Tulkubash Resource Update

·      Samples for geological logging, assay, geotechnical, metallurgical, and density test work are collected via a combination of HQ Diamond Drill Holes, underground adit sampling, trench channel sampling, and chips from exploration road cuts.

·      Drilling for collection of samples for assay is conducted on an East-West (rotated 42° degrees East) grid at 40 m × 40 m collar spacing. All intervals in bedrock are sampled.

·      Dry bulk density is measured using a paraffin-coated immersion method.

·      The presence of mineralisation is determined by a combination of geological logging (core observations) and assay results.

·      Drilling is diamond core, predominantly HQ in diameter, down to NQ at depth; occasional use of triple-tube when required to improve recoveries.

·      The majority of drilling is inclined attempting to cut the mineralized structures at a closest to a normal angle to the strike orientation as possible.

·      Drilling from underground stations is orientated normal to the strike of the structure.

·      Diamond core recovery is maximised via the use of triple-tube sampling and additive drilling muds.

·      Nominal down-the-hole sample length is 1.5m

·      Diamond core recovery is recorded as a percentage of total length drilled, estimated directly from core box observations.

·      Also rock quality designation (RQD) measurements are taken.

·      Overall recovery from diamond drill core showed acceptable levels of recovery (>90%) for all holes.

·      Sample recovery in some friable mineralisation may be reduced; however it is unlikely to have a material impact on the reported assays for these intervals.

·      Analysis of duplicate samples performance does not indicate any chemical bias as a result of inequalities in samples weights/core recovery.

·      All drill samples are geologically described utilising logging codes.

·      Geological logging is performed on nominal 1.5 m intervals.

·      When required, logging is done on shorter intervals, as well as across the mineralized zone's boundaries.

·      All core to date has been photographed, logged, and stored in the database.

·      Sample intervals are designated and marked by project geologists prior to sampling. Samples are typically 1.5 meter intervals, but can vary to log structural, alteration, or lithological contacts.

·      Core samples are split using a diamond saw, with highly fractured intervals being split manually. One half of the core is selected and bagged for assay.

·      Samples are packaged in individually labelled polyethylene bags, top rolled and stapled, weighed, and packaged with 5- 6 samples per rice sack.

·      Individual rice sacks are tied with wire, labelled, and set aside for pickup by Chaarat Logistics for transport to IRC Laboratories (IRC) in Kara Balta for sample preparation.

·     The second half of the core is retained in numbered and labelled wooden core boxes for future reference and possible check analysis. These core boxes are stored in a Chaarat storage facility in Bishkek.

·     Sample intervals are designated and marked by project geologists prior to cutting.

·     At IRC's sample preparation facility, samples are dried, crushed in a laboratory jaw crusher to 100% passing 2 mm mesh (10 mesh) and two 120 to 150 g manual splits are taken.

·     These subsamples are pulverized to minus 0.075 mm (200 mesh) in a ring and puck pulveriser and stored in numbered paper packets. One packet is sent to the IRC assay lab where a 2 g split is assayed for gold by Aqua regia digestion with AA finish.

·     Assay values from IRC are reported electronically to Chaarat. The second packet, along with coarse reject material, is shipped to Chaarat's core and sample storage facility in Bishkek.

·     For those samples over 0.3 gpt Au from IRC, the sample packets are transported to Stewart Assay and Environmental Laboratory (Stewart), also in Kara Balta. Stewart logs the samples into the LIMS system, re-labels the sample packets with ALS barcoded labels, and assays for gold by 30 g charge Fire Assay, Aqua regia digestion, and AA finish, and reported electronically to Chaarat.

·      Starting in 2017, the core samples were sent directly to Stewart.  The entire sample is crushed to 90% passing 2mm.  Two pulps are made by pulverizing to 85% passing 0.075mm. One pulp is returned to the Chaarat Bishkek core yard.  The second was analysed by fire assay per the procedure above.

·     The Competent Person with responsibility for this resource estimate visited the IRC sample prep facility, as well as both the IRC and Stewart laboratories.

·     Selected pulps were submitted for referee assay by SGS (Chita, Russia). Review of duplicate samples shows good agreement between different assay labs.

·      Five assay labs have been used during the life of the project. Labs currently used are the Information Research Centre (IRC) in Kara Balta, a Kyrgyz Lab which is ISO 9001:2008 certified by Bureau Veritas; Stewart Assay and Environmental Laboratories (Stewart) in Kara Balta, a subsidiary of ALS, which is also ISO 9001:2008 certified; and Genalysis Laboratory Services Pty Ltd (Genalysis) of Perth, Western Australia, a subsidiary of Intertek, which is ISO/IEC 17025 Certified by NATA. A fourth lab, not used since 2007, was Central Scientific Research Laboratory (CSRL) in Kara Balta. And in this 2017 season, a fifth laboratory was used as a check laboratory, SGS in Chita, Russia which is ISO/IEC 17025 Certified.

·     Samples are dried, crushed in a laboratory jaw crusher to 100% passing 2 mm mesh (10 mesh) and two 120 to 150 g manual splits are taken. These subsamples are pulverized to minus 0.075 mm (200 mesh) in a ring and puck pulveriser and stored in numbered paper packets. One packet is sent to the IRC assay lab where a 2 g split is assayed for gold by Aqua regia digestion with AA finish.

·     Assay values from IRC are reported electronically to Chaarat. For those samples over 0.3 gpt Au from IRC, the sample packets are transported to Stewart Assay and Environmental Laboratory (Stewart), also in Kara Balta. Stewart logs the samples into the LIMS system, re-labels the sample packets with ALS barcoded labels, and assays for gold by 30 g charge Fire Assay, Aqua regia digestion, and AA finish. ALS Stewart assay values are reported electronically to Chaarat.

·     The Competent Person with responsibility for this resource estimate visited the IRC sample prep facility, as well as both the IRC and Stewart laboratories.

·     Previously, mineralized intervals were selected by Chaarat personnel and pulps transported to Genalysis for referee analysis. At the end of the 2017 drilling campaign, SGS (Chita, Russia) was used as a further check laboratory.

·      No twinned drilling has been conducted at Tulkubash.

·      There is a quality assurance-quality control process in place that has to be followed prior to accepting a batch of assay results from the laboratory.

·      Significant intercepts are routinely re-assayed to confirm higher grade intercepts.

·      Sample blanks are inserted into the sample stream at site at a rate of 1 blank per 18 samples. Blank material is un-mineralized limestone. However, it is preferable that blanks have the same matrix as the regular mineralised samples.

·      Standards are inserted into the sample stream upon transport from IRC to Stewart at a rate of 1 standard per 18 samples. Pulps used by Chaarat are commercially certified reference material from Geostats Pty Ltd, Malcolm Smith Reference Materials, and Rocklabs.

·      Review of the available blanks, duplicates, and standards data for the entire Chaarat project reveals very good results.

·      Inter-laboratory duplicate samples show excellent agreement between different assay labs.

·      The laboratories send the information back to Chaarat Gold electronically, which is stored in secured Excel spreadsheets.

·      Project surveys use the Pulkovo 1942 datum, and a Gauss Krueger projection, which is standard for Kyrgyzstan for consistency with government geologic and infrastructure databases.

·      All surface drill holes have been surveyed by total station. Underground drill collars have likewise been surveyed by total station. Collar locations are assumed to be accurate to within centimetres.

·      All of the surface drill holes and underground drill holes have downhole surveys, typically taken at 15 meters and then every 50 meters using Reflex EzShot electronic single-shot downhole survey equipment. Equipment is serviced and factory set for declination annually.

·      The resource area has been resurveyed by total station along roads, ridges, valleys, and additional traverses and the resulting surface elevation points have been contoured. Surface elevations from the resulting topographic surface correspond well to surveyed drill collar, trench sample, and drill road locations and are assumed to be accurate to within less than 5 meters.

·      Drill spacing is typically 30-40 meter spacing, but can vary depending on road construction and access.

·      Not all the data available is used in Resource estimation. Only assays from surface core drillhole data; trenched; and underground drilling are used to estimate resources.

·      Drill sampling is typically done on 1.5 m intervals, except where interval length is adjusted to accommodate changes in lithology, alteration, or mineralization.

·      The drill spacing is deemed appropriate by the Competent Person to estimate resources to the level of confidence provided by Mineral Resource classification applied.

·     The mineralised domains (structures) at Tulkubash have demonstrated sufficient continuity in both geology and grade to support the definition of Mineral Resources and the classifications applied under the 2012 JORC Code guidelines.

·      Drill lines are oriented East-West on a 42°rotated grid to the East, and perpendicular to the deposit strike.

·     Drilling is predominantly inclined at multiple angles, including underground drill stations.

·     Considering the multiple orientations of drill holes at Tulkubash, there is no sampling bias due to drilling orientation.

·      Samples are bagged in labelled polyethylene bags on site and consolidated in rice sacks for transport. Samples are transported by Chaarat personnel directly to the prep lab in Kara Balta. Core boxes are collected on site by Chaarat personnel and transported to a core storage facility in Bishkek.

·      Samples are transported between IRC and Stewart labs by laboratory personnel. Samples are picked up from IRC and/or ALS Stewart for transport to Bishkek by Chaarat Personnel. A Sample Dispatch Form listing the samples and sample weight is signed by the Chaarat driver on receiving the samples and by the driver and the Stewart representative on the transfer of the samples to the lab. A copy of the Sample Dispatch Form is then signed by the Chaarat driver at the pickup at the assay lab and the samples are signed in to the Bishkek core and sample storage facility.

·      No external audits have been performed.

·      Resource estimation work and report developed by an independent third party.

·     Internal Chaarat Gold peer review processes have been completed. These reviews concluded that the fundamental data collection, geological modelling, and grade estimation are appropriate.

·      Chaarat Zaav (the Kyrgyzstan subsidiary of Chaarat) received its initial exploration license (No. Au-174-02) for the property on 10th December 2002. The current exploration license number 3319 AP was issued on 7th October 2013 and is valid through 7th October 2023. The Chaarat Project consists of the 10 kilometres of strike length in the centre of the 15,425 hectare license area.

·      An additional developmental license number 3117AE was issued 22nd January 2014 covering the core 700 hectares of the Chaarat Project. This license is valid through 25th June 2032.

·      The Competent Person (CP) for this report relies on the client's assertion that all relevant permits, tax payments, and filings are current and correct.

·      Initial exploration work conducted at the Project was carried out during the 1970s under the Soviet regime. The initial work involved construction of three exploration adits (two of which remain open). The primary mineral target at the time was antimony and there was no sampling carried out for precious metals as part of this exploration program.

·      The first modern exploration was carried out in the 1990s by a joint venture between Apex Asia and Newmont. This program included 7 drill holes, 5634 surface trench samples, and geophysical surveys. The results of this work are included in the current project database.

·      Chaarat acquired the project in 2002 and began exploration work in 2004. Chaarat exploration has included the construction of Adit 4 in the Contact zone, surface and underground drilling, and surface and underground sampling.

·      All work since 2002 has been carried out by Chaarat and its contractors.

·      There are three main mineralised zones: Contact, Main, and Tulkubash; these zones present different geologic characteristics, but share the overall continuity of the mineralized zones.

·      The current Resource Estimate and Report refer only to Tulkubash.

·      Tulkubash is a mineralised shear zone that is continuous along strike; all mineralized zones share in having similar geometries, strikes, and dips; and are traceable for more than a kilometre with diamond drill holes. They have been traced for several kilometres along strike through mapping and trenching.

·      Tulkubash is lower grade, generally free-milling mineralisation and wider in general, compared to the other zones within Chaarat; some cross-cutting high grade stibnite veins have been observed, which are sub-parallel to the section lines.

·     There are clear visual clues to detect the mineralised shear zone, such as quartz-carbonate veining, shearing, and veining.

·      All drilling data has been used for geological interpretation and Mineral Resource estimation.

·      The following is the summary of the database for Chaarat, and includes Tulkubash:

·      The Tulkubash assay database was prepared in MineSight using the desurveying process which assigns to each drill hole interval with Au grades a X/Y/Z coordinate. The assay database was coded with the geologic information and the interpreted mineralized zones.

·      Sampling procedures at Tulkubash are such that most of the samples are 1.5m long, although there are exceptions to this. Three-meter composites were obtained to maintain or achieve mostly uniform support; to introduce some down the hole dilution to better reflect the grade mixing expected at the time of mining; and to reduce the variability of gold grades in the samples.

·     Spatial restrictions for outlier Au grades were used during the estimation of the Tulkubash resources. The definition of "outlier Au grades" changed according to the grade estimation domain defined.

·      Drill holes, surface trenches, and underground sampling channels intersect mineralized zones at a number of different angles, ranging from perpendicular to oblique to the mineralization.

·     Since the work is performed in cross sections, and also because of the large amount of drill data, it is not expected that the drill hole orientations have a material impact on the estimation of grade.

·      See main body and other appendices of the Report

·      Not applicable in the context of a Resource Estimate Report.

·      Chaarat Gold has carried out extensive geologic mapping and surface sampling along extensions of the drilled structures within the project area, and for some 5km of strike length to the northeast of the main project area.

·      There are several additional areas of mineralization which have been identified, and which are slated for further exploration as time and funding permit.

·      Additional drilling targeted at extending Tulkubash zone mineralization would be beneficial to the project. Tulkubash is also open at depth. Drilling to date has been focused on the upper, oxidized portion of Tulkubash because it is amenable to cyanide leaching, and there has been limited drilling at depth.

·      All drilling data is securely stored in Excel spreadsheets. The database is backed up by Chaarat off- and on site, as well as GSI keeping multiple secure copies of the database.

·      The drill hole database used for Mineral Resource estimation has been internally validated and externally audited, by Gustavson and Associates (2014), and by GeoSystems International (GSI, 2017), in the context of preparing the current Resource Model update.

·      Drill hole data is validated visually by domain and compared to the geological model.

·     Multiple checks have been completed on the database, such as: checks of grades against original laboratory certificates; checks by grade ranges; checks of hole locations; checks of duplicate and overlapping intervals; checks of geological coding; checks by zone coding; checks for intervals with poor recoveries; higher grade interval checks; etc.

·      The Competent Person visited Chaarat from August 25^th through August 28^th, 2014. And again from August 30^th through September 3^rd, 2017.

·      Overall the Competent Person's confidence in the geological interpretation of the area is good, based on the quantity and quality of data available, and the continuity and nature of the mineralisation.

·      Geological modelling was performed by Chaarat geologists, and checked by GSI's contractors. The method involves interpretation on cross sections of the 0.25 gpt Au grade envelope which defines the mineralisation boundaries. Three-dimensional wireframes of the sectional interpretations are created to produce the geological model.

·      There are also geologic interpretations of several logged attributes: oxidation level; lithology; type of alteration; intensity of alteration; and silicification; these interpretations were also modelled in three-dimensions (wireframe), and for the basis for the grade estimation domains used within the grade shells.

·      Mineralisation is continuous. It is affected by structures, but the drill hole spacing is sufficient to capture grade and geology changes at the scale of observation.

·     The geological model is sub-divided into 7 grade domains, in addition to the mineralized zones, and both the composites and model blocks are coded with these domains. The grade domains are used to constrain further the estimation, and are used in addition to the wireframes that represent the mineralized zones.

·      Mineralisation extends for several kilometres along strike in an SW-NE. The Tulkubash zone extends for several hundred metres along strike.

·      The mineralised structures are between a few metres and up to 20-40 metres across strike, and to a depth of no less than 250m below current topographical surface.

·      Tulkubash was estimated using ordinary kriging for Au, Ag, As, and Sb.

·      Inverse Distance Squared was used to estimate in situ bulk dry density in the vicinity where data has been collected; other regions of the model with sparse information were assigned in situ bulk dry density averages by lithology.

·      Correlogram models as required by the estimation method chosen were obtained for all variables and grade domains.

·      These methods are appropriate for estimating the tonnes and grade of the reported Mineral Resources.

·      A block size of 10 m (X) × 10 m (Y) × 5 m (Z) was used for parent blocks. Parent blocks are sub-celled to the geological boundaries to increase the resolution of the contacts in the block model.

·      The Tulkubash mineralized zones were estimated using only composites within the 0.25 gpt Au grade wireframe that describes the zone. An additional estimation of spotty mineralization outside the mineralized zones was also performed using the 3m composites lying outside of the mineralized zones. This external estimation was constrained by the same grade domains defined inside the grade shells, in addition to an external envelope that limits extrapolation to less than 40m. This material adds a small percentage of the total resource.

·      Detailed statistical analysis was performed on the assay and the composite data.

·      High yield limit were applied to all grades to restrict higher grade samples' to a 10m radii range of influence. In the case of Au, these limits varied by grade estimation domain.

·      The grade estimation process was completed using MineSight software.

·      Grades are mostly interpolated, and only extrapolated at depth down to approximately 30m below the deepest composites. Some lateral extrapolation is also present outside the mineralized zones, up to a maximum of 40m.

·      The block model was validated using a combination of visual and statistical techniques.

·      All Mineral Resource tonnages are estimated and reported on a dry basis.

·      Cutoff of interest begin at approximately 0.2 gpt Au.

·      The Resources reported are within a "resource pit" which has been optimized using a Lerchs-Grossman-type algorithm. The economic parameters for obtaining the pit are the same as those used by Chaarat Gold on the upcoming Feasibility Study, except that the gold price was set at USD 1,500/oz. The breakeven economic cutoff using these parameters is approximately 0.22 gpt.

·      The final economic cutoff will be determined with further engineering studies, which will include variable cutoff optimization, and will likely result in a cutoff higher than the reserves breakeven cutoff.

·      Development of this Mineral Resource assumes mining using standard open pit methods, including conventional truck and shovel at an appropriate bench height.

·      Mining practices will include grade control, likely utilising blast hole data.

·      Current metallurgical testing shows that free milling (heap leaching) of the Tulkubash ore is possible, and that a standard beneficiation method will be applied.

·      The Resource has been defined with a "resource pit", which, among other economic parameters, assumes a 72% metallurgical recovery for Au, and a 48% metallurgical recovery for Ag. These metallurgical recovery factors have been obtained as averages of the metallurgical sampling of Tulkubash ore reported to date.

·      There are no environmental issues or assumptions made that would impact on the Mineral Resource estimate.

·      Dry core densities are generated by first covering the 15 to 20 cm long piece of core with paraffin; and then using the immersion method to obtain the density value, and taking into account the paraffin weight.

·      Dry bulk density was estimated using the Inverse Distance Squared method

·      The model has been classified into the categories of Measured, Indicated and Inferred.

·      Resources were classified with consideration to the following criteria: 1) The quality of the data gathering, data management, assays and geologic information; 2) Confidence in the geological conceptual model, mapping and interpretation, and limitations of the geological model related to drill hole spacing and the characteristics of the wireframes modelled; 3) Drill hole spacing and orientation within the mineralized zone; and 4) Gold grade's spatial distribution and continuity, as observed from statistical and geostatistical analyses. Ag, Sb, and As continuity was not a resource classification criteria.

·      The determination of the applicable Mineral Resource category has considered the average data density for the respective domains, the interpreted geological continuity and the estimation strategy.

·      The Competent Person is satisfied that the stated Mineral Resource classification reflects the data spacing, data quality, level of geological continuity and the estimation constraints of the deposits.

·      All stages of Mineral Resource estimation have undergone a documented internal peer review process, which has documented all phases of the process.

·      The Mineral Resource data collection and estimation techniques used for the Tulkubash deposit are consistent with those applied at other deposits of similar characteristics.

·      No production reconciliation is currently possible. Further infill drilling has been recommended to test possible extensions to the current resource, as well as further reduce uncertainties in the Resource Estimate.