Determination of trace element mineral/liquid partition coefficients in melilite and diopside by ion and electron microprobe techniques

The use of the ion microprobe for quantitative analysis of Sr, Y, Zr, La, Sm, and Yb in melilite and pyroxene is evaluated. Three trace element-doped synthetic glasses of composition Ak 40, Ak 80, and Di 2AbAn were analyzed by ion microprobe (IMP) using ion yields determined from Corning glass stand...

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Veröffentlicht in:	Geochimica et cosmochimica acta 1989-12, Vol.53 (12), p.3115-3130
Hauptverfasser:	Kuehner, S.M., Laughlin, J.R., Grossman, L., Johnson, M.L., Burnett, D.S.
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Sprache:	eng
Schlagworte:	AMORPHOUS STATE CHEMICAL ANALYSIS CHEMICAL COMPOSITION CHEMISTRY COMPARATIVE EVALUATIONS CRYSTALLIZATION DIOPSIDE ELECTRON MICROPROBE ANALYSIS EQUILIBRIUM FRACTIONATION GEOCHEMISTRY GEOLOGIC MODELS GEOSCIENCES INCLUSIONS ION MICROPROBE ANALYSIS Lunar And Planetary Exploration MAGMA MICROANALYSIS MINERALS NONDESTRUCTIVE ANALYSIS OXYGEN COMPOUNDS PHASE TRANSFORMATIONS PYROXENES QUANTITATIVE CHEMICAL ANALYSIS SEPARATION PROCESSES SILICATE MINERALS SILICATES SILICON COMPOUNDS 580000 > Geosciences SYNTHESIS
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container_title	Geochimica et cosmochimica acta
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creator	Kuehner, S.M. Laughlin, J.R. Grossman, L. Johnson, M.L. Burnett, D.S.
description	The use of the ion microprobe for quantitative analysis of Sr, Y, Zr, La, Sm, and Yb in melilite and pyroxene is evaluated. Three trace element-doped synthetic glasses of composition Ak 40, Ak 80, and Di 2AbAn were analyzed by ion microprobe (IMP) using ion yields determined from Corning glass standards. IMP-determined oxide concentrations in the Di 2AbAn glass agree well with electron microprobe (EMP) analyses (to within 6%), but IMP analyses of the melilite glasses deviate from EMP averages by up to 19%. The deviations are due to erroneous SiO 2 estimates caused by suppression of Si ion intensities by the enhanced concentrations of Ca and Al in the melilite glasses compared to the standards. Thus, in order to determine compositions of melilite, diopside, and glass from subliquidus experiments on each of the three starting compositions, we adopted a new set of ion yields such that IMP analyses of the three starting glasses reproduce the EMP average compositions. Further IMP and EMP comparisons of the subliquidus assemblages show that quantitative analyses of melilite, diopside, and glass can be obtained by IMP that are within 10% of the concentrations obtained by EMP, when ion yields determined from glass starting compositions are used. EMP-IMP comparison of crystal and glass analyses also suggests that a structural matrix effect may result in overestimation of SrO (10–12%) in melilite by IMP. Comparison of our data for Ak 12 and Ak 90 melilite compositions with literature results shows that melilite/liquid D- values for REE 3+ determined by IMP decrease with increasing X AK ( Ak 90: D la = 0.038, D Sm = 0.032, D Yb = 0.0086 ; Ak 12: 0.67, 0.75, 0.25 , respectively) while that for Sr (=Eu 2+) changes only slightly (0.99 to 0.78, respectively). Since X Ak increases with decreasing temperature for all melilite with X Ak < 0.7 , a progressively larger positive Eu anomaly is predicted for melilite as it crystallizes with falling temperature. Our diopside/liquid data are characterized by a large degree of scatter on most interelement correlation plots of apparent partition coefficients. The data cannot be understood in terms of simple models of boundary layer formation but require a complex surface partitioning explanation. Nevertheless, estimates of diopside/liquid D- values are in excellent agreement with literature data.
doi_str_mv	10.1016/0016-7037(89)90093-8
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Three trace element-doped synthetic glasses of composition Ak 40, Ak 80, and Di 2AbAn were analyzed by ion microprobe (IMP) using ion yields determined from Corning glass standards. IMP-determined oxide concentrations in the Di 2AbAn glass agree well with electron microprobe (EMP) analyses (to within 6%), but IMP analyses of the melilite glasses deviate from EMP averages by up to 19%. The deviations are due to erroneous SiO 2 estimates caused by suppression of Si ion intensities by the enhanced concentrations of Ca and Al in the melilite glasses compared to the standards. Thus, in order to determine compositions of melilite, diopside, and glass from subliquidus experiments on each of the three starting compositions, we adopted a new set of ion yields such that IMP analyses of the three starting glasses reproduce the EMP average compositions. Further IMP and EMP comparisons of the subliquidus assemblages show that quantitative analyses of melilite, diopside, and glass can be obtained by IMP that are within 10% of the concentrations obtained by EMP, when ion yields determined from glass starting compositions are used. EMP-IMP comparison of crystal and glass analyses also suggests that a structural matrix effect may result in overestimation of SrO (10–12%) in melilite by IMP. Comparison of our data for Ak 12 and Ak 90 melilite compositions with literature results shows that melilite/liquid D- values for REE 3+ determined by IMP decrease with increasing X AK ( Ak 90: D la = 0.038, D Sm = 0.032, D Yb = 0.0086 ; Ak 12: 0.67, 0.75, 0.25 , respectively) while that for Sr (=Eu 2+) changes only slightly (0.99 to 0.78, respectively). Since X Ak increases with decreasing temperature for all melilite with X Ak < 0.7 , a progressively larger positive Eu anomaly is predicted for melilite as it crystallizes with falling temperature. Our diopside/liquid data are characterized by a large degree of scatter on most interelement correlation plots of apparent partition coefficients. The data cannot be understood in terms of simple models of boundary layer formation but require a complex surface partitioning explanation. 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Three trace element-doped synthetic glasses of composition Ak 40, Ak 80, and Di 2AbAn were analyzed by ion microprobe (IMP) using ion yields determined from Corning glass standards. IMP-determined oxide concentrations in the Di 2AbAn glass agree well with electron microprobe (EMP) analyses (to within 6%), but IMP analyses of the melilite glasses deviate from EMP averages by up to 19%. The deviations are due to erroneous SiO 2 estimates caused by suppression of Si ion intensities by the enhanced concentrations of Ca and Al in the melilite glasses compared to the standards. Thus, in order to determine compositions of melilite, diopside, and glass from subliquidus experiments on each of the three starting compositions, we adopted a new set of ion yields such that IMP analyses of the three starting glasses reproduce the EMP average compositions. Further IMP and EMP comparisons of the subliquidus assemblages show that quantitative analyses of melilite, diopside, and glass can be obtained by IMP that are within 10% of the concentrations obtained by EMP, when ion yields determined from glass starting compositions are used. EMP-IMP comparison of crystal and glass analyses also suggests that a structural matrix effect may result in overestimation of SrO (10–12%) in melilite by IMP. Comparison of our data for Ak 12 and Ak 90 melilite compositions with literature results shows that melilite/liquid D- values for REE 3+ determined by IMP decrease with increasing X AK ( Ak 90: D la = 0.038, D Sm = 0.032, D Yb = 0.0086 ; Ak 12: 0.67, 0.75, 0.25 , respectively) while that for Sr (=Eu 2+) changes only slightly (0.99 to 0.78, respectively). Since X Ak increases with decreasing temperature for all melilite with X Ak < 0.7 , a progressively larger positive Eu anomaly is predicted for melilite as it crystallizes with falling temperature. Our diopside/liquid data are characterized by a large degree of scatter on most interelement correlation plots of apparent partition coefficients. The data cannot be understood in terms of simple models of boundary layer formation but require a complex surface partitioning explanation. Nevertheless, estimates of diopside/liquid D- values are in excellent agreement with literature data.</description><subject>AMORPHOUS STATE</subject><subject>CHEMICAL ANALYSIS</subject><subject>CHEMICAL COMPOSITION</subject><subject>CHEMISTRY</subject><subject>COMPARATIVE EVALUATIONS</subject><subject>CRYSTALLIZATION</subject><subject>DIOPSIDE</subject><subject>ELECTRON MICROPROBE ANALYSIS</subject><subject>EQUILIBRIUM</subject><subject>FRACTIONATION</subject><subject>GEOCHEMISTRY</subject><subject>GEOLOGIC MODELS</subject><subject>GEOSCIENCES</subject><subject>INCLUSIONS</subject><subject>ION MICROPROBE ANALYSIS</subject><subject>Lunar And Planetary Exploration</subject><subject>MAGMA</subject><subject>MICROANALYSIS</subject><subject>MINERALS</subject><subject>NONDESTRUCTIVE ANALYSIS</subject><subject>OXYGEN COMPOUNDS</subject><subject>PHASE TRANSFORMATIONS</subject><subject>PYROXENES</subject><subject>QUANTITATIVE CHEMICAL ANALYSIS</subject><subject>SEPARATION PROCESSES</subject><subject>SILICATE MINERALS</subject><subject>SILICATES</subject><subject>SILICON COMPOUNDS 580000 -- Geosciences</subject><subject>SYNTHESIS</subject><issn>0016-7037</issn><issn>1872-9533</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>1989</creationdate><recordtype>article</recordtype><sourceid>CYI</sourceid><recordid>eNp9kc-O1iAUxRujiZ-jbzAL4sLoos6llEI3Jmb8m0ziRteEwm28poVPYEzmCXxtYWpcuoHA-d3D4d6uu-TwmgOfrqAuvQKhXur51Qwwi14_6E5cq6GfpRAPu9M_5HH3JOcfAKCkhFP3-x0WTDsFWygGFldWknXIcMMdQ2FVwWS3q41-3pJnZ5sK3ZMu4rqSowplRoHtuNFGBZkNnnmK50we2XLHGtzuqqMrqR52cimeU1yQFXTfQ3XG_LR7tNot47O_-0X37cP7r9ef-psvHz9fv73p7aiG0utxRO385EAOfvDL4pZF6EGB0iiGAcALnAfJRyclSr5oWGCSXs_rJJbJC3HRPT98Yy5ksqMWwcUQajgzKS4UTBV6cUA1ZQtXzE7Z4bbZgPE2m_qAluPUwPEA649yTriac6LdpjvDwbTRmNZ30_pu9GzuR2N0Lbs8yoLN1oSSsuFzFUEIPvEqvzlkrI34RZhaTgwOPaUW00f6v_8fvlOgJQ</recordid><startdate>19891201</startdate><enddate>19891201</enddate><creator>Kuehner, S.M.</creator><creator>Laughlin, J.R.</creator><creator>Grossman, L.</creator><creator>Johnson, M.L.</creator><creator>Burnett, D.S.</creator><general>Elsevier Ltd</general><scope>CYE</scope><scope>CYI</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>8FD</scope><scope>H8D</scope><scope>L7M</scope><scope>OTOTI</scope></search><sort><creationdate>19891201</creationdate><title>Determination of trace element mineral/liquid partition coefficients in melilite and diopside by ion and electron microprobe techniques</title><author>Kuehner, S.M. ; Laughlin, J.R. ; Grossman, L. ; Johnson, M.L. ; Burnett, D.S.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a472t-844e8cd6c052d2dbbcbb3827078e32200d3e92514c55e51b80b065d89f63b6d33</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>1989</creationdate><topic>AMORPHOUS STATE</topic><topic>CHEMICAL ANALYSIS</topic><topic>CHEMICAL COMPOSITION</topic><topic>CHEMISTRY</topic><topic>COMPARATIVE EVALUATIONS</topic><topic>CRYSTALLIZATION</topic><topic>DIOPSIDE</topic><topic>ELECTRON MICROPROBE ANALYSIS</topic><topic>EQUILIBRIUM</topic><topic>FRACTIONATION</topic><topic>GEOCHEMISTRY</topic><topic>GEOLOGIC MODELS</topic><topic>GEOSCIENCES</topic><topic>INCLUSIONS</topic><topic>ION MICROPROBE ANALYSIS</topic><topic>Lunar And Planetary Exploration</topic><topic>MAGMA</topic><topic>MICROANALYSIS</topic><topic>MINERALS</topic><topic>NONDESTRUCTIVE ANALYSIS</topic><topic>OXYGEN COMPOUNDS</topic><topic>PHASE TRANSFORMATIONS</topic><topic>PYROXENES</topic><topic>QUANTITATIVE CHEMICAL ANALYSIS</topic><topic>SEPARATION PROCESSES</topic><topic>SILICATE MINERALS</topic><topic>SILICATES</topic><topic>SILICON COMPOUNDS 580000 -- Geosciences</topic><topic>SYNTHESIS</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Kuehner, S.M.</creatorcontrib><creatorcontrib>Laughlin, J.R.</creatorcontrib><creatorcontrib>Grossman, L.</creatorcontrib><creatorcontrib>Johnson, M.L.</creatorcontrib><creatorcontrib>Burnett, D.S.</creatorcontrib><collection>NASA Scientific and Technical Information</collection><collection>NASA Technical Reports Server</collection><collection>CrossRef</collection><collection>Technology Research Database</collection><collection>Aerospace Database</collection><collection>Advanced Technologies Database with Aerospace</collection><collection>OSTI.GOV</collection><jtitle>Geochimica et cosmochimica acta</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Kuehner, S.M.</au><au>Laughlin, J.R.</au><au>Grossman, L.</au><au>Johnson, M.L.</au><au>Burnett, D.S.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Determination of trace element mineral/liquid partition coefficients in melilite and diopside by ion and electron microprobe techniques</atitle><jtitle>Geochimica et cosmochimica acta</jtitle><date>1989-12-01</date><risdate>1989</risdate><volume>53</volume><issue>12</issue><spage>3115</spage><epage>3130</epage><pages>3115-3130</pages><issn>0016-7037</issn><eissn>1872-9533</eissn><abstract>The use of the ion microprobe for quantitative analysis of Sr, Y, Zr, La, Sm, and Yb in melilite and pyroxene is evaluated. Three trace element-doped synthetic glasses of composition Ak 40, Ak 80, and Di 2AbAn were analyzed by ion microprobe (IMP) using ion yields determined from Corning glass standards. IMP-determined oxide concentrations in the Di 2AbAn glass agree well with electron microprobe (EMP) analyses (to within 6%), but IMP analyses of the melilite glasses deviate from EMP averages by up to 19%. The deviations are due to erroneous SiO 2 estimates caused by suppression of Si ion intensities by the enhanced concentrations of Ca and Al in the melilite glasses compared to the standards. Thus, in order to determine compositions of melilite, diopside, and glass from subliquidus experiments on each of the three starting compositions, we adopted a new set of ion yields such that IMP analyses of the three starting glasses reproduce the EMP average compositions. Further IMP and EMP comparisons of the subliquidus assemblages show that quantitative analyses of melilite, diopside, and glass can be obtained by IMP that are within 10% of the concentrations obtained by EMP, when ion yields determined from glass starting compositions are used. EMP-IMP comparison of crystal and glass analyses also suggests that a structural matrix effect may result in overestimation of SrO (10–12%) in melilite by IMP. Comparison of our data for Ak 12 and Ak 90 melilite compositions with literature results shows that melilite/liquid D- values for REE 3+ determined by IMP decrease with increasing X AK ( Ak 90: D la = 0.038, D Sm = 0.032, D Yb = 0.0086 ; Ak 12: 0.67, 0.75, 0.25 , respectively) while that for Sr (=Eu 2+) changes only slightly (0.99 to 0.78, respectively). Since X Ak increases with decreasing temperature for all melilite with X Ak < 0.7 , a progressively larger positive Eu anomaly is predicted for melilite as it crystallizes with falling temperature. Our diopside/liquid data are characterized by a large degree of scatter on most interelement correlation plots of apparent partition coefficients. The data cannot be understood in terms of simple models of boundary layer formation but require a complex surface partitioning explanation. Nevertheless, estimates of diopside/liquid D- values are in excellent agreement with literature data.</abstract><cop>Legacy CDMS</cop><pub>Elsevier Ltd</pub><doi>10.1016/0016-7037(89)90093-8</doi><tpages>16</tpages></addata></record>
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subjects	AMORPHOUS STATE CHEMICAL ANALYSIS CHEMICAL COMPOSITION CHEMISTRY COMPARATIVE EVALUATIONS CRYSTALLIZATION DIOPSIDE ELECTRON MICROPROBE ANALYSIS EQUILIBRIUM FRACTIONATION GEOCHEMISTRY GEOLOGIC MODELS GEOSCIENCES INCLUSIONS ION MICROPROBE ANALYSIS Lunar And Planetary Exploration MAGMA MICROANALYSIS MINERALS NONDESTRUCTIVE ANALYSIS OXYGEN COMPOUNDS PHASE TRANSFORMATIONS PYROXENES QUANTITATIVE CHEMICAL ANALYSIS SEPARATION PROCESSES SILICATE MINERALS SILICATES SILICON COMPOUNDS 580000 -- Geosciences SYNTHESIS
title	Determination of trace element mineral/liquid partition coefficients in melilite and diopside by ion and electron microprobe techniques
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