Hebbard, E.R., Wilson, S.A., Jowitt, S.M., Tait, A.W., Turvey, C.C., Wilson, H.L. (2017): Regrowth of arsenate-sulfate efflorescences on processing plant walls at the Ottery arsenic-tin mine, New South Wales, Australia: Implications for arsenic mobility and remediation of mineral processing sites. Applied Geochemistry 79, 91-106.

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	Hebbard, Emily R., Wilson, Siobhan A., Jowitt, Simon M., Tait, Alastair W., Turvey, Connor C., Wilson, Harriet L. (2017) Regrowth of arsenate–sulfate efflorescences on processing plant walls at the Ottery arsenic–tin mine, New South Wales, Australia: Implications for arsenic mobility and remediation of mineral processing sites. Applied Geochemistry, 79. 91-106 doi:10.1016/j.apgeochem.2017.01.015
	Turvey, C.C., Wilson, S.A., Hamilton, J.L., Tait, A.W., McCutcheon, J., Beinlich, A., Fallon, S.J., Dipple, G.M., Southam, G. (2018) Hydrotalcites and hydrated Mg-carbonates as carbon sinks in serpentinite mineral wastes from the Woodsreef chrysotile mine, New South Wales, Australia: Controls on carbonate mineralogy and efficiency of CO2 air capture in mine tailings. International Journal of Greenhouse Gas Control, 79, 38-60.
	Hamilton, J.L., Wilson, S.A., Turvey, C.C., Morgan, B., Tait, A.W., McCutcheon, J., Fallon, S.J., Southam, G. (2021) Carbon accounting of mined landscapes, and deployment of a geochemical treatment system for enhanced weathering at Woodsreef Chrysotile Mine, NSW, Australia. Journal of Geochemical Exploration, 220. 106655pp. doi:10.1016/j.gexplo.2020.106655
	Turvey, C. C., Wilson, S. A., Hamilton, J. L., Tait, A. W., McCutcheon, J., Beinlich, A., ... & Southam, G. (2018). Hydrotalcites and hydrated Mg-carbonates as carbon sinks in serpentinite mineral wastes from the Woodsreef chrysotile mine, New South Wales, Australia: Controls on carbonate mineralogy and efficiency of CO2 air capture in mine tailings. International Journal of Greenhouse Gas Control, 79, 38-60.
	Haffert, Laura, Craw, Dave (2008) Mineralogical controls on environmental mobility of arsenic from historic mine processing residues, New Zealand. Applied Geochemistry, 23 (6) 1467-1483 doi:10.1016/j.apgeochem.2007.12.030
	Paktunc, D., Majzlan, J., Palatinus, L., Dutrizac, J., Klementová, M. & Poirier, G. (2013) Characterization of ferric arsenate-sulfate compounds: Implications for arsenic control in refractory gold processing residues. American Mineralogist 98, pages 554–565.
	Paktunc, D., Bruggeman, K. (2010) Solubility of nanocrystalline scorodite and amorphous ferric arsenate: Implications for stabilization of arsenic in mine wastes. Applied Geochemistry, 25 (5) 674-683 doi:10.1016/j.apgeochem.2010.01.021
	Liu, Ying, Zhao, Jia, Chen, Shu, Yao, Jun, Liu, Jing (2024) Removal of arsenic from realgar-containing water by Spirogyra: Implications for in situ remediation of arsenic in the mine area. Applied Geochemistry, 160. 105873 doi:10.1016/j.apgeochem.2023.105873
	Haffert, L., Craw, D., Pope, J. (2010) Climatic and compositional controls on secondary arsenic mineral formation in high-arsenic mine wastes, South Island, New Zealand. New Zealand Journal of Geology and Geophysics, 53, 91-101.
	Jamieson, H. E. (2014, January 1st) The Legacy of Arsenic Contamination from Mining and Processing Refractory Gold Ore at Giant Mine, Yellowknife, Northwest Territories, Canada. Reviews in Mineralogy and Geochemistry Vol. 79. Mineralogical Society of America p.533-551. doi:10.2138/rmg.2014.79.12
	Nixon, L.G. (1959) Second Report on Talisker Lead-Arsenic Mine. Mineral Resources Section, Geological Survey, Department of Mines, South Australia.