Thermal equilibration of iron meteorite and pallasite parent bodies recorded at the mineral scale by Fe and Ni isotope systematics

Stepan M. Chernonozhkin; Mona Weyrauch; Steven Goderis; Martin Oeser; Seann J. McKibbin; Ingo Horn; Lutz Hecht; Stefan Weyer; Philippe Claeys; Frank Vanhaecke

doi:10.1016/j.gca.2017.08.022

Details

Originalsprache	Englisch
Seiten (von - bis)	95-111
Seitenumfang	17
Fachzeitschrift	Geochimica et cosmochimica acta
Jahrgang	217
Publikationsstatus	Veröffentlicht - 15 Nov. 2017

Abstract

In this work, a femtosecond laser ablation (LA) system coupled to a multi-collector inductively coupled plasma-mass spectrometer (fs-LA-MC-ICP-MS) was used to obtain laterally resolved (30–80 μm), high-precision combined Ni and Fe stable isotope ratio data for a variety of mineral phases (olivine, kamacite, taenite, schreibersite and troilite) composing main group pallasites (PMG) and iron meteorites. The stable isotopic signatures of Fe and Ni at the mineral scale, in combination with the factors governing the kinetic or equilibrium isotope fractionation processes, are used to interpret the thermal histories of small differentiated asteroidal bodies. As Fe isotopic zoning is only barely resolvable within the internal precision level of the isotope ratio measurements within a single olivine in Esquel PMG, the isotopically lighter olivine core relative to the rim (Δ^56/54Fe_rim-core = 0.059‰) suggests that the olivines were largely thermally equilibrated. The observed hint of an isotopic and concentration gradient for Fe of crudely similar width is interpreted here to reflect Fe loss from olivine in the process of partial reduction of the olivine rim. The ranges of the determined Fe and Ni isotopic signatures of troilite (δ^56/54Fe of −0.66 to −0.09‰) and schreibersite (δ^56/54Fe of −0.48 to −0.09‰, and δ^62/60Ni of −0.64 to +0.29‰) may result from thermal equilibration. Schreibersite and troilite likely remained in equilibrium with their enclosing metal to temperatures significantly below their point of crystallization. The Ni isotopic signatures of bulk metal and schreibersite correlate negatively, with isotopically lighter Ni in the metal of PMGs and isotopically heavier Ni in the metal of the iron meteorites analyzed. As such, the light Ni isotopic signatures previously observed in PMG metal relative to chondrites may not result from heterogeneity in the Solar Nebula, but rather reflect fractionation in the metal-schreibersite system. Comparison between the isotope ratio profiles of Fe and Ni determined across kamacite-taenite interfaces (Δ^56/54Fe_kam-tae = −0.51 to −0.69‰ and Δ^62/60Ni_kam-tae = +1.59 to +2.50‰) and theoretical taenite sub-solidus diffusive isotopic zoning broadly constrain the cooling rates of Esquel, CMS 04071 PMGs and Udei Station IAB to between ∼25 and 500 °C/Myr.

ASJC Scopus Sachgebiete

Erdkunde und Planetologie (insg.)
Geochemie und Petrologie

Zitieren

Thermal equilibration of iron meteorite and pallasite parent bodies recorded at the mineral scale by Fe and Ni isotope systematics. / Chernonozhkin, Stepan M.; Weyrauch, Mona; Goderis, Steven et al.
in: Geochimica et cosmochimica acta, Jahrgang 217, 15.11.2017, S. 95-111.

Publikation: Beitrag in Fachzeitschrift › Artikel › Forschung › Peer-Review

Chernonozhkin, SM, Weyrauch, M, Goderis, S, Oeser, M, McKibbin, SJ, Horn, I, Hecht, L, Weyer, S, Claeys, P & Vanhaecke, F 2017, 'Thermal equilibration of iron meteorite and pallasite parent bodies recorded at the mineral scale by Fe and Ni isotope systematics', Geochimica et cosmochimica acta, Jg. 217, S. 95-111. https://doi.org/10.1016/j.gca.2017.08.022

Chernonozhkin, S. M., Weyrauch, M., Goderis, S., Oeser, M., McKibbin, S. J., Horn, I., Hecht, L., Weyer, S., Claeys, P., & Vanhaecke, F. (2017). Thermal equilibration of iron meteorite and pallasite parent bodies recorded at the mineral scale by Fe and Ni isotope systematics. Geochimica et cosmochimica acta, 217, 95-111. https://doi.org/10.1016/j.gca.2017.08.022

Chernonozhkin SM, Weyrauch M, Goderis S, Oeser M, McKibbin SJ, Horn I et al. Thermal equilibration of iron meteorite and pallasite parent bodies recorded at the mineral scale by Fe and Ni isotope systematics. Geochimica et cosmochimica acta. 2017 Nov 15;217:95-111. doi: 10.1016/j.gca.2017.08.022

Chernonozhkin, Stepan M. ; Weyrauch, Mona ; Goderis, Steven et al. / Thermal equilibration of iron meteorite and pallasite parent bodies recorded at the mineral scale by Fe and Ni isotope systematics. in: Geochimica et cosmochimica acta. 2017 ; Jahrgang 217. S. 95-111.

Download

@article{4d84abb4d2f94fad98ca26ce1f4bda11,

title = "Thermal equilibration of iron meteorite and pallasite parent bodies recorded at the mineral scale by Fe and Ni isotope systematics",

abstract = "In this work, a femtosecond laser ablation (LA) system coupled to a multi-collector inductively coupled plasma-mass spectrometer (fs-LA-MC-ICP-MS) was used to obtain laterally resolved (30–80 μm), high-precision combined Ni and Fe stable isotope ratio data for a variety of mineral phases (olivine, kamacite, taenite, schreibersite and troilite) composing main group pallasites (PMG) and iron meteorites. The stable isotopic signatures of Fe and Ni at the mineral scale, in combination with the factors governing the kinetic or equilibrium isotope fractionation processes, are used to interpret the thermal histories of small differentiated asteroidal bodies. As Fe isotopic zoning is only barely resolvable within the internal precision level of the isotope ratio measurements within a single olivine in Esquel PMG, the isotopically lighter olivine core relative to the rim (Δ56/54Ferim-core = 0.059‰) suggests that the olivines were largely thermally equilibrated. The observed hint of an isotopic and concentration gradient for Fe of crudely similar width is interpreted here to reflect Fe loss from olivine in the process of partial reduction of the olivine rim. The ranges of the determined Fe and Ni isotopic signatures of troilite (δ56/54Fe of −0.66 to −0.09‰) and schreibersite (δ56/54Fe of −0.48 to −0.09‰, and δ62/60Ni of −0.64 to +0.29‰) may result from thermal equilibration. Schreibersite and troilite likely remained in equilibrium with their enclosing metal to temperatures significantly below their point of crystallization. The Ni isotopic signatures of bulk metal and schreibersite correlate negatively, with isotopically lighter Ni in the metal of PMGs and isotopically heavier Ni in the metal of the iron meteorites analyzed. As such, the light Ni isotopic signatures previously observed in PMG metal relative to chondrites may not result from heterogeneity in the Solar Nebula, but rather reflect fractionation in the metal-schreibersite system. Comparison between the isotope ratio profiles of Fe and Ni determined across kamacite-taenite interfaces (Δ56/54Fekam-tae = −0.51 to −0.69‰ and Δ62/60Nikam-tae = +1.59 to +2.50‰) and theoretical taenite sub-solidus diffusive isotopic zoning broadly constrain the cooling rates of Esquel, CMS 04071 PMGs and Udei Station IAB to between ∼25 and 500 °C/Myr.",

keywords = "Core formation, Fe and Ni stable isotope ratios, Iron meteorites, Pallasites, Schreibersite",

author = "Chernonozhkin, {Stepan M.} and Mona Weyrauch and Steven Goderis and Martin Oeser and McKibbin, {Seann J.} and Ingo Horn and Lutz Hecht and Stefan Weyer and Philippe Claeys and Frank Vanhaecke",

year = "2017",

month = nov,

day = "15",

doi = "10.1016/j.gca.2017.08.022",

language = "English",

volume = "217",

pages = "95--111",

journal = "Geochimica et cosmochimica acta",

issn = "0016-7037",

publisher = "Elsevier Ltd.",

}

Download

TY - JOUR

T1 - Thermal equilibration of iron meteorite and pallasite parent bodies recorded at the mineral scale by Fe and Ni isotope systematics

AU - Chernonozhkin, Stepan M.

AU - Weyrauch, Mona

AU - Goderis, Steven

AU - Oeser, Martin

AU - McKibbin, Seann J.

AU - Horn, Ingo

AU - Hecht, Lutz

AU - Weyer, Stefan

AU - Claeys, Philippe

AU - Vanhaecke, Frank

PY - 2017/11/15

Y1 - 2017/11/15

N2 - In this work, a femtosecond laser ablation (LA) system coupled to a multi-collector inductively coupled plasma-mass spectrometer (fs-LA-MC-ICP-MS) was used to obtain laterally resolved (30–80 μm), high-precision combined Ni and Fe stable isotope ratio data for a variety of mineral phases (olivine, kamacite, taenite, schreibersite and troilite) composing main group pallasites (PMG) and iron meteorites. The stable isotopic signatures of Fe and Ni at the mineral scale, in combination with the factors governing the kinetic or equilibrium isotope fractionation processes, are used to interpret the thermal histories of small differentiated asteroidal bodies. As Fe isotopic zoning is only barely resolvable within the internal precision level of the isotope ratio measurements within a single olivine in Esquel PMG, the isotopically lighter olivine core relative to the rim (Δ56/54Ferim-core = 0.059‰) suggests that the olivines were largely thermally equilibrated. The observed hint of an isotopic and concentration gradient for Fe of crudely similar width is interpreted here to reflect Fe loss from olivine in the process of partial reduction of the olivine rim. The ranges of the determined Fe and Ni isotopic signatures of troilite (δ56/54Fe of −0.66 to −0.09‰) and schreibersite (δ56/54Fe of −0.48 to −0.09‰, and δ62/60Ni of −0.64 to +0.29‰) may result from thermal equilibration. Schreibersite and troilite likely remained in equilibrium with their enclosing metal to temperatures significantly below their point of crystallization. The Ni isotopic signatures of bulk metal and schreibersite correlate negatively, with isotopically lighter Ni in the metal of PMGs and isotopically heavier Ni in the metal of the iron meteorites analyzed. As such, the light Ni isotopic signatures previously observed in PMG metal relative to chondrites may not result from heterogeneity in the Solar Nebula, but rather reflect fractionation in the metal-schreibersite system. Comparison between the isotope ratio profiles of Fe and Ni determined across kamacite-taenite interfaces (Δ56/54Fekam-tae = −0.51 to −0.69‰ and Δ62/60Nikam-tae = +1.59 to +2.50‰) and theoretical taenite sub-solidus diffusive isotopic zoning broadly constrain the cooling rates of Esquel, CMS 04071 PMGs and Udei Station IAB to between ∼25 and 500 °C/Myr.

AB - In this work, a femtosecond laser ablation (LA) system coupled to a multi-collector inductively coupled plasma-mass spectrometer (fs-LA-MC-ICP-MS) was used to obtain laterally resolved (30–80 μm), high-precision combined Ni and Fe stable isotope ratio data for a variety of mineral phases (olivine, kamacite, taenite, schreibersite and troilite) composing main group pallasites (PMG) and iron meteorites. The stable isotopic signatures of Fe and Ni at the mineral scale, in combination with the factors governing the kinetic or equilibrium isotope fractionation processes, are used to interpret the thermal histories of small differentiated asteroidal bodies. As Fe isotopic zoning is only barely resolvable within the internal precision level of the isotope ratio measurements within a single olivine in Esquel PMG, the isotopically lighter olivine core relative to the rim (Δ56/54Ferim-core = 0.059‰) suggests that the olivines were largely thermally equilibrated. The observed hint of an isotopic and concentration gradient for Fe of crudely similar width is interpreted here to reflect Fe loss from olivine in the process of partial reduction of the olivine rim. The ranges of the determined Fe and Ni isotopic signatures of troilite (δ56/54Fe of −0.66 to −0.09‰) and schreibersite (δ56/54Fe of −0.48 to −0.09‰, and δ62/60Ni of −0.64 to +0.29‰) may result from thermal equilibration. Schreibersite and troilite likely remained in equilibrium with their enclosing metal to temperatures significantly below their point of crystallization. The Ni isotopic signatures of bulk metal and schreibersite correlate negatively, with isotopically lighter Ni in the metal of PMGs and isotopically heavier Ni in the metal of the iron meteorites analyzed. As such, the light Ni isotopic signatures previously observed in PMG metal relative to chondrites may not result from heterogeneity in the Solar Nebula, but rather reflect fractionation in the metal-schreibersite system. Comparison between the isotope ratio profiles of Fe and Ni determined across kamacite-taenite interfaces (Δ56/54Fekam-tae = −0.51 to −0.69‰ and Δ62/60Nikam-tae = +1.59 to +2.50‰) and theoretical taenite sub-solidus diffusive isotopic zoning broadly constrain the cooling rates of Esquel, CMS 04071 PMGs and Udei Station IAB to between ∼25 and 500 °C/Myr.

KW - Core formation

KW - Fe and Ni stable isotope ratios

KW - Iron meteorites

KW - Pallasites

KW - Schreibersite

UR - http://www.scopus.com/inward/record.url?scp=85028504270&partnerID=8YFLogxK

U2 - 10.1016/j.gca.2017.08.022

DO - 10.1016/j.gca.2017.08.022

M3 - Article

AN - SCOPUS:85028504270

VL - 217

SP - 95

EP - 111

JO - Geochimica et cosmochimica acta

JF - Geochimica et cosmochimica acta

SN - 0016-7037

ER -

Research@Leibniz University

Thermal equilibration of iron meteorite and pallasite parent bodies recorded at the mineral scale by Fe and Ni isotope systematics

Autoren

Organisationseinheiten

Externe Organisationen

Details

Abstract

ASJC Scopus Sachgebiete

Zitieren

Von denselben Autoren

Weathering-induced Sb isotope fractionation during leaching of stibnite and formation of secondary Sb minerals

High-temperature boron partitioning and isotope fractionation between basaltic melt and fluid

Antimony Isotope Fractionation during Kinetic Sb(III) Oxidation by Antimony-Oxidizing Bacteria Pseudomonas sp. J1

Trace element (Be, Zn, Ga, Rb, Nb, Cs, Ta, W) partitioning between mica and Li-rich granitic melt: Experimental approach and implications for W mineralization

Pentavalent U Reactivity Impacts U Isotopic Fractionation during Reduction by Magnetite