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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

dc.contributor.authorTurvey, Connor C.
dc.contributor.authorWilson, Siobhan
dc.contributor.authorHamilton, Jessica L.
dc.contributor.authorTait, Alastair
dc.contributor.authorMcCutcheon, Jenine
dc.contributor.authorBeinlich, Andreas
dc.contributor.authorFallon, Stewart
dc.contributor.authorDipple, Greg
dc.contributor.authorSoutham, Gordon
dc.date.accessioned2020-01-10T03:08:47Z
dc.date.issued2018
dc.date.updated2019-08-25T08:18:59Z
dc.description.abstractCarbon mineralisation of ultramafic mine tailings can reduce net emissions of anthropogenic carbon dioxide by reacting Mg-silicate and hydroxide minerals with atmospheric CO2 to produce carbonate minerals. We investigate the controls on carbonate mineral formation at the derelict Woodsreef chrysotile mine (New South Wales, Australia). Quantitative XRD was used to understand how mineralogy changes with depth into the tailings pile, and shows that hydromagnesite [Mg5(CO3)4(OH)2·4H2O], is present in shallow tailings material (<40 cm), while coalingite [Mg10Fe3+ 2(CO3)(OH)24·2H2O] and pyroaurite [Mg6Fe3+ 2(CO3)(OH)16·4H2O] are forming deeper in the tailings material. This indicates that there may be two geochemical environments within the upper ∼1 m of the tailings, with hydromagnesite forming within the shallow tailings via carbonation of brucite in CO2-rich conditions, and pyroaurite and coalingite forming under more carbon limited conditions at depth. Radiogenic isotope results indicate hydromagnesite and pyroaurite have a modern (F14C > 0.8) atmospheric CO2 source. Laboratory-based anion exchange experiments, conducted to explore stable C isotope fractionation in pyroaurite, shows that pyroaurite δ13C values change with carbon availability, and 13C-depleted signatures are typical of hydrotalcites in C-limited environments, such as the deep tailings at Woodsreef. Quantitative XRD and elemental C data estimates that Woodsreef absorbs between of 229.0–405.1 g CO2 m−2 y−1.en_AU
dc.description.sponsorshipWe would like to acknowledge funding from Carbon Management Canada and the New South Wales Department of Industry to S.A.W., G.M.D. and G.S. Work by C.C.T., J.L.H. and A.W.T. was supported by Australian Postgraduate Awardsen_AU
dc.format.mimetypeapplication/pdfen_AU
dc.identifier.issn1750-5836en_AU
dc.identifier.urihttp://hdl.handle.net/1885/196859
dc.language.isoen_AUen_AU
dc.publisherElsevier BVen_AU
dc.rights© 2018 Elsevier Ltden_AU
dc.sourceInternational Journal of Greenhouse Gas Controlen_AU
dc.titleHydrotalcites 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 tailingsen_AU
dc.typeJournal articleen_AU
local.bibliographicCitation.lastpage60en_AU
local.bibliographicCitation.startpage38en_AU
local.contributor.affiliationTurvey, Connor C, Monash Universityen_AU
local.contributor.affiliationWilson, Siobhan, Monash Universityen_AU
local.contributor.affiliationHamilton, Jessica L, Monash Universityen_AU
local.contributor.affiliationTait, Alastair, Monash Universityen_AU
local.contributor.affiliationMcCutcheon, Jenine, University of Queenslanden_AU
local.contributor.affiliationBeinlich, Andreas, University of British Columbiaen_AU
local.contributor.affiliationFallon, Stewart, College of Science, ANUen_AU
local.contributor.affiliationDipple, Greg, University of British Columbiaen_AU
local.contributor.affiliationSoutham, Gordon, University of Queenslanden_AU
local.contributor.authoruidFallon, Stewart, u9708405en_AU
local.description.embargo2037-12-31
local.description.notesImported from ARIESen_AU
local.identifier.absfor040202 - Inorganic Geochemistryen_AU
local.identifier.absfor040203 - Isotope Geochemistryen_AU
local.identifier.absseo960302 - Climate Change Mitigation Strategiesen_AU
local.identifier.ariespublicationu3102795xPUB46en_AU
local.identifier.citationvolume79en_AU
local.identifier.doi10.1016/j.ijggc.2018.09.015en_AU
local.identifier.scopusID2-s2.0-85054904028
local.publisher.urlhttps://www.elsevier.com/en_AU
local.type.statusPublished Versionen_AU

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