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Enargite oxidation: A review
Enargite, Cu 3AsS 4, is common in some deposit types, e.g. porphyry systems and high sulphidation epithermal deposits. It is of environmental concern as a potential source of arsenic. In this communication, we review the current knowledge of enargite oxidation, based on the existing literature and o...
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| Published in: | Earth-science reviews 2008, Vol.86 (1), p.62-88 |
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| creator | Lattanzi, Pierfranco Da Pelo, Stefania Musu, Elodia Atzei, Davide Elsener, Bernhard Fantauzzi, Marzia Rossi, Antonella |
| description | Enargite, Cu
3AsS
4, is common in some deposit types, e.g. porphyry systems and high sulphidation epithermal deposits. It is of environmental concern as a potential source of arsenic. In this communication, we review the current knowledge of enargite oxidation, based on the existing literature and our own original data.
Explicit descriptions of enargite oxidation in natural environments are scarce. The most common oxidized alteration mineral of enargite is probably scorodite, FeAsO
4.2H
2O, with iron provided most likely by pyrite, a phase almost ubiquitously associated with enargite. Other secondary minerals after enargite include arsenates such as chenevixite, Cu
2Fe
2(AsO
4)
2(OH)
4.H
2O, and ceruleite, Cu
2Al
7(AsO
4)
4.11.5H
2O, and sulphates such as brochantite, Cu
4(SO
4)(OH)
6, and posnjakite, Cu
4(SO
4)(OH)
6·H
2O. Detailed studies of enargite field alteration at Furtei, Sardinia, suggest that most alteration occurs through dissolution, as testified by the appearance of etch pits at the surface of enargite crystals. However, apparent replacement by scorodite and cuprian melanterite was observed.
Bulk oxidation of enargite in air is a very slow process. However, X-ray photoelectron spectroscopy (XPS) reveals subtle surface changes. From synchrotron-based XPS it was suggested that surface As atoms react very fast, presumably by forming bonds with oxygen. Conventional XPS shows the formation, on aged samples, of a nanometer-size alteration layer with an appreciably distinct composition with respect to the bulk. Mechanical activation considerably increases enargite reactivity.
In laboratory experiments at acidic to neutral pH, enargite oxidation/dissolution is slow, although it is accelerated by the presence of ferric iron and/or bacteria such as
Acidithiobacillus ferrooxidans and
Sulfolobus BC. In the presence of sulphuric acid and ferric iron, the reaction involves dissolution of Cu and formation of native sulphur, subsequently partly oxidized to sulphate. At alkaline pH, the reactivity of enargite is apparently slightly greater. XPS spectra of surfaces conditioned at pH 11 have been interpreted as evidence of formation of a number of surface species, including cupric oxide and arsenic oxide. Treatment with hypochlorite solutions at pH 12.5 quickly produces a coating of cupric oxide.
Electrochemical oxidation of enargite typically involves low current densities, confirming that the oxidation process is slow. Important surface changes occur only at h |
| doi_str_mv | 10.1016/j.earscirev.2007.07.006 |
| format | article |
| fullrecord | <record><control><sourceid>proquest_cross</sourceid><recordid>TN_cdi_proquest_miscellaneous_20706627</recordid><sourceformat>XML</sourceformat><sourcesystem>PC</sourcesystem><els_id>S0012825207001158</els_id><sourcerecordid>20706627</sourcerecordid><originalsourceid>FETCH-LOGICAL-a396t-48427e79f09cec1431b98936ec7d9e5b419dda60dea5b2f9b1823a94b1bd12643</originalsourceid><addsrcrecordid>eNqFkEtLAzEUhYMoWKv_QLC4cDfjTWaah7si9QEFN7oOmeSOZGgnNZn6-PdmqLhwI1y4XPjO4Z5DyAWFkgLl112JJibrI76XDECU4wA_IBMqBSu4ZPKQTAAoKySbs2NyklIH-QYlJuR82Zv46gechU_vzOBDfzNbzLKZx49TctSadcKznz0lL3fL59uHYvV0_3i7WBWmUnwoalkzgUK1oCxaWle0UVJVHK1wCudNTZVzhoNDM29YqxoqWWVU3dDGUcbrakqu9r7bGN52mAa98cniem16DLukGQjgnIkMXv4Bu7CLff5Ns4rnQBJGN7GHbAwpRWz1NvqNiV-agh4r053-rUyPlelxgGflYq_EHDYXEHWGsLfoMmoH7YL_1-Mb_J125g</addsrcrecordid><sourcetype>Aggregation Database</sourcetype><iscdi>true</iscdi><recordtype>article</recordtype><pqid>236097804</pqid></control><display><type>article</type><title>Enargite oxidation: A review</title><source>Elsevier</source><creator>Lattanzi, Pierfranco ; Da Pelo, Stefania ; Musu, Elodia ; Atzei, Davide ; Elsener, Bernhard ; Fantauzzi, Marzia ; Rossi, Antonella</creator><creatorcontrib>Lattanzi, Pierfranco ; Da Pelo, Stefania ; Musu, Elodia ; Atzei, Davide ; Elsener, Bernhard ; Fantauzzi, Marzia ; Rossi, Antonella</creatorcontrib><description>Enargite, Cu
3AsS
4, is common in some deposit types, e.g. porphyry systems and high sulphidation epithermal deposits. It is of environmental concern as a potential source of arsenic. In this communication, we review the current knowledge of enargite oxidation, based on the existing literature and our own original data.
Explicit descriptions of enargite oxidation in natural environments are scarce. The most common oxidized alteration mineral of enargite is probably scorodite, FeAsO
4.2H
2O, with iron provided most likely by pyrite, a phase almost ubiquitously associated with enargite. Other secondary minerals after enargite include arsenates such as chenevixite, Cu
2Fe
2(AsO
4)
2(OH)
4.H
2O, and ceruleite, Cu
2Al
7(AsO
4)
4.11.5H
2O, and sulphates such as brochantite, Cu
4(SO
4)(OH)
6, and posnjakite, Cu
4(SO
4)(OH)
6·H
2O. Detailed studies of enargite field alteration at Furtei, Sardinia, suggest that most alteration occurs through dissolution, as testified by the appearance of etch pits at the surface of enargite crystals. However, apparent replacement by scorodite and cuprian melanterite was observed.
Bulk oxidation of enargite in air is a very slow process. However, X-ray photoelectron spectroscopy (XPS) reveals subtle surface changes. From synchrotron-based XPS it was suggested that surface As atoms react very fast, presumably by forming bonds with oxygen. Conventional XPS shows the formation, on aged samples, of a nanometer-size alteration layer with an appreciably distinct composition with respect to the bulk. Mechanical activation considerably increases enargite reactivity.
In laboratory experiments at acidic to neutral pH, enargite oxidation/dissolution is slow, although it is accelerated by the presence of ferric iron and/or bacteria such as
Acidithiobacillus ferrooxidans and
Sulfolobus BC. In the presence of sulphuric acid and ferric iron, the reaction involves dissolution of Cu and formation of native sulphur, subsequently partly oxidized to sulphate. At alkaline pH, the reactivity of enargite is apparently slightly greater. XPS spectra of surfaces conditioned at pH 11 have been interpreted as evidence of formation of a number of surface species, including cupric oxide and arsenic oxide. Treatment with hypochlorite solutions at pH 12.5 quickly produces a coating of cupric oxide.
Electrochemical oxidation of enargite typically involves low current densities, confirming that the oxidation process is slow. Important surface changes occur only at high applied potentials, e.g. +
0.74 V vs. SHE. It is confirmed that, at acidic pH, the dominant process is Cu dissolution, accompanied (at +
0.56 V vs. SHE, pH
=
1) by formation of native sulphur. At alkaline pH, a number of surface products have been suggested, including copper and arsenic oxides, and copper arsenates. XPS studies of the reacted surfaces demonstrate the evolution of Cu from the monovalent to the divalent state, the formation of As–O bonds, and the oxidation of sulphur to polysulphide, sulphite and eventually sulphate.
In most natural and quasi-natural (mining) situations, it is expected that enargite reactivity will be slow. Moreover, it is likely that the release of arsenic will be further slowed down by at least temporary trapping in secondary phases. Therefore, an adequate management of exposed surfaces and wastes should minimize the environmental impact of enargite-bearing deposits.
In spite of an increasing body of data, there are several gaps in our knowledge of enargite oxidation. The exact nature of most mechanisms and products remains poorly constrained, and there is a lack of quantitative data on the dependence on parameters such as pH and dissolved oxygen.</description><identifier>ISSN: 0012-8252</identifier><identifier>EISSN: 1872-6828</identifier><identifier>DOI: 10.1016/j.earscirev.2007.07.006</identifier><identifier>CODEN: ESREAV</identifier><language>eng</language><publisher>Amsterdam: Elsevier B.V</publisher><subject>Acidithiobacillus ferrooxidans ; Chemical bonds ; Chemical compounds ; Dissolution ; enargite ; laboratory experiments ; Minerals ; Oxidation ; secondary minerals ; Spectrum analysis ; Sulfolobus ; surface oxidation</subject><ispartof>Earth-science reviews, 2008, Vol.86 (1), p.62-88</ispartof><rights>2007 Elsevier B.V.</rights><rights>Copyright Elsevier Sequoia S.A. Jan 2008</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-a396t-48427e79f09cec1431b98936ec7d9e5b419dda60dea5b2f9b1823a94b1bd12643</citedby><cites>FETCH-LOGICAL-a396t-48427e79f09cec1431b98936ec7d9e5b419dda60dea5b2f9b1823a94b1bd12643</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,4024,27923,27924,27925</link.rule.ids></links><search><creatorcontrib>Lattanzi, Pierfranco</creatorcontrib><creatorcontrib>Da Pelo, Stefania</creatorcontrib><creatorcontrib>Musu, Elodia</creatorcontrib><creatorcontrib>Atzei, Davide</creatorcontrib><creatorcontrib>Elsener, Bernhard</creatorcontrib><creatorcontrib>Fantauzzi, Marzia</creatorcontrib><creatorcontrib>Rossi, Antonella</creatorcontrib><title>Enargite oxidation: A review</title><title>Earth-science reviews</title><description>Enargite, Cu
3AsS
4, is common in some deposit types, e.g. porphyry systems and high sulphidation epithermal deposits. It is of environmental concern as a potential source of arsenic. In this communication, we review the current knowledge of enargite oxidation, based on the existing literature and our own original data.
Explicit descriptions of enargite oxidation in natural environments are scarce. The most common oxidized alteration mineral of enargite is probably scorodite, FeAsO
4.2H
2O, with iron provided most likely by pyrite, a phase almost ubiquitously associated with enargite. Other secondary minerals after enargite include arsenates such as chenevixite, Cu
2Fe
2(AsO
4)
2(OH)
4.H
2O, and ceruleite, Cu
2Al
7(AsO
4)
4.11.5H
2O, and sulphates such as brochantite, Cu
4(SO
4)(OH)
6, and posnjakite, Cu
4(SO
4)(OH)
6·H
2O. Detailed studies of enargite field alteration at Furtei, Sardinia, suggest that most alteration occurs through dissolution, as testified by the appearance of etch pits at the surface of enargite crystals. However, apparent replacement by scorodite and cuprian melanterite was observed.
Bulk oxidation of enargite in air is a very slow process. However, X-ray photoelectron spectroscopy (XPS) reveals subtle surface changes. From synchrotron-based XPS it was suggested that surface As atoms react very fast, presumably by forming bonds with oxygen. Conventional XPS shows the formation, on aged samples, of a nanometer-size alteration layer with an appreciably distinct composition with respect to the bulk. Mechanical activation considerably increases enargite reactivity.
In laboratory experiments at acidic to neutral pH, enargite oxidation/dissolution is slow, although it is accelerated by the presence of ferric iron and/or bacteria such as
Acidithiobacillus ferrooxidans and
Sulfolobus BC. In the presence of sulphuric acid and ferric iron, the reaction involves dissolution of Cu and formation of native sulphur, subsequently partly oxidized to sulphate. At alkaline pH, the reactivity of enargite is apparently slightly greater. XPS spectra of surfaces conditioned at pH 11 have been interpreted as evidence of formation of a number of surface species, including cupric oxide and arsenic oxide. Treatment with hypochlorite solutions at pH 12.5 quickly produces a coating of cupric oxide.
Electrochemical oxidation of enargite typically involves low current densities, confirming that the oxidation process is slow. Important surface changes occur only at high applied potentials, e.g. +
0.74 V vs. SHE. It is confirmed that, at acidic pH, the dominant process is Cu dissolution, accompanied (at +
0.56 V vs. SHE, pH
=
1) by formation of native sulphur. At alkaline pH, a number of surface products have been suggested, including copper and arsenic oxides, and copper arsenates. XPS studies of the reacted surfaces demonstrate the evolution of Cu from the monovalent to the divalent state, the formation of As–O bonds, and the oxidation of sulphur to polysulphide, sulphite and eventually sulphate.
In most natural and quasi-natural (mining) situations, it is expected that enargite reactivity will be slow. Moreover, it is likely that the release of arsenic will be further slowed down by at least temporary trapping in secondary phases. Therefore, an adequate management of exposed surfaces and wastes should minimize the environmental impact of enargite-bearing deposits.
In spite of an increasing body of data, there are several gaps in our knowledge of enargite oxidation. The exact nature of most mechanisms and products remains poorly constrained, and there is a lack of quantitative data on the dependence on parameters such as pH and dissolved oxygen.</description><subject>Acidithiobacillus ferrooxidans</subject><subject>Chemical bonds</subject><subject>Chemical compounds</subject><subject>Dissolution</subject><subject>enargite</subject><subject>laboratory experiments</subject><subject>Minerals</subject><subject>Oxidation</subject><subject>secondary minerals</subject><subject>Spectrum analysis</subject><subject>Sulfolobus</subject><subject>surface oxidation</subject><issn>0012-8252</issn><issn>1872-6828</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2008</creationdate><recordtype>article</recordtype><recordid>eNqFkEtLAzEUhYMoWKv_QLC4cDfjTWaah7si9QEFN7oOmeSOZGgnNZn6-PdmqLhwI1y4XPjO4Z5DyAWFkgLl112JJibrI76XDECU4wA_IBMqBSu4ZPKQTAAoKySbs2NyklIH-QYlJuR82Zv46gechU_vzOBDfzNbzLKZx49TctSadcKznz0lL3fL59uHYvV0_3i7WBWmUnwoalkzgUK1oCxaWle0UVJVHK1wCudNTZVzhoNDM29YqxoqWWVU3dDGUcbrakqu9r7bGN52mAa98cniem16DLukGQjgnIkMXv4Bu7CLff5Ns4rnQBJGN7GHbAwpRWz1NvqNiV-agh4r053-rUyPlelxgGflYq_EHDYXEHWGsLfoMmoH7YL_1-Mb_J125g</recordid><startdate>2008</startdate><enddate>2008</enddate><creator>Lattanzi, Pierfranco</creator><creator>Da Pelo, Stefania</creator><creator>Musu, Elodia</creator><creator>Atzei, Davide</creator><creator>Elsener, Bernhard</creator><creator>Fantauzzi, Marzia</creator><creator>Rossi, Antonella</creator><general>Elsevier B.V</general><general>Elsevier Sequoia S.A</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7TG</scope><scope>8FD</scope><scope>F1W</scope><scope>FR3</scope><scope>H8D</scope><scope>H96</scope><scope>KL.</scope><scope>KR7</scope><scope>L.G</scope><scope>L7M</scope><scope>7QL</scope><scope>C1K</scope></search><sort><creationdate>2008</creationdate><title>Enargite oxidation: A review</title><author>Lattanzi, Pierfranco ; Da Pelo, Stefania ; Musu, Elodia ; Atzei, Davide ; Elsener, Bernhard ; Fantauzzi, Marzia ; Rossi, Antonella</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a396t-48427e79f09cec1431b98936ec7d9e5b419dda60dea5b2f9b1823a94b1bd12643</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2008</creationdate><topic>Acidithiobacillus ferrooxidans</topic><topic>Chemical bonds</topic><topic>Chemical compounds</topic><topic>Dissolution</topic><topic>enargite</topic><topic>laboratory experiments</topic><topic>Minerals</topic><topic>Oxidation</topic><topic>secondary minerals</topic><topic>Spectrum analysis</topic><topic>Sulfolobus</topic><topic>surface oxidation</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Lattanzi, Pierfranco</creatorcontrib><creatorcontrib>Da Pelo, Stefania</creatorcontrib><creatorcontrib>Musu, Elodia</creatorcontrib><creatorcontrib>Atzei, Davide</creatorcontrib><creatorcontrib>Elsener, Bernhard</creatorcontrib><creatorcontrib>Fantauzzi, Marzia</creatorcontrib><creatorcontrib>Rossi, Antonella</creatorcontrib><collection>CrossRef</collection><collection>Meteorological & Geoastrophysical Abstracts</collection><collection>Technology Research Database</collection><collection>ASFA: Aquatic Sciences and Fisheries Abstracts</collection><collection>Engineering Research Database</collection><collection>Aerospace Database</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) 2: Ocean Technology, Policy & Non-Living Resources</collection><collection>Meteorological & Geoastrophysical Abstracts - Academic</collection><collection>Civil Engineering Abstracts</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) Professional</collection><collection>Advanced Technologies Database with Aerospace</collection><collection>Bacteriology Abstracts (Microbiology B)</collection><collection>Environmental Sciences and Pollution Management</collection><jtitle>Earth-science reviews</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Lattanzi, Pierfranco</au><au>Da Pelo, Stefania</au><au>Musu, Elodia</au><au>Atzei, Davide</au><au>Elsener, Bernhard</au><au>Fantauzzi, Marzia</au><au>Rossi, Antonella</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Enargite oxidation: A review</atitle><jtitle>Earth-science reviews</jtitle><date>2008</date><risdate>2008</risdate><volume>86</volume><issue>1</issue><spage>62</spage><epage>88</epage><pages>62-88</pages><issn>0012-8252</issn><eissn>1872-6828</eissn><coden>ESREAV</coden><abstract>Enargite, Cu
3AsS
4, is common in some deposit types, e.g. porphyry systems and high sulphidation epithermal deposits. It is of environmental concern as a potential source of arsenic. In this communication, we review the current knowledge of enargite oxidation, based on the existing literature and our own original data.
Explicit descriptions of enargite oxidation in natural environments are scarce. The most common oxidized alteration mineral of enargite is probably scorodite, FeAsO
4.2H
2O, with iron provided most likely by pyrite, a phase almost ubiquitously associated with enargite. Other secondary minerals after enargite include arsenates such as chenevixite, Cu
2Fe
2(AsO
4)
2(OH)
4.H
2O, and ceruleite, Cu
2Al
7(AsO
4)
4.11.5H
2O, and sulphates such as brochantite, Cu
4(SO
4)(OH)
6, and posnjakite, Cu
4(SO
4)(OH)
6·H
2O. Detailed studies of enargite field alteration at Furtei, Sardinia, suggest that most alteration occurs through dissolution, as testified by the appearance of etch pits at the surface of enargite crystals. However, apparent replacement by scorodite and cuprian melanterite was observed.
Bulk oxidation of enargite in air is a very slow process. However, X-ray photoelectron spectroscopy (XPS) reveals subtle surface changes. From synchrotron-based XPS it was suggested that surface As atoms react very fast, presumably by forming bonds with oxygen. Conventional XPS shows the formation, on aged samples, of a nanometer-size alteration layer with an appreciably distinct composition with respect to the bulk. Mechanical activation considerably increases enargite reactivity.
In laboratory experiments at acidic to neutral pH, enargite oxidation/dissolution is slow, although it is accelerated by the presence of ferric iron and/or bacteria such as
Acidithiobacillus ferrooxidans and
Sulfolobus BC. In the presence of sulphuric acid and ferric iron, the reaction involves dissolution of Cu and formation of native sulphur, subsequently partly oxidized to sulphate. At alkaline pH, the reactivity of enargite is apparently slightly greater. XPS spectra of surfaces conditioned at pH 11 have been interpreted as evidence of formation of a number of surface species, including cupric oxide and arsenic oxide. Treatment with hypochlorite solutions at pH 12.5 quickly produces a coating of cupric oxide.
Electrochemical oxidation of enargite typically involves low current densities, confirming that the oxidation process is slow. Important surface changes occur only at high applied potentials, e.g. +
0.74 V vs. SHE. It is confirmed that, at acidic pH, the dominant process is Cu dissolution, accompanied (at +
0.56 V vs. SHE, pH
=
1) by formation of native sulphur. At alkaline pH, a number of surface products have been suggested, including copper and arsenic oxides, and copper arsenates. XPS studies of the reacted surfaces demonstrate the evolution of Cu from the monovalent to the divalent state, the formation of As–O bonds, and the oxidation of sulphur to polysulphide, sulphite and eventually sulphate.
In most natural and quasi-natural (mining) situations, it is expected that enargite reactivity will be slow. Moreover, it is likely that the release of arsenic will be further slowed down by at least temporary trapping in secondary phases. Therefore, an adequate management of exposed surfaces and wastes should minimize the environmental impact of enargite-bearing deposits.
In spite of an increasing body of data, there are several gaps in our knowledge of enargite oxidation. The exact nature of most mechanisms and products remains poorly constrained, and there is a lack of quantitative data on the dependence on parameters such as pH and dissolved oxygen.</abstract><cop>Amsterdam</cop><pub>Elsevier B.V</pub><doi>10.1016/j.earscirev.2007.07.006</doi><tpages>27</tpages></addata></record> |
| fulltext | fulltext |
| identifier | ISSN: 0012-8252 |
| ispartof | Earth-science reviews, 2008, Vol.86 (1), p.62-88 |
| issn | 0012-8252 1872-6828 |
| language | eng |
| recordid | cdi_proquest_miscellaneous_20706627 |
| source | Elsevier |
| subjects | Acidithiobacillus ferrooxidans Chemical bonds Chemical compounds Dissolution enargite laboratory experiments Minerals Oxidation secondary minerals Spectrum analysis Sulfolobus surface oxidation |
| title | Enargite oxidation: A review |
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