Bluejay Mining plc announce, following a systematic review, the previously unrecognized presence of high concentrations of helium and hydrogen gases at its wholly owned Outokumpu Project, in Finland. Independent studies associated with deep drilling results by the Geological Survey of Finland ('GTK') ('Outokumpu Deep Drillhole'), identified significant potential for these gases, particularly within serpentinized ophiolites and associated geological formations, in the region ('Outokumpu Belt'). Systematic review of historical government drilling has indicated the presence of substantial industrial gas including helium and white hydrogen concentrations within the Outokumpu Belt.

Best intersection recorded was of 100m at 5.6% helium (within an intersection of 1500m, at 1.5% helium). Deposit is comparable in formation and structure to the world's largest known deposit of white (or geological) hydrogen ('White Hydrogen'), which was recently discovered in France, with estimates suggesting up to 46 million tonnes of the carbon-neutral fuel in the French deposit. This newly discovered gas province is located in the Lorraine region, a French mining region similar in nature geologically to the Outokumpu Belt.

Gas sampling from the Outokumpu Deep Drillhole, which reached a total depth of 2480 meters, revealed high concentrations of other naturally forming industrial gasses such as argon, xenon, krypton, White Hydrogen and helium (with hydrogen being the dominant gas) returning results up to 46% hydrogen in gas samples taken from various saline groundwater samples. The Outokumpu Belt's unique geological composition, including serpentinized ophiolites and pegmatitic granites, hosts multiple potential sources for the generation of White Hydrogen and helium gases. Bluejay, through its wholly-owned subsidiary FinnAust, has exploration permits covering this gas-rich ophiolite belt.

Over 2000 historical drillholes, some exceeding depths of 1000 meters, provide a comprehensive foundation to fast-track the assessment of subsurface industrial gas across the Outokumpu Belt. Current exploration licenses include gas exploration, ensuring a streamlined regulatory pathway. White Hydrogen can be produced at a fraction of the cost of "Green" Hydrogen (produced using wind and solar power), that could then potentially be integrated into Finland's goal to enhance energy security within a circular economy.

The Company will now begin to systematically assess historical drillholes for the most prospective occurrences of industrial gasses including hydrogen and helium with a view to re-entering these holes to undertake further testing using modern, more accurate, equipment. Re-entering historical drillholes offers a considerable cost savings in comparison to new drilling, and virtually eliminates the programs environmental impact. These findings will be compared with historical and newly acquired seismic data to identify areas with the highest potential.

The Outokumpu Belt, with its serpentinized ophiolites, represents a significant potential target area for hydrogen exploration. FinnAust's exploration permits cover most of the serpentinites of the Outokumpu Belt. Although gas research has been limited (to the Outokumpu Deep Drillhole), the highest single hydrogen measurement recorded was 46% in the gas component of groundwater samples.

The same deep drillhole averaged 1.54% Helium over a 1500m interval, with 100m at 5.60% helium recorded. The Outokumpu assemblage rocks, which include hydrothermally altered mantle-derived ultramafic rocks (ophiolites) and are often wrapped with graphitic and sulphidic black schists, are associated with all discovered Outokumpu-type sulphide ore shoots. Due to active historical metal exploration, there are over 2000 surface drillholes in the Outokumpu Belt, with some drilled deeper than 1000 meters.

These deeper drillholes represent opportunities for further exploration of hydrogen and helium. Bluejay Mining is currently assessing the feasibility of leveraging these historical drillholes for new sampling initiatives. The primary historical study of hydrogen and helium potential in the Outokumpu Belt is an MSc thesis by Nina Heikkinen from the University of Helsinki (2016), which investigated gases in saline groundwater of the 2.5 km deep Outokumpu Deep Drillhole.

This hole was drilled by NEDRA for the Geological Survey of Finland (GTK) in 2004-2005. Outokumpu Deep Drillhole: · Gas Composition in Groundwater:Saline groundwaters in crystalline bedrock can contain significant amounts of methane, nitrogen, hydrogen, and helium. The solubility of these gases in water increases with depth due to higher pressure, temperature, and salinity.

Maximum Solubilities:For methane, nitrogen, hydrogen, and helium, maximum solubilities were determined at temperatures of 273-323 K, pressures of 1-300 bar, and salinities of 0-2 molal concentration. The solubility of gases increases significantly with higher pressure and salinity. This was applied to the 2.5 km deep Outokumpu Deep Drillhole samples from 2011-2012.

Sampling Data:Gas samples were collected from depths of 180, 500, 970, 1470, 1820, 2350, and 2480 meters using pressurized techniques to maintain in-situ pressure until analysis. This method provided accurate data on gas concentrations at specific depths. Dominant Gases:Methane and nitrogen are the most represented gases.

Hydrogen is the dominant gas in the deepest part of the drillhole. The highest concentration of gases was observed at a depth of 970 meters. Hydrostatic Pressure and Gas Bubbles:At a depth of 180 meters, the sum of the partial pressures of the gases (approximately 13 bar) was nearing the hydrostatic pressure (approximately 18 bar).

Gas bubbles are likely to escape from the solution at depths of 150 meters and above. Below 180 meters, due to significant pressure, all gases are likely dissolved in water. Helium and Hydrogen Content:Helium content remained stable from 300 meters depth to the end of the drillhole.

In contrast, hydrogen content increased rapidly after 1500 meters depth, correlating with an increase in water salinity. Geological Correlation:The increase in salinity and hydrogen content begins immediately below the section of the Outokumpu assemblage rocks, which are hydrothermal products of mantle-derived ultramafic rocks (ophiolites). Pegmatitic granite could serve as an additional hydrogen source due to the potential breaking up of H2O molecules by radioactive components.