Sulfur isotope evidence for surface-derived sulfur in Eoarchean TTGs

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Sulfur isotope evidence for surface-derived sulfur in Eoarchean TTGs. / Lewis, Jonathan A.; Hoffmann, J. Elis; Schwarzenbach, Esther M.; Strauss, Harald; Liesegang, Moritz; Rosing, Minik T.

In: Earth and Planetary Science Letters, Vol. 576, 117218, 2021.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Lewis, JA, Hoffmann, JE, Schwarzenbach, EM, Strauss, H, Liesegang, M & Rosing, MT 2021, 'Sulfur isotope evidence for surface-derived sulfur in Eoarchean TTGs', Earth and Planetary Science Letters, vol. 576, 117218. https://doi.org/10.1016/j.epsl.2021.117218

APA

Lewis, J. A., Hoffmann, J. E., Schwarzenbach, E. M., Strauss, H., Liesegang, M., & Rosing, M. T. (2021). Sulfur isotope evidence for surface-derived sulfur in Eoarchean TTGs. Earth and Planetary Science Letters, 576, [117218]. https://doi.org/10.1016/j.epsl.2021.117218

Vancouver

Lewis JA, Hoffmann JE, Schwarzenbach EM, Strauss H, Liesegang M, Rosing MT. Sulfur isotope evidence for surface-derived sulfur in Eoarchean TTGs. Earth and Planetary Science Letters. 2021;576. 117218. https://doi.org/10.1016/j.epsl.2021.117218

Author

Lewis, Jonathan A. ; Hoffmann, J. Elis ; Schwarzenbach, Esther M. ; Strauss, Harald ; Liesegang, Moritz ; Rosing, Minik T. / Sulfur isotope evidence for surface-derived sulfur in Eoarchean TTGs. In: Earth and Planetary Science Letters. 2021 ; Vol. 576.

Bibtex

@article{e2acc12192ad46d997dd5e5b72049db6,
title = "Sulfur isotope evidence for surface-derived sulfur in Eoarchean TTGs",
abstract = "The conditions giving rise to the first evolved melts preserved on Earth remain a subject of debate. These melts formed tonalite-trondhjemite-granodiorites (TTGs) comprising the first cratonic cores. Constraining the nature of the rocks that melted to form these TTGs is crucial to understanding the mechanism that produced the first continents. Previous studies have indicated that TTGs' source rocks are hydrated mafic lithologies similar to modern arc tholeiitic basalts, comparable to amphibolites embedded in greenstone belts within Archean cratons. To elucidate the geodynamic setting of TTG formation, we investigated 3.9-3.6 Ga TTGs and amphibolites from the Itsaq Gneiss Complex (IGC), southern West Greenland using multiple sulfur isotope signatures, as well as textural and compositional analysis of selected sample sulfides. Small but significant nonzero Δ33S and Δ36S values were measured in the TTGs, with Δ33S values from 0.00‰ to +0.30‰, and Δ36S values from -0.13‰ to +0.80‰. Amphibolites yielded Δ33S values of -0.01‰ and +0.14‰, and Δ36S values of +0.08‰ and +0.23‰. These values are consistent with the presence of sedimentary sulfur, likely introduced to the sources of the TTGs' precursor rocks via horizontal tectonics. Sulfur in the TTGs was likely subject to mass independent fractionation on Earth's surface and may have experienced subsequent 34S enrichment during metamorphism in the TTGs' source rocks. Relative enrichment in 34S and 36S in TTGs may be explained by incorporation of fluid sampling hydrothermal deposits within the thickened mafic crust, released during arc accretion. This fluid may have triggered partial melting, forming the TTGs. Hence, the sulfur isotope composition of the TTGs represents a mixture of material derived from the source rocks by melting and from fluid released from other rocks bearing hydrothermally derived sulfur. Our results add weight to existing models of modern-like tectonic processes active in the Eoarchean.",
keywords = "Archean, Eoarchean, Isua, MIF-S, sulfur isotopes, TTGs",
author = "Lewis, {Jonathan A.} and Hoffmann, {J. Elis} and Schwarzenbach, {Esther M.} and Harald Strauss and Moritz Liesegang and Rosing, {Minik T.}",
note = "Publisher Copyright: {\textcopyright} 2021 Elsevier B.V.",
year = "2021",
doi = "10.1016/j.epsl.2021.117218",
language = "English",
volume = "576",
journal = "Earth and Planetary Science Letters",
issn = "0012-821X",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Sulfur isotope evidence for surface-derived sulfur in Eoarchean TTGs

AU - Lewis, Jonathan A.

AU - Hoffmann, J. Elis

AU - Schwarzenbach, Esther M.

AU - Strauss, Harald

AU - Liesegang, Moritz

AU - Rosing, Minik T.

N1 - Publisher Copyright: © 2021 Elsevier B.V.

PY - 2021

Y1 - 2021

N2 - The conditions giving rise to the first evolved melts preserved on Earth remain a subject of debate. These melts formed tonalite-trondhjemite-granodiorites (TTGs) comprising the first cratonic cores. Constraining the nature of the rocks that melted to form these TTGs is crucial to understanding the mechanism that produced the first continents. Previous studies have indicated that TTGs' source rocks are hydrated mafic lithologies similar to modern arc tholeiitic basalts, comparable to amphibolites embedded in greenstone belts within Archean cratons. To elucidate the geodynamic setting of TTG formation, we investigated 3.9-3.6 Ga TTGs and amphibolites from the Itsaq Gneiss Complex (IGC), southern West Greenland using multiple sulfur isotope signatures, as well as textural and compositional analysis of selected sample sulfides. Small but significant nonzero Δ33S and Δ36S values were measured in the TTGs, with Δ33S values from 0.00‰ to +0.30‰, and Δ36S values from -0.13‰ to +0.80‰. Amphibolites yielded Δ33S values of -0.01‰ and +0.14‰, and Δ36S values of +0.08‰ and +0.23‰. These values are consistent with the presence of sedimentary sulfur, likely introduced to the sources of the TTGs' precursor rocks via horizontal tectonics. Sulfur in the TTGs was likely subject to mass independent fractionation on Earth's surface and may have experienced subsequent 34S enrichment during metamorphism in the TTGs' source rocks. Relative enrichment in 34S and 36S in TTGs may be explained by incorporation of fluid sampling hydrothermal deposits within the thickened mafic crust, released during arc accretion. This fluid may have triggered partial melting, forming the TTGs. Hence, the sulfur isotope composition of the TTGs represents a mixture of material derived from the source rocks by melting and from fluid released from other rocks bearing hydrothermally derived sulfur. Our results add weight to existing models of modern-like tectonic processes active in the Eoarchean.

AB - The conditions giving rise to the first evolved melts preserved on Earth remain a subject of debate. These melts formed tonalite-trondhjemite-granodiorites (TTGs) comprising the first cratonic cores. Constraining the nature of the rocks that melted to form these TTGs is crucial to understanding the mechanism that produced the first continents. Previous studies have indicated that TTGs' source rocks are hydrated mafic lithologies similar to modern arc tholeiitic basalts, comparable to amphibolites embedded in greenstone belts within Archean cratons. To elucidate the geodynamic setting of TTG formation, we investigated 3.9-3.6 Ga TTGs and amphibolites from the Itsaq Gneiss Complex (IGC), southern West Greenland using multiple sulfur isotope signatures, as well as textural and compositional analysis of selected sample sulfides. Small but significant nonzero Δ33S and Δ36S values were measured in the TTGs, with Δ33S values from 0.00‰ to +0.30‰, and Δ36S values from -0.13‰ to +0.80‰. Amphibolites yielded Δ33S values of -0.01‰ and +0.14‰, and Δ36S values of +0.08‰ and +0.23‰. These values are consistent with the presence of sedimentary sulfur, likely introduced to the sources of the TTGs' precursor rocks via horizontal tectonics. Sulfur in the TTGs was likely subject to mass independent fractionation on Earth's surface and may have experienced subsequent 34S enrichment during metamorphism in the TTGs' source rocks. Relative enrichment in 34S and 36S in TTGs may be explained by incorporation of fluid sampling hydrothermal deposits within the thickened mafic crust, released during arc accretion. This fluid may have triggered partial melting, forming the TTGs. Hence, the sulfur isotope composition of the TTGs represents a mixture of material derived from the source rocks by melting and from fluid released from other rocks bearing hydrothermally derived sulfur. Our results add weight to existing models of modern-like tectonic processes active in the Eoarchean.

KW - Archean

KW - Eoarchean

KW - Isua, MIF-S

KW - sulfur isotopes

KW - TTGs

U2 - 10.1016/j.epsl.2021.117218

DO - 10.1016/j.epsl.2021.117218

M3 - Journal article

AN - SCOPUS:85116505747

VL - 576

JO - Earth and Planetary Science Letters

JF - Earth and Planetary Science Letters

SN - 0012-821X

M1 - 117218

ER -

ID: 284294408