A condensation origin for the mass-dependent silicon isotopic variations in Allende components: implications for complementarity

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A condensation origin for the mass-dependent silicon isotopic variations in Allende components : implications for complementarity. / Martins, Rayssa; Chaussidon, Marc; Deng, Zhengbin; Pignatale, Francesco; Moynier, Frederic.

In: Earth and Planetary Science Letters, Vol. 554, 116678, 2021.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Martins, R, Chaussidon, M, Deng, Z, Pignatale, F & Moynier, F 2021, 'A condensation origin for the mass-dependent silicon isotopic variations in Allende components: implications for complementarity', Earth and Planetary Science Letters, vol. 554, 116678. https://doi.org/10.1016/j.epsl.2020.116678

APA

Martins, R., Chaussidon, M., Deng, Z., Pignatale, F., & Moynier, F. (2021). A condensation origin for the mass-dependent silicon isotopic variations in Allende components: implications for complementarity. Earth and Planetary Science Letters, 554, [116678]. https://doi.org/10.1016/j.epsl.2020.116678

Vancouver

Martins R, Chaussidon M, Deng Z, Pignatale F, Moynier F. A condensation origin for the mass-dependent silicon isotopic variations in Allende components: implications for complementarity. Earth and Planetary Science Letters. 2021;554. 116678. https://doi.org/10.1016/j.epsl.2020.116678

Author

Martins, Rayssa ; Chaussidon, Marc ; Deng, Zhengbin ; Pignatale, Francesco ; Moynier, Frederic. / A condensation origin for the mass-dependent silicon isotopic variations in Allende components : implications for complementarity. In: Earth and Planetary Science Letters. 2021 ; Vol. 554.

Bibtex

@article{54ce6703d115495687ec056beab38067,
title = "A condensation origin for the mass-dependent silicon isotopic variations in Allende components: implications for complementarity",
abstract = "Primitive chondrites have bulk compositions close to that of the solar photosphere, with however significant variations of elemental ratio relative to the solar composition, depending on the volatility of the elements considered. This is classically understood as indicating a primary geochemical signature due to the formation of the components of chondrites (refractory inclusions, chondrules and matrix), or of their precursors, through condensation of a gas of near solar composition, plus secondary variations due to processes such as (i) incomplete volatilization of presolar components, (ii) complex high-temperature exchanges between condensed phases and the nebular gas, and (iii) sorting and transport of grains in the accretion disk before accretion of chondrite parent bodies. Because most of the mass of chondrites is made by elements which condense at high temperatures, equilibrium condensation produces in general little isotopic fractionation for these elements. Silicon is however an exception with per mil level equilibrium isotopic fractionation at high temperature between the SiO gas and condensed silicates, allowing to use silicon isotopes in chondrites to constrain the origin of their components and to put at test scenarios of condensation.Individual components (chondrule fragments, isolated olivines in the matrix, and matrix fragments) of the carbonaceous chondrite Allende were separated and analysed at high-precision for their silicon isotopic composition. Large variations have been found among chondrules (delta Si-30 from -0.86 +/- 0.16 parts per thousand 2 s.e. to +0.04 +/- 0.03 parts per thousand for 11 chondrules), isolated olivines (delta Si-30 from -0.51 +/- 0.12 parts per thousand 2 s.e. to +0.20 +/- 0.10 parts per thousand for 12 olivines), and matrix (delta Si-30 from -0.95 +/- 0.08 parts per thousand 2 s.e. to -0.41 +/- 0.01 %o for 17 matrix fragments). These variations distribute on both sides of the bulk delta Si-30 value of Allende (-0.43 +/- 0.03 parts per thousand 2 s.e., Armytage et al., 2011; Pringle et al., 2013, 2014; Savage and Moynier, 2013). There is a global positive trend between 6 30 Si values and Mg/Fe ratio for chondrules and isolated olivines. This systematics appears in agreement with what can be modeled for producing Allende components, or their precursors, from fractionated condensation of a single gaseous reservoir having initially the silicon isotopic composition of bulk Allende. Mass balance taking into account the mean abundances and delta Si-30 values of Allende components is consistent with their accretion in the Allende parent body in the proportions produced by the condensation of the parent parcel of nebular gas. This supports complementarity between chondrules, olivines and matrix as being a primary feature. However, this conclusion cannot be definitive because of the uncertainties in defining mean delta Si-30 values for Allende components. (C) 2020 Elsevier B.V. All rights reserved.",
keywords = "silicon isotopes, Allende chondrite, condensation, complementarity, chondrules, MODERATELY VOLATILE ELEMENTS, SOLAR NEBULA, CHONDRULES, CONSTRAINTS, FRACTIONATION, CHONDRITES, MATRIX, EQUILIBRIUM, PLANETARY, OLIVINE",
author = "Rayssa Martins and Marc Chaussidon and Zhengbin Deng and Francesco Pignatale and Frederic Moynier",
year = "2021",
doi = "10.1016/j.epsl.2020.116678",
language = "English",
volume = "554",
journal = "Earth and Planetary Science Letters",
issn = "0012-821X",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - A condensation origin for the mass-dependent silicon isotopic variations in Allende components

T2 - implications for complementarity

AU - Martins, Rayssa

AU - Chaussidon, Marc

AU - Deng, Zhengbin

AU - Pignatale, Francesco

AU - Moynier, Frederic

PY - 2021

Y1 - 2021

N2 - Primitive chondrites have bulk compositions close to that of the solar photosphere, with however significant variations of elemental ratio relative to the solar composition, depending on the volatility of the elements considered. This is classically understood as indicating a primary geochemical signature due to the formation of the components of chondrites (refractory inclusions, chondrules and matrix), or of their precursors, through condensation of a gas of near solar composition, plus secondary variations due to processes such as (i) incomplete volatilization of presolar components, (ii) complex high-temperature exchanges between condensed phases and the nebular gas, and (iii) sorting and transport of grains in the accretion disk before accretion of chondrite parent bodies. Because most of the mass of chondrites is made by elements which condense at high temperatures, equilibrium condensation produces in general little isotopic fractionation for these elements. Silicon is however an exception with per mil level equilibrium isotopic fractionation at high temperature between the SiO gas and condensed silicates, allowing to use silicon isotopes in chondrites to constrain the origin of their components and to put at test scenarios of condensation.Individual components (chondrule fragments, isolated olivines in the matrix, and matrix fragments) of the carbonaceous chondrite Allende were separated and analysed at high-precision for their silicon isotopic composition. Large variations have been found among chondrules (delta Si-30 from -0.86 +/- 0.16 parts per thousand 2 s.e. to +0.04 +/- 0.03 parts per thousand for 11 chondrules), isolated olivines (delta Si-30 from -0.51 +/- 0.12 parts per thousand 2 s.e. to +0.20 +/- 0.10 parts per thousand for 12 olivines), and matrix (delta Si-30 from -0.95 +/- 0.08 parts per thousand 2 s.e. to -0.41 +/- 0.01 %o for 17 matrix fragments). These variations distribute on both sides of the bulk delta Si-30 value of Allende (-0.43 +/- 0.03 parts per thousand 2 s.e., Armytage et al., 2011; Pringle et al., 2013, 2014; Savage and Moynier, 2013). There is a global positive trend between 6 30 Si values and Mg/Fe ratio for chondrules and isolated olivines. This systematics appears in agreement with what can be modeled for producing Allende components, or their precursors, from fractionated condensation of a single gaseous reservoir having initially the silicon isotopic composition of bulk Allende. Mass balance taking into account the mean abundances and delta Si-30 values of Allende components is consistent with their accretion in the Allende parent body in the proportions produced by the condensation of the parent parcel of nebular gas. This supports complementarity between chondrules, olivines and matrix as being a primary feature. However, this conclusion cannot be definitive because of the uncertainties in defining mean delta Si-30 values for Allende components. (C) 2020 Elsevier B.V. All rights reserved.

AB - Primitive chondrites have bulk compositions close to that of the solar photosphere, with however significant variations of elemental ratio relative to the solar composition, depending on the volatility of the elements considered. This is classically understood as indicating a primary geochemical signature due to the formation of the components of chondrites (refractory inclusions, chondrules and matrix), or of their precursors, through condensation of a gas of near solar composition, plus secondary variations due to processes such as (i) incomplete volatilization of presolar components, (ii) complex high-temperature exchanges between condensed phases and the nebular gas, and (iii) sorting and transport of grains in the accretion disk before accretion of chondrite parent bodies. Because most of the mass of chondrites is made by elements which condense at high temperatures, equilibrium condensation produces in general little isotopic fractionation for these elements. Silicon is however an exception with per mil level equilibrium isotopic fractionation at high temperature between the SiO gas and condensed silicates, allowing to use silicon isotopes in chondrites to constrain the origin of their components and to put at test scenarios of condensation.Individual components (chondrule fragments, isolated olivines in the matrix, and matrix fragments) of the carbonaceous chondrite Allende were separated and analysed at high-precision for their silicon isotopic composition. Large variations have been found among chondrules (delta Si-30 from -0.86 +/- 0.16 parts per thousand 2 s.e. to +0.04 +/- 0.03 parts per thousand for 11 chondrules), isolated olivines (delta Si-30 from -0.51 +/- 0.12 parts per thousand 2 s.e. to +0.20 +/- 0.10 parts per thousand for 12 olivines), and matrix (delta Si-30 from -0.95 +/- 0.08 parts per thousand 2 s.e. to -0.41 +/- 0.01 %o for 17 matrix fragments). These variations distribute on both sides of the bulk delta Si-30 value of Allende (-0.43 +/- 0.03 parts per thousand 2 s.e., Armytage et al., 2011; Pringle et al., 2013, 2014; Savage and Moynier, 2013). There is a global positive trend between 6 30 Si values and Mg/Fe ratio for chondrules and isolated olivines. This systematics appears in agreement with what can be modeled for producing Allende components, or their precursors, from fractionated condensation of a single gaseous reservoir having initially the silicon isotopic composition of bulk Allende. Mass balance taking into account the mean abundances and delta Si-30 values of Allende components is consistent with their accretion in the Allende parent body in the proportions produced by the condensation of the parent parcel of nebular gas. This supports complementarity between chondrules, olivines and matrix as being a primary feature. However, this conclusion cannot be definitive because of the uncertainties in defining mean delta Si-30 values for Allende components. (C) 2020 Elsevier B.V. All rights reserved.

KW - silicon isotopes

KW - Allende chondrite

KW - condensation

KW - complementarity

KW - chondrules

KW - MODERATELY VOLATILE ELEMENTS

KW - SOLAR NEBULA

KW - CHONDRULES

KW - CONSTRAINTS

KW - FRACTIONATION

KW - CHONDRITES

KW - MATRIX

KW - EQUILIBRIUM

KW - PLANETARY

KW - OLIVINE

U2 - 10.1016/j.epsl.2020.116678

DO - 10.1016/j.epsl.2020.116678

M3 - Journal article

VL - 554

JO - Earth and Planetary Science Letters

JF - Earth and Planetary Science Letters

SN - 0012-821X

M1 - 116678

ER -

ID: 256886709