Reclaiming value from phosphate mine waste rock: An integrated flowsheet for sustainable recovery

Phosphate mining operations generate substantial quantities of waste rock as a byproduct of ore extraction, referred to as phosphate mine waste rock (PMWR) and stored in large stockpiles. PMWR retains significant residual phosphate yet is challenging to process due to lithological heterogeneity and a wide particle size distribution, necessitating the development of an optimized processing strategy. This study investigates a beneficiation route integrating size classification, sensor-based sorting (SBS) coupled with comminution, and reverse flotation for PMWR upgrading. Classification and sorting partitioned the material into a fine fraction (FF, <10 mm), dominated by sandy phosphate, and a coarse fraction (CF, >10 mm), composed of indured phosphate (IndP). Chemical and mineralogical analyses revealed enrichment in carbonate-fluorapatite (CFA) within the FF (63.5 %) compared to the IndP fraction (50.8 %), with more than 80 % of CFA grains free in both fractions. Reverse flotation with phosphoric acid ester and alkyl ether amine collectors, as well as phosphoric acid as depressant and pH modifier, exhibited effective gangue elimination and satisfactory selectivity, yielding an 11 % increase in CFA grade with 88.7 % recovery for the FF, and an 18 % increase with 89.4 % recovery for the IndP. Based on these outcomes, a novel process flowsheet is proposed to support resource efficiency and reduce the environmental footprint of PMWR. Valorization of residual phosphate through this approach constitutes a critical step toward advancing circular economy principles in sustainable phosphate mining.