Please use this identifier to cite or link to this item: http://hdl.handle.net/2440/78573
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Type: Journal article
Title: Can biological toxicity drive the contrasting behavior of platinum and gold in surface environments?
Author: Brugger, J.
Etschmann, B.
Grosse, C.
Plumridge, C.
Kaminski, J.
Paterson, D.
Shar, S.
Ta, C.
Howard, D.
de Jonge, M.
Ball, A.
Reith, F.
Citation: Chemical Geology, 2013; 343(8):99-110
Publisher: Elsevier
Issue Date: 2013
ISSN: 0009-2541
1872-6836
Statement of
Responsibility: 
Joël Brugger, Barbara Etschmann, Cornelia Grosse, Colin Plumridge, John Kaminski, David Paterson, Sahar Saad Shar, Christine Ta, Daryl L. Howard, Martin D. de Jonge, Andrew S. Ball and Frank Reith
Abstract: In spite of the similar chemical properties of gold (Au) and platinum (Pt), Au is highly mobile in surface environments, whereas Pt appears to be far less so. In this study we assess if geomicrobial processes are likely to cause these differences, as the mobility of Pt and Au should differ little based on thermodynamic solubility alone. To achieve an accurate comparison it is important that both metals occur in the same environment. Mineral- and groundwater samples were obtained from the Fifield Pt–Au field in New South Wales, Australia, where Pt and Au nuggets occur in a series of Tertiary eluvial and alluvial paleo-placers. In particular, we studied the μm-scale dispersion of Au and Pt within an extraordinary 10 mm-sized fragment of ferruginous paleochannel material, which contained abundant native Au- and isoferroplatinum grains. Gold grains displayed complex secondary morphologies indicative of biogeochemical transformations, whereas isoferroplatinum grains appeared smooth and well-rounded and showed no signs of supergene transformation. Gold grains were surrounded by a dusting of highly pure metallic Au particles (< 10 nm to > 10 μm in diameter), whereas no metallic Pt particles were detected. A search for ionic Pt was also unsuccessful. A series of biotic and abiotic incubation experiments was conducted to investigate the hypothesis that these differences in mobility are driven by interactions with microbiota. Biofilms consisting of metallophilic bacteria formed on ultraflat Au surfaces and caused significant surface transformations. In contrast, only subtle changes were observed on Pt surfaces incubated under similar conditions. Minimal inhibitory concentrations for Au complexes are more than an order of magnitude lower than those measured for Pt complexes in Cupriavidus metallidurans cells. This higher cell-toxicity of mobile Au- compared to Pt-complexes can lead to toxic levels of mobile Au in the vicinity of Au grain surfaces. The elevated toxicity drives the formation of Au-detoxifying biofilms that catalyze the biomineralization of spheroidal nano-particulate and bacteriomorphic Au. In contrast, this does not occur on isoferroplatinum grains due to the lower toxicity of Pt. In conclusion, these results are consistent with microbial adaptation to element toxicity driving the cycling of precious metals in surface environments.
Keywords: Gold; platinum; microbiology; environmental mobility of precious metals; synchrotron radiation; Fifield New South Wales; Australia
Rights: © 2013 Elsevier B.V. All rights reserved.
RMID: 0020126546
DOI: 10.1016/j.chemgeo.2013.02.010
Grant ID: http://purl.org/au-research/grants/arc/DP0878903
http://purl.org/au-research/grants/arc/DP20106946
Appears in Collections:Earth and Environmental Sciences publications
Environment Institute publications

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