The 'zero charge' partitioning behaviour of noble gases during mantle melting

The 'zero charge' partitioning behaviour of noble gases during mantle melting

Noble-gas geochemistry is an important tool for understanding planetary processes from accretion to mantle dynamics and atmospheric formation. Central to much of the modelling of such processes is the crystal-melt partitioning of noble gases during mantle melting, magma ascent and near-surface degas...

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Bibliographic Details
Published in:Nature (London) Vol. 423; no. 6941; pp. 738 - 741
Main Authors: Brooker, R. A, Du, Z, Blundy, J. D, Kelley, S. P, Allan, N. L, Wood, B. J, Chamorro, E. M, Wartho, J.-A, Purton, J. A
Format: Journal Article
Language:English
Published: London Nature Publishing 12-06-2003
Nature Publishing Group
Subjects:
Accretion
Atmosphere
Chemistry
Crystalline rocks
Degassing
Earth sciences
Earth, ocean, space
Exact sciences and technology
Experimental data
Experimental petrology
Gases
Geochemistry
Geology
Melting
Mineralogy
Silicates
Soil and rock geochemistry
experimental studies
fractionation
models
partition coefficients
computer programs
chain silicates
degassing
simulation
jadeite
magmas
partial melting
alkalic pyroxene
Young's modulus
pyroxene
silicates
deformation
noble gases
mantle
clinopyroxene
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Summary:Noble-gas geochemistry is an important tool for understanding planetary processes from accretion to mantle dynamics and atmospheric formation. Central to much of the modelling of such processes is the crystal-melt partitioning of noble gases during mantle melting, magma ascent and near-surface degassing. Geochemists have traditionally considered the 'inert' noble gases to be extremely incompatible elements, with almost 100 per cent extraction efficiency from the solid phase during melting processes. Previously published experimental data on partitioning between crystalline silicates and melts has, however, suggested that noble gases approach compatible behaviour, and a significant proportion should therefore remain in the mantle during melt extraction. Here we present experimental data to show that noble gases are more incompatible than previously demonstrated, but not necessarily to the extent assumed or required by geochemical models. Independent atomistic computer simulations indicate that noble gases can be considered as species of 'zero charge' incorporated at crystal lattice sites. Together with the lattice strain model, this provides a theoretical framework with which to model noble-gas geochemistry as a function of residual mantle mineralogy.
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ISSN:0028-0836
1476-4687
DOI:10.1038/nature01708