Australian Vanadium Limited announced that it has produced high-purity 99.5% V2O5 marketing samples in the final stage of metallurgical testing for the bankable feasibility study (BFS). The V2O5 was recovered from leach solutions generated in AVL's recent hydrometallurgy pilot program1 via the ammonium metavanadate (AMV) process. This work in turn followed the pyrometallurgy pilot runs conducted at Metso Outotec's Dansville facilities in the USA2 and the beneficiation pilot program conducted at ALS Metallurgy in Perth3. The feed materials for this sequence of pilot programs comprised two composites of drill core, designed to be indicative of the average first five years of production and life of mine production4. A sample of V2O5, alongside AVL's pelletised vanadium concentrate and a sample of ore is shown in Figure 1. The AMV precipitation process was selected over other options due to its applicability to high-purity leach solutions, such as those generated in AVL's pilot program. It is conducted at ambient temperature, near-neutral pH and has simple process control requirements. Silica is removed beforehand by a well-established method known as "desilication", achieved by the addition of aluminium sulfate to the leach solution, leading to selective silica precipitation and removal. The final metallurgical process is to heat the AMV precipitate at 650°C to convert it to high-purity V2O5. The suite of assays for the V2O5 product is shown in Table 1. The V2O5 generated in this pilot program meets market specifications for the production of high- strength steel alloys. The high purity achieved for this product simplifies continuing work with AVL's research partners in the CRC-P to further increase the product purity for the battery industry. This will lead to the design of an ultra-high purity process to feed AVL's future electrolyte plant, for which a grant was awarded through the Federal Government's Modern Manufacturing Initiative5. Supply and quality of V2O5 are critical for the development of the vanadium redox flow battery (VRFB) market which is expected to grow rapidly in coming years. Estimates vary between 27,000 tonnes V2O5 per annum by 2030 from Roskill and 44,000 tonnes V2O5 per annum by 2025 from TTP Squared, the latter approximately 15% of the expected global vanadium market in 2025. AVL intends to produce 11,000 tonnes of V2O5 per annum, with a portion dedicated to the battery market. AVL has signed MOUs with a number of VRFB manufacturers such as CellCube, E22 and VFlow Tech to help meet demand. This work concludes the metallurgical testwork program for the BFS. The work was partly funded by the Australian Government's Cooperative Research Centre Projects scheme. Work under this scheme is continuing outside the BFS on programs such as downstream electrolyte production and value-adding to process waste streams.