In 2012 Portofino Resources contracted a helicopter-borne geophysical survey by Precision Geosurveys Ltd, with radiometric and magnetic sensors, and carried out a ground geochemical sampling program targeting specific areas of the Iron Horse and Bolivar Zones of the Property.

The geophysical survey involved the acquisition of high resolution magnetic and radiometric data over the Iron HorseBolivar property. The survey area, indicated by the TMI image in Figure 20 was approximately 3.8 km by 9.1 km, covered by 173 kilometres of main survey lines at 150 meter spacings on headings of 340° and 160° with orthogonal tie lines at 1 km intervals and at an average survey clearance of 44 meters.

A possibly significant feature of the TMI map is a northwest-trending, elongate annular magnetic low (blue colour on Figure 19) that encloses a moderate magnetic high in the northwest corner of the property. The Silver King, Oka 8, Bolivar West and Bolivar East showings all occur within this magnetic low; the Alma Mater showing is along the southern edge of the area of low magnetic intensity. The area of low magnetic intensity corresponds to an area of pyritic hornfels observed on surface near the Oka 8 showing. The Silver King area is characterized by sericitized granitoids, which may have lost magnetite by the alteration. This pattern of annular magnetic lows is commonly developed by magnetite destructive, argillic alteration in the outer zones of some porphyry copper deposits.

The Iron Horse showings occur on the southern flanks of a northwest trending moderate to high magnetic intensity zone as shown in Figure 19. This magnetic feature may be the result of secondary magnetite and pyrrhotite related to skarning in Nicola Group sedimentary rocks adjacent to plutons or it may be a contrast between hornfelsed sedimentary rocks and a dioritic intrusion of the Pennask Batholith.

Radiometric surveys detect and map natural radioactive decay products from uranium, thorium and potassium in minerals in soils and rocks by characteristic wavelengths of gamma rays. The purpose of radiometric surveys is to determine either the absolute or the relative ratios of U, Th, and K in surface rocks and soils. The image for the potassium equivalent radiometric survey generated by Precision Surveys is shown in Figure 21 with major geological contacts and mineral occurrences superimposed. Potassium is mobile in hydrothermal alteration systems and the K concentration is a useful measure to evaluate the zoning across an altered area. Areas of K enrichment correspond to the potassic zone; removal of K (plus Na, Ca, Mg) occurs as a result of intense and pervasive argillic (clay) alteration.

The most striking feature visible on Figure 21 is a northwest elongate high-K anomaly in the northwest corner of the property. This anomaly roughly corresponds to an area of pyritic hornfels that is also a magnetic low in Figure 20. Other areas of high K concentration occur in the southeast and southwest corners of the property. The significance of these anomalies is unknown. Some of the potassium lows (Fig. 21) may also be due to feldspar destructive hydrothermal alteration. However, in contrast to magnetic field intensity measurements of bedrock, radiometric intensity measurements are significantly attenuated by organic and inorganic overburden and a knowledge of surficial geology is required for accurate interpretation. The noticeable potassic anomaly along Bolingbroke Creek is a proportionate to a high degree of bare outcrop exposed on steep slopes and in blasted rock cuts and quarries, compared to bedrock in upland areas buried under radiation-attenuating glacial drift and forest.

The 2014 ground-based magnetometer surveys focused on high magnetic susceptibility areas defined by the 2012 airborne survey that coincided with known mineralized zones. Ground magnetic highs within these zones commonly were found to correlate more precisely with some types of mineralization such as skarns and pyrrhotite-bearing massive sulphide lenses. A map from the report by Kikauka and MacIntyre is shown in Figure 23, which highlights magnetometer anomalies above an arbitrarily determined 56,200 nT that may correlate with higher mineralization potential resulting from skarn formation.

In 2014 Portofino Resources Inc. continued exploring the Iron Horse Property with an expanded program of geological mapping (1:5,000 scale, 420 hectares), geochemical 30 element ICP and Au geochemical analysis (34 rock samples, 334 soil samples), magnetometer geophysics (18.54 line-km), and prospecting carried out between April 16, 2014 to May 31, 2014. on mineral tenure numbers 518238, 518239, 537695, 559571, 581151, and 1028372. Most of the effort was placed around the Gayle and Iron Horse mineralized zones at the east end of the property as it existed in 2014. 

A program of targeted soil, silt and rock geochemical sampling was undertaken on the Iron Horse claims by Craig Lynes, the property owner at the time, in May 2012. A total of 24 rock, 15 silt and 151 soil samples were collected in the Silver King, Alma Mater, Bolivar Road, Bolivar Creek and Bolivar East areas shown in Figure 22. 

A total of 20 rock samples were collected and analyzed as part of Rich River’s targeted geochemical program. Several samples returned anomalous values for Cu, Mo, Pb and Zn and one sample returned anomalous Ag. The best result was for sample IRN-CR-016 (coordinates in Table 3, Kikauka and MacIntyre, 2012; no map provided) which returned 2600 ppm Cu and 17800 ppm Zn. This sample was collected from a malachite-stained shear zone exposed 20 m up a cliff exposed along the east bank of a logging road. This locality is approximately 200 meters south-southeast of the Alma Mater adit. Another sample from this locality contained 1095 ppm Mo. This sample was also anomalous in Zn and Ag. Sample IRN-CR-015 was collected from a 20 cm wide banded quartz vein approximately 150 meters north of the Alma Mater adit . This sample returned 1535 ppm Mo suggesting that the dark bands in this sample are composed of fine grains of molybdenite. The only other significant result was for sample IRN-CR-013, a grab sample obtained from the waste dump at the Silver King showing which returned 4800 ppm Pb and 4740 ppm Zn. One sample near the Bolivar Creek showing described as an angular quartz subcrop returned anomalous Au (0.02 ppm) and Ag (21.2 ppm).

The surveyed area lies in the vicinity of the Iron Horse and Gayle showings. Rock samples collected in the 2014 program are plotted by location on Figure 24, with values for Cu, Zn, As, Ag and Au listed in the labels at each site. 

Soil samples were collected along 16 lines in a NW trending en-echelon array from which 334 soil samples were collected and analyzed by multi-element ICP spectrometry. Two maps summarizing the geochemistry for gold and copper are shown respectively in Figures 25 and 26. The map for gold (Fig. 25) shows the location of values above 20 ppb, which range up to 320 ppb. Twelve samples fall within this range; two proximal to the Gayle showing and the other 10 north of the Iron Horse showings mainly in an area of second growth forest on a silty till veneer. 

The copper soil map highlights values of copper in soil above 100 ppm, which is a common value for anomalous threshold in many geological environments of British Columbia, and shows a convincing NW trending anomalous zone extending from the Gayle showing across the Iron Horse zone. Fifteen copper values above 100 ppm range from 106 to 436 ppm with three clusters of 2 or 3 anomalous samples in the Gayle and Iron Horse areas. 

Kikauka and MacIntyre (2015) correlated the anomalous soil geochemical zones to 4 geological / geophysical features including a feldspar porphyry breccia, folded and faulted strata, magnetic anomalies and a well-defined sulphide mineralized fold hinge (see Table 15 in Kikauka and MacIntyre, 2015).