that any damp fines did not remain upon transfer to drying containers. Once dry the samples were crushed 70% to less than 2 millimetres, (Tyler 9 mesh, US Std#10 screen). Each sample was then riffle split and an aliquot up to 250 grams was pulverized to better than 85% to less than 75 µm, (Tyler 200 mesh, US Std#200 screen). Quality control testing was conducted on random samples at both crushing and pulverizing stages to verify efficiency. Samples were then analyzed using the fusion XRF whole rock package which provide the analysis of Al2O3, CaO, Cr2O3, Fe(T), K2O, MgO, SiO2, TiO2, and single temperature Loss On Ignition, as well as As, Ba, Cl, Co, Cu, Mn, Ni, P, Pb, S, Sn, Sr, V, Zn, and Zr. Each batch was accompanied by QAQC measures provided by the laboratory as well as those conducted during the sampling. These included the analysis of blanks, duplicates and certified standard reference materials. All QAQC standards are control charted to ensure that the data passes quality control prior to final release.
Upon completion of analysis and verification by the laboratory chemist, results were entered into the information management system and approved. Reports are then generated and a final quality control check is done by an independent person. This person also did the final certification of the data. Data was then transferred to Fancamp.
S.E.C. Exemption: 12(g)3-2(b)
No stock exchange or securities regulatory authority has reviewed or accepted responsibility for the adequacy or accuracy of this release.