Redox chemistry in two iron-bentonite field experiments at Aspo Hard Rock Laboratory, Sweden; an XRD and Fe K-edge XANES study

Excavated bentonite from two large iron--bentonite field experiments at Aspo Hard Rock Laboratory in Sweden was investigated with respect to iron redox chemistry and mineralogy. The iron redox chemistry was studied by Fe K-edge X-ray absorption near edge structure spectroscopy and the mineral phases...

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Veröffentlicht in:	Clays and clay minerals 2013-12, Vol.61 (6), p.566-579
Hauptverfasser:	Svensson, Per Daniel, Hansen, Staffan
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Sprache:	eng
Schlagworte:	A &uml ABM Alteration Alternative Buffer Material Aspo Bentonite Biogeosciences Buffers (chemistry) chemical properties Chemical Sciences clastic rocks clay mineralogy clay minerals Earth and Environmental Science Earth Sciences Earth, ocean, space Exact sciences and technology experimental studies Geochemistry Iron Kemi laboratory studies Medicinal Chemistry Mineralogy Montmorillonite Nanoscale Science and Technology Natural Sciences Naturvetenskap Phases Radioactive waste Redox Rock rock, sediment, soil sed rocks, sediments Sedimentary petrology sedimentary rocks sheet silicates Silicates Soil Science & Conservation Sp&ouml spectra Temperature Buffer Test (tbt) X-ray diffraction data X-ray spectra X-rays XANES XANES spectra XRD
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description	Excavated bentonite from two large iron--bentonite field experiments at Aspo Hard Rock Laboratory in Sweden was investigated with respect to iron redox chemistry and mineralogy. The iron redox chemistry was studied by Fe K-edge X-ray absorption near edge structure spectroscopy and the mineral phases were studied using X-ray diffraction. Bentonite is to be used as a buffer material in high-level radioactive waste repositories to protect the waste containers from their surroundings. Montmorillonite, which is responsible for the sealing properties in the bentonite, is susceptible to redox reactions. A change in the montmorillonite iron redox chemistry may affect its layer charge and hence its properties. The experiments included are the first Alternative Buffer Material test (ABM1) and the Temperature Buffer Test (TBT). The clays were heated to a maximum of approximately 130°C (ABM1) or approximately 150°C (TBT) for 2.5 and 7 y, respectively. In the central part of the compacted clay blocks was placed an iron heater and the distance from the heater to the rock was approximately 10 cm (ABM1) and approximately 50 cm (TBT), respectively. Eleven different clay materials were included in the ABM1 experiment and five were analyzed here. In the ABM1 experiment, the Fe(II)/Fe(III) ratio was increased in several samples from the vicinity of the heater. Kinetic data were collected and showed that most of the Fe(II)-rich samples oxidized rapidly when exposed to atmospheric oxygen. In the TBT experiment the corrosion products were dominated by Fe(III) and no significant increase in Fe(II) was seen. In ABM1, reducing conditions were achieved, at least in parts of the experiment; in TBT, reducing conditions were not achieved. The difference was attributed to the larger scale of the TBT experiment, providing more oxygen after the installation, and to the longer time taken for water saturation; oxidation of the samples during excavation cannot be ruled out. Minor changes in the bentonite mineral phases were found in some cases where direct contact was made with the iron heater but no significant impact on the bentonite performance in high-level radioactive waste applications was expected as a result.
doi_str_mv	10.1346/CCMN.2013.0610609
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The iron redox chemistry was studied by Fe K-edge X-ray absorption near edge structure spectroscopy and the mineral phases were studied using X-ray diffraction. Bentonite is to be used as a buffer material in high-level radioactive waste repositories to protect the waste containers from their surroundings. Montmorillonite, which is responsible for the sealing properties in the bentonite, is susceptible to redox reactions. A change in the montmorillonite iron redox chemistry may affect its layer charge and hence its properties. The experiments included are the first Alternative Buffer Material test (ABM1) and the Temperature Buffer Test (TBT). The clays were heated to a maximum of approximately 130°C (ABM1) or approximately 150°C (TBT) for 2.5 and 7 y, respectively. In the central part of the compacted clay blocks was placed an iron heater and the distance from the heater to the rock was approximately 10 cm (ABM1) and approximately 50 cm (TBT), respectively. Eleven different clay materials were included in the ABM1 experiment and five were analyzed here. In the ABM1 experiment, the Fe(II)/Fe(III) ratio was increased in several samples from the vicinity of the heater. Kinetic data were collected and showed that most of the Fe(II)-rich samples oxidized rapidly when exposed to atmospheric oxygen. In the TBT experiment the corrosion products were dominated by Fe(III) and no significant increase in Fe(II) was seen. In ABM1, reducing conditions were achieved, at least in parts of the experiment; in TBT, reducing conditions were not achieved. The difference was attributed to the larger scale of the TBT experiment, providing more oxygen after the installation, and to the longer time taken for water saturation; oxidation of the samples during excavation cannot be ruled out. 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The iron redox chemistry was studied by Fe K-edge X-ray absorption near edge structure spectroscopy and the mineral phases were studied using X-ray diffraction. Bentonite is to be used as a buffer material in high-level radioactive waste repositories to protect the waste containers from their surroundings. Montmorillonite, which is responsible for the sealing properties in the bentonite, is susceptible to redox reactions. A change in the montmorillonite iron redox chemistry may affect its layer charge and hence its properties. The experiments included are the first Alternative Buffer Material test (ABM1) and the Temperature Buffer Test (TBT). The clays were heated to a maximum of approximately 130°C (ABM1) or approximately 150°C (TBT) for 2.5 and 7 y, respectively. In the central part of the compacted clay blocks was placed an iron heater and the distance from the heater to the rock was approximately 10 cm (ABM1) and approximately 50 cm (TBT), respectively. Eleven different clay materials were included in the ABM1 experiment and five were analyzed here. In the ABM1 experiment, the Fe(II)/Fe(III) ratio was increased in several samples from the vicinity of the heater. Kinetic data were collected and showed that most of the Fe(II)-rich samples oxidized rapidly when exposed to atmospheric oxygen. In the TBT experiment the corrosion products were dominated by Fe(III) and no significant increase in Fe(II) was seen. In ABM1, reducing conditions were achieved, at least in parts of the experiment; in TBT, reducing conditions were not achieved. The difference was attributed to the larger scale of the TBT experiment, providing more oxygen after the installation, and to the longer time taken for water saturation; oxidation of the samples during excavation cannot be ruled out. Minor changes in the bentonite mineral phases were found in some cases where direct contact was made with the iron heater but no significant impact on the bentonite performance in high-level radioactive waste applications was expected as a result.</description><subject>A &uml</subject><subject>ABM</subject><subject>Alteration</subject><subject>Alternative Buffer Material</subject><subject>Aspo</subject><subject>Bentonite</subject><subject>Biogeosciences</subject><subject>Buffers (chemistry)</subject><subject>chemical properties</subject><subject>Chemical Sciences</subject><subject>clastic rocks</subject><subject>clay mineralogy</subject><subject>clay minerals</subject><subject>Earth and Environmental Science</subject><subject>Earth Sciences</subject><subject>Earth, ocean, space</subject><subject>Exact sciences and technology</subject><subject>experimental studies</subject><subject>Geochemistry</subject><subject>Iron</subject><subject>Kemi</subject><subject>laboratory studies</subject><subject>Medicinal Chemistry</subject><subject>Mineralogy</subject><subject>Montmorillonite</subject><subject>Nanoscale Science and Technology</subject><subject>Natural Sciences</subject><subject>Naturvetenskap</subject><subject>Phases</subject><subject>Radioactive waste</subject><subject>Redox</subject><subject>Rock</subject><subject>rock, sediment, soil</subject><subject>sed rocks, sediments</subject><subject>Sedimentary petrology</subject><subject>sedimentary rocks</subject><subject>sheet silicates</subject><subject>Silicates</subject><subject>Soil Science & Conservation</subject><subject>Sp&ouml</subject><subject>spectra</subject><subject>Temperature Buffer Test (tbt)</subject><subject>X-ray diffraction data</subject><subject>X-ray spectra</subject><subject>X-rays</subject><subject>XANES</subject><subject>XANES spectra</subject><subject>XRD</subject><issn>0009-8604</issn><issn>1552-8367</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2013</creationdate><recordtype>article</recordtype><recordid>eNqFkk1v1DAQhiMEEqXwA7j5goQEKf5IHEcc0GppKWJbpBak3ix_TJaUrL3YDtvlwG_H6a7aE2Bp5JH9vo_GMy6K5wQfEVbxN_P52fkRxYQdYU4wx-2D4oDUNS0F483D4gBj3JaC4-px8STGa4wprxg9KH5fgPU3yHyDVR9T2KLeobTxqA_elRpc8q5PgLoeBovgZg2hX-XTiFRCs7j26FQFiy68-Y4WSvugkg_b1-hyAxbcW6Qcurp4nzeLTgB9KsEuAV3Nzo8vUUyj3T4tHnVqiPBsvx8WX0-Ov8xPy8XnDx_ns0WpOBOpbA0HqquOaE1bZhteN5WoG427iihmgFhF645gQZllWgugtK4Fabqurjnomh0Wix03bmA9arnOz1BhK73q5TCuc-gcMoLsWstA1Va22ICsdA1Sc62kMpWoSEt5g6uMe7nDrYP_MUJMMnfPwDAoB36MkjS04QIz0v5fyhuBCSWUZynZSU3wMQbo7sokWE5TltOU5TRluZ9y9rzY41U0auiCcqaPd0YqMj1rs47uG5Cv3BKCvPZjcLnn_4S_25kmh0vq3mNWOcxqL79dnOwTzKUKaUomwtlfCL25hUyq6VvKn5w4nnmU4Ja2uS20khY6NQ5JJhXk8peME-_VjrcEH00PzsDGh8Hec3NFlcRUcEHYH7IO8eM</recordid><startdate>20131201</startdate><enddate>20131201</enddate><creator>Svensson, Per Daniel</creator><creator>Hansen, Staffan</creator><general>Clay Minerals Society</general><general>The Clay Minerals Society</general><general>Springer International Publishing</general><scope>IQODW</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7QQ</scope><scope>8FD</scope><scope>JG9</scope><scope>7UA</scope><scope>C1K</scope><scope>F1W</scope><scope>H96</scope><scope>L.G</scope><scope>ADTPV</scope><scope>AOWAS</scope><scope>D95</scope></search><sort><creationdate>20131201</creationdate><title>Redox chemistry in two iron-bentonite field experiments at Aspo Hard Rock Laboratory, Sweden; an XRD and Fe K-edge XANES study</title><author>Svensson, Per Daniel ; Hansen, Staffan</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a638t-9c6e2b4f1bb293d76574857b0f41a3ce1da25f10823d3bb8e2255817ff556eb53</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2013</creationdate><topic>A &uml</topic><topic>ABM</topic><topic>Alteration</topic><topic>Alternative Buffer Material</topic><topic>Aspo</topic><topic>Bentonite</topic><topic>Biogeosciences</topic><topic>Buffers (chemistry)</topic><topic>chemical properties</topic><topic>Chemical Sciences</topic><topic>clastic rocks</topic><topic>clay mineralogy</topic><topic>clay minerals</topic><topic>Earth and Environmental Science</topic><topic>Earth Sciences</topic><topic>Earth, ocean, space</topic><topic>Exact sciences and technology</topic><topic>experimental studies</topic><topic>Geochemistry</topic><topic>Iron</topic><topic>Kemi</topic><topic>laboratory studies</topic><topic>Medicinal Chemistry</topic><topic>Mineralogy</topic><topic>Montmorillonite</topic><topic>Nanoscale Science and Technology</topic><topic>Natural Sciences</topic><topic>Naturvetenskap</topic><topic>Phases</topic><topic>Radioactive waste</topic><topic>Redox</topic><topic>Rock</topic><topic>rock, sediment, soil</topic><topic>sed rocks, sediments</topic><topic>Sedimentary petrology</topic><topic>sedimentary rocks</topic><topic>sheet silicates</topic><topic>Silicates</topic><topic>Soil Science & Conservation</topic><topic>Sp&ouml</topic><topic>spectra</topic><topic>Temperature Buffer Test (tbt)</topic><topic>X-ray diffraction data</topic><topic>X-ray spectra</topic><topic>X-rays</topic><topic>XANES</topic><topic>XANES spectra</topic><topic>XRD</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Svensson, Per Daniel</creatorcontrib><creatorcontrib>Hansen, Staffan</creatorcontrib><collection>Pascal-Francis</collection><collection>CrossRef</collection><collection>Ceramic Abstracts</collection><collection>Technology Research Database</collection><collection>Materials Research Database</collection><collection>Water Resources Abstracts</collection><collection>Environmental Sciences and Pollution Management</collection><collection>ASFA: Aquatic Sciences and Fisheries Abstracts</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) 2: Ocean Technology, Policy & Non-Living Resources</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) Professional</collection><collection>SwePub</collection><collection>SwePub Articles</collection><collection>SWEPUB Lunds universitet</collection><jtitle>Clays and clay minerals</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Svensson, Per Daniel</au><au>Hansen, Staffan</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Redox chemistry in two iron-bentonite field experiments at Aspo Hard Rock Laboratory, Sweden; an XRD and Fe K-edge XANES study</atitle><jtitle>Clays and clay minerals</jtitle><stitle>Clays Clay Miner</stitle><date>2013-12-01</date><risdate>2013</risdate><volume>61</volume><issue>6</issue><spage>566</spage><epage>579</epage><pages>566-579</pages><issn>0009-8604</issn><eissn>1552-8367</eissn><coden>CLCMAB</coden><abstract>Excavated bentonite from two large iron--bentonite field experiments at Aspo Hard Rock Laboratory in Sweden was investigated with respect to iron redox chemistry and mineralogy. The iron redox chemistry was studied by Fe K-edge X-ray absorption near edge structure spectroscopy and the mineral phases were studied using X-ray diffraction. Bentonite is to be used as a buffer material in high-level radioactive waste repositories to protect the waste containers from their surroundings. Montmorillonite, which is responsible for the sealing properties in the bentonite, is susceptible to redox reactions. A change in the montmorillonite iron redox chemistry may affect its layer charge and hence its properties. The experiments included are the first Alternative Buffer Material test (ABM1) and the Temperature Buffer Test (TBT). The clays were heated to a maximum of approximately 130°C (ABM1) or approximately 150°C (TBT) for 2.5 and 7 y, respectively. In the central part of the compacted clay blocks was placed an iron heater and the distance from the heater to the rock was approximately 10 cm (ABM1) and approximately 50 cm (TBT), respectively. Eleven different clay materials were included in the ABM1 experiment and five were analyzed here. In the ABM1 experiment, the Fe(II)/Fe(III) ratio was increased in several samples from the vicinity of the heater. Kinetic data were collected and showed that most of the Fe(II)-rich samples oxidized rapidly when exposed to atmospheric oxygen. In the TBT experiment the corrosion products were dominated by Fe(III) and no significant increase in Fe(II) was seen. In ABM1, reducing conditions were achieved, at least in parts of the experiment; in TBT, reducing conditions were not achieved. The difference was attributed to the larger scale of the TBT experiment, providing more oxygen after the installation, and to the longer time taken for water saturation; oxidation of the samples during excavation cannot be ruled out. Minor changes in the bentonite mineral phases were found in some cases where direct contact was made with the iron heater but no significant impact on the bentonite performance in high-level radioactive waste applications was expected as a result.</abstract><cop>Cham</cop><pub>Clay Minerals Society</pub><doi>10.1346/CCMN.2013.0610609</doi><tpages>14</tpages></addata></record>
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subjects	A &uml ABM Alteration Alternative Buffer Material Aspo Bentonite Biogeosciences Buffers (chemistry) chemical properties Chemical Sciences clastic rocks clay mineralogy clay minerals Earth and Environmental Science Earth Sciences Earth, ocean, space Exact sciences and technology experimental studies Geochemistry Iron Kemi laboratory studies Medicinal Chemistry Mineralogy Montmorillonite Nanoscale Science and Technology Natural Sciences Naturvetenskap Phases Radioactive waste Redox Rock rock, sediment, soil sed rocks, sediments Sedimentary petrology sedimentary rocks sheet silicates Silicates Soil Science & Conservation Sp&ouml spectra Temperature Buffer Test (tbt) X-ray diffraction data X-ray spectra X-rays XANES XANES spectra XRD
title	Redox chemistry in two iron-bentonite field experiments at Aspo Hard Rock Laboratory, Sweden; an XRD and Fe K-edge XANES study
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