Johnson, D BarrieDybowska, AgnieszkaSchofield, PaulHerrington, Richard JSmith, Sarah LSantos, Ana Laura2022-08-262022-08-2619/06/20202020-04-01D. Barrie Johnson, Agnieszka Dybowska, Paul F. Schofield, Richard J. Herrington, Sarah L. Smith, Ana Laura Santos, Bioleaching of arsenic-rich cobalt mineral resources, and evidence for concurrent biomineralisation of scorodite during oxidative bio-processing of skutterudite, Hydrometallurgy, Volume 195, 2020, 105395, ISSN 0304-386X, https://doi.org/10.1016/j.hydromet.2020.105395.0304-386X10.1016/j.hydromet.2020.105395http://hdl.handle.net/10141/623015Experiments were carried out to test the amenabilities of mineral deposits that contained cobalt deported in arseno-sulfide (cobaltite) and arsenide (skutterudite) minerals, to oxidative bioleaching at mesophilic temperatures and low pH. An ore sample from the Iron Mask deposit (Canada) and a mineral concentrate from a working mine (Bou Azzer, Morocco) were thoroughly characterised, both prior to and following bio-processing. A “top down” approach, using microbial consortia including (initially) 13 species of mineral-degrading acidophiles was used to bioleach the ore and concentrate in shake flasks and bioreactors. Cobalt was successfully liberated from both materials tested (up to 93% from the ore, and 49% from the concentrate), though the chemistries of the leach liquors were very different, with redox potentials being >200 mV lower, and concentrations of soluble arsenic about 7-fold greater, with the concentrate. Addition of pyrite to the arsenide concentrate was found to promote the biomineralisation of scorodite (ferric arsenate), which was detected by both XRD and SEM-EDX, but was not found in bioleached residues of the arseno-sulfide ore. A model was proposed wherein pyrite had three critical roles in facilitating the genesis of scorodite: (i) providing the catalytic surface to promote the oxidation of As (III) to As (V); (ii) acting as a putative “seed” for scorodite crystallisation; (iii) being a secondary source of iron, since the molar ratios of iron:arsenic in the concentrate itself (0.19:1) was well below that required for effective removal of soluble arsenic as scorodite (1:1). This work provided proof of concept that cobalt arseno-sulfide and arsenide ores and concentrates are amenable to bio-processing, and also that it is possible to induce concurrent solubilisation of arsenic from primary minerals and immobilisation in a secondary mineral, scorodite.enopenAccesshttps://creativecommons.org/licenses/by/4.0/Journal Article1879-1158Hydrometallurgy2022-08-24195105395-105395arsenicbioleachingcobaltcobaltitescoroditeskutterudite