Structural change in molten basalt at deep mantle conditions

The structure of molten basalt up to 60 GPa by means of in situ X-ray diffraction is described, with the coordination of silicon increasing from four under ambient conditions to six at 35 GPa, and subsequent reduced melt compressibility, which seems to affect siderophile-element partitioning. Change...

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Published in:	Nature (London) Vol. 503; no. 7474; pp. 104 - 107
Main Authors:	Sanloup, Chrystèle, Drewitt, James W. E., Konôpková, Zuzana, Dalladay-Simpson, Philip, Morton, Donna M., Rai, Nachiketa, van Westrenen, Wim, Morgenroth, Wolfgang
Format:	Journal Article
Language:	English
Published:	London Nature Publishing Group UK 07-11-2013 Nature Publishing Group
Subjects:	639/766/119/1002 704/2151/209 704/2151/2809 Basalt Diffraction Earth Earth Sciences Humanities and Social Sciences Lasers letter Mantle Methods Mineralogy multidisciplinary Nickel Science Sciences of the Universe Silica Silicates Structure Thermal properties Values X-ray diffraction Europe
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Abstract	The structure of molten basalt up to 60 GPa by means of in situ X-ray diffraction is described, with the coordination of silicon increasing from four under ambient conditions to six at 35 GPa, and subsequent reduced melt compressibility, which seems to affect siderophile-element partitioning. Changes in molten basalt at depth Chrystèle Sanloup and co-authors report on the structure of molten basalt at deep mantle conditions determined using in situ X-ray diffraction experiments in laser-heated diamond anvil cells. They find that silicon coordination increases from 4 at ambient conditions to 6 at a pressure of 35 GPa, with the compressibility of the melt becoming lower above this transition. Given that this pressure coincides with a marked change in the pressure evolution of nickel partitioning between molten iron and molten silicates, the authors conclude that melt compressibility may control siderophile-element partitioning. These findings provide data that can be incorporated into quantitative models of the behaviour of silicate liquids deep in the Earth's mantle. Silicate liquids play a key part at all stages of deep Earth evolution, ranging from core and crust formation billions of years ago to present-day volcanic activity. Quantitative models of these processes require knowledge of the structural changes and compression mechanisms that take place in liquid silicates at the high pressures and temperatures in the Earth’s interior. However, obtaining such knowledge has long been impeded by the challenging nature of the experiments. In recent years, structural and density information for silica glass was obtained at record pressures of up to 100 GPa (ref. 1 ), a major step towards obtaining data on the molten state. Here we report the structure of molten basalt up to 60 GPa by means of in situ X-ray diffraction. The coordination of silicon increases from four under ambient conditions to six at 35 GPa, similar to what has been reported in silica glass 1 , 2 , 3 . The compressibility of the melt after the completion of the coordination change is lower than at lower pressure, implying that only a high-order equation of state can accurately describe the density evolution of silicate melts over the pressure range of the whole mantle. The transition pressure coincides with a marked change in the pressure-evolution of nickel partitioning between molten iron and molten silicates, indicating that melt compressibility controls siderophile-element partitioning.
AbstractList	The structure of molten basalt up to 60 GPa by means of in situ X-ray diffraction is described, with the coordination of silicon increasing from four under ambient conditions to six at 35 GPa, and subsequent reduced melt compressibility, which seems to affect siderophile-element partitioning. Changes in molten basalt at depth Chrystèle Sanloup and co-authors report on the structure of molten basalt at deep mantle conditions determined using in situ X-ray diffraction experiments in laser-heated diamond anvil cells. They find that silicon coordination increases from 4 at ambient conditions to 6 at a pressure of 35 GPa, with the compressibility of the melt becoming lower above this transition. Given that this pressure coincides with a marked change in the pressure evolution of nickel partitioning between molten iron and molten silicates, the authors conclude that melt compressibility may control siderophile-element partitioning. These findings provide data that can be incorporated into quantitative models of the behaviour of silicate liquids deep in the Earth's mantle. Silicate liquids play a key part at all stages of deep Earth evolution, ranging from core and crust formation billions of years ago to present-day volcanic activity. Quantitative models of these processes require knowledge of the structural changes and compression mechanisms that take place in liquid silicates at the high pressures and temperatures in the Earth’s interior. However, obtaining such knowledge has long been impeded by the challenging nature of the experiments. In recent years, structural and density information for silica glass was obtained at record pressures of up to 100 GPa (ref. 1 ), a major step towards obtaining data on the molten state. Here we report the structure of molten basalt up to 60 GPa by means of in situ X-ray diffraction. The coordination of silicon increases from four under ambient conditions to six at 35 GPa, similar to what has been reported in silica glass 1 , 2 , 3 . The compressibility of the melt after the completion of the coordination change is lower than at lower pressure, implying that only a high-order equation of state can accurately describe the density evolution of silicate melts over the pressure range of the whole mantle. The transition pressure coincides with a marked change in the pressure-evolution of nickel partitioning between molten iron and molten silicates, indicating that melt compressibility controls siderophile-element partitioning. Silicate liquids play a key part at all stages of deep Earth evolution, ranging from core and crust formation billions of years ago to present-day volcanic activity. Quantitative models of these processes require knowledge of the structural changes and compression mechanisms that take place in liquid silicates at the high pressures and temperatures in the Earth's interior. However, obtaining such knowledge has long been impeded by the challenging nature of the experiments. In recent years, structural and density information for silica glass was obtained at record pressures of up to 100 GPa (ref. 1), a major step towards obtaining data on the molten state. Here we report the structure of molten basalt up to 60 GPa by means of in situ X-ray diffraction. The coordination of silicon increases from four under ambient conditions to six at 35 GPa, similar to what has been reported in silica glass (1-3). The compressibility of the melt after the completion of the coordination change is lower than at lower pressure, implying that only a high-order equation of state can accurately describe the density evolution of silicate melts over the pressure range of the whole mantle. The transition pressure coincides with a marked change in the pressure-evolution of nickel partitioning between molten iron and molten silicates, indicating that melt compressibility controls siderophile-element partitioning. Silicate liquids play a key part at all stages of deep Earth evolution, ranging from core and crust formation billions of years ago to present-day volcanic activity. Quantitative models of these processes require knowledge of the structural changes and compression mechanisms that take place in liquid silicates at the high pressures and temperatures in the Earth's interior. However, obtaining such knowledge has long been impeded by the challenging nature of the experiments. In recent years, structural and density information for silica glass was obtained at record pressures of up to 100 GPa (ref. 1), a major step towards obtaining data on the molten state. Here we report the structure of molten basalt up to 60 GPa by means of in situ X-ray diffraction. The coordination of silicon increases from four under ambient conditions to six at 35 GPa, similar to what has been reported in silica glass^sup 1-3^. The compressibility of the melt after the completion of the coordination change is lower than at lower pressure, implying that only a high-order equation of state can accurately describe the density evolution of silicate melts over the pressure range of the whole mantle. The transition pressure coin- cides with a marked change in the pressure-evolution of nickel partitioning between molten iron and molten silicates, indicating that melt compressibility controls siderophile-element partitioning. [PUBLICATION ABSTRACT] Silicate liquids play a key part at all stages of deep Earth evolution, ranging from core and crust formation billions of years ago to present-day volcanic activity. Quantitative models of these processes require knowledge of the structural changes and compression mechanisms that take place in liquid silicates at the high pressures and temperatures in the Earth's interior. However, obtaining such knowledge has long been impeded by the challenging nature of the experiments. In recent years, structural and density information for silica glass was obtained at record pressures of up to 100 GPa (ref. 1), a major step towards obtaining data on the molten state. Here we report the structure of molten basalt up to 60 GPa by means of in situ X-ray diffraction. The coordination of silicon increases from four under ambient conditions to six at 35 GPa, similar to what has been reported in silica glass. The compressibility of the melt after the completion of the coordination change is lower than at lower pressure, implying that only a high-order equation of state can accurately describe the density evolution of silicate melts over the pressure range of the whole mantle. The transition pressure coincides with a marked change in the pressure-evolution of nickel partitioning between molten iron and molten silicates, indicating that melt compressibility controls siderophile-element partitioning.
Audience	Academic
Author	Drewitt, James W. E. Morton, Donna M. Dalladay-Simpson, Philip Morgenroth, Wolfgang Konôpková, Zuzana Rai, Nachiketa Sanloup, Chrystèle van Westrenen, Wim
Author_xml	– sequence: 1 givenname: Chrystèle surname: Sanloup fullname: Sanloup, Chrystèle email: chrystele.sanloup@ed.ac.uk organization: Centre for Science at Extreme Conditions and School of Physics and Astronomy, University of Edinburgh, Scottish Universities Physics Alliance, Edinburgh EH9 3JZ, UK, Université Pierre et Marie Curie, UMR-CNRS 7193, Institut des Sciences de la Terre Paris, F-75005, Paris, France – sequence: 2 givenname: James W. E. surname: Drewitt fullname: Drewitt, James W. E. organization: Centre for Science at Extreme Conditions and School of Physics and Astronomy, University of Edinburgh, Scottish Universities Physics Alliance, Edinburgh EH9 3JZ, UK – sequence: 3 givenname: Zuzana surname: Konôpková fullname: Konôpková, Zuzana organization: DESY Photon Science, Notkestrasse 85, D-22607 Hamburg, Germany – sequence: 4 givenname: Philip surname: Dalladay-Simpson fullname: Dalladay-Simpson, Philip organization: Centre for Science at Extreme Conditions and School of Physics and Astronomy, University of Edinburgh, Scottish Universities Physics Alliance, Edinburgh EH9 3JZ, UK – sequence: 5 givenname: Donna M. surname: Morton fullname: Morton, Donna M. organization: Centre for Science at Extreme Conditions and School of Physics and Astronomy, University of Edinburgh, Scottish Universities Physics Alliance, Edinburgh EH9 3JZ, UK – sequence: 6 givenname: Nachiketa surname: Rai fullname: Rai, Nachiketa organization: Faculty of Earth and Life Sciences, Vrije Universität Amsterdam, 1081 HV, The Netherlands – sequence: 7 givenname: Wim surname: van Westrenen fullname: van Westrenen, Wim organization: Faculty of Earth and Life Sciences, Vrije Universität Amsterdam, 1081 HV, The Netherlands – sequence: 8 givenname: Wolfgang surname: Morgenroth fullname: Morgenroth, Wolfgang organization: DESY Photon Science, Notkestrasse 85, D-22607 Hamburg, Germany, Institut für Geowissenschaften, Goethe-Universität Frankfurt, D-60438 Frankfurt am Main, Germany
BackLink	https://www.ncbi.nlm.nih.gov/pubmed/24201283$$D View this record in MEDLINE/PubMed https://hal.sorbonne-universite.fr/hal-00936436$$DView record in HAL
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Copyright	Springer Nature Limited 2013 COPYRIGHT 2013 Nature Publishing Group Copyright Nature Publishing Group Nov 7, 2013 Distributed under a Creative Commons Attribution 4.0 International License
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Snippet	The structure of molten basalt up to 60 GPa by means of in situ X-ray diffraction is described, with the coordination of silicon increasing from four under... Silicate liquids play a key part at all stages of deep Earth evolution, ranging from core and crust formation billions of years ago to present-day volcanic...
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SubjectTerms	639/766/119/1002 704/2151/209 704/2151/2809 Basalt Diffraction Earth Earth Sciences Humanities and Social Sciences Lasers letter Mantle Methods Mineralogy multidisciplinary Nickel Science Sciences of the Universe Silica Silicates Structure Thermal properties Values X-ray diffraction
Title	Structural change in molten basalt at deep mantle conditions
URI	https://link.springer.com/article/10.1038/nature12668 https://www.ncbi.nlm.nih.gov/pubmed/24201283 https://www.proquest.com/docview/1462237895 https://search.proquest.com/docview/1449768536 https://hal.sorbonne-universite.fr/hal-00936436
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