Temporal evolution of 142Nd signatures in SW Greenland from high precision MC-ICP-MS measurements

Institut for Geovidenskab og Naturforvaltning

Temporal evolution of ¹⁴²Nd signatures in SW Greenland from high precision MC-ICP-MS measurements

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Standard

Temporal evolution of ¹⁴²Nd signatures in SW Greenland from high precision MC-ICP-MS measurements. / Hasenstab-Dübeler, Eric; Tusch, Jonas; Hoffmann, J. Elis; Fischer-Gödde, Mario; Szilas, Kristoffer; Münker, Carsten.

I: Chemical Geology, Bind 614, 121141, 2022.

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt

Harvard

Hasenstab-Dübeler, E, Tusch, J, Hoffmann, JE, Fischer-Gödde, M, Szilas, K & Münker, C 2022, 'Temporal evolution of ¹⁴²Nd signatures in SW Greenland from high precision MC-ICP-MS measurements', Chemical Geology, bind 614, 121141. https://doi.org/10.1016/j.chemgeo.2022.121141

APA

Hasenstab-Dübeler, E., Tusch, J., Hoffmann, J. E., Fischer-Gödde, M., Szilas, K., & Münker, C. (2022). Temporal evolution of ¹⁴²Nd signatures in SW Greenland from high precision MC-ICP-MS measurements. Chemical Geology, 614, [121141]. https://doi.org/10.1016/j.chemgeo.2022.121141

Vancouver

Hasenstab-Dübeler E, Tusch J, Hoffmann JE, Fischer-Gödde M, Szilas K, Münker C. Temporal evolution of ¹⁴²Nd signatures in SW Greenland from high precision MC-ICP-MS measurements. Chemical Geology. 2022;614. 121141. https://doi.org/10.1016/j.chemgeo.2022.121141

Author

Hasenstab-Dübeler, Eric ; Tusch, Jonas ; Hoffmann, J. Elis ; Fischer-Gödde, Mario ; Szilas, Kristoffer ; Münker, Carsten. / Temporal evolution of ¹⁴²Nd signatures in SW Greenland from high precision MC-ICP-MS measurements. I: Chemical Geology. 2022 ; Bind 614.

Bibtex

@article{7d630ece8793434b996fb1b01f3a967b,

title = "Temporal evolution of 142Nd signatures in SW Greenland from high precision MC-ICP-MS measurements",

abstract = "Measurements of 142Nd isotope signatures in Archean rocks are a powerful tool to investigate the earliest silicate differentiation events on Earth. Here, we introduce a new analytical protocol that allows high precision radiogenic and mass-independent Nd isotope measurements by MC-ICP-MS. To validate our method, we have measured well-characterized ∼3.72 to ∼3.8 Ga samples from the Eoarchean Itsaq Gneiss Complex and associated supracrustal belts, as well as Mesoarchean greenstones and a Proterozoic dike in SW Greenland, including lithostratigraphic units that were previously analyzed for 142-143Nd isotope systematics, by both TIMS and MC-ICP-MS. Our μ142Nd values for ∼3.72 to ∼3.8 Ga rocks from the Isua region range from +9.2 ± 2.6 to +13.2 ± 1.1 ppm and are in good agreement with previous studies. Using coupled 142,143Nd/144Nd isotope systematics from our data for ∼3.8 Ga mafic-ultramafic successions from the Isua region, we can confirm previous age constraints on the earliest silicate differentiation events with differentiation age of 4.390−0.060+0.045 Ga. Moreover, we can resolve a statistically significant decrease of 142Nd/144Nd isotope compositions in the ambient mantle of SW Greenland that already started to commence by Eoarchean time, between ∼3.8 Ga (μ142Nd = +13.0 ± 1.1) and ∼ 3.72 Ga (μ142Nd = +9.8 ± 1.0). Even lower but homogeneous μ142Nd values of +3.8 ± 1.1 are found in ∼3.4 Ga mantle-derived rocks from the Ameralik dike swarms. Our study reveals that ε143Nd(i) and εHf(i) values of Isua rocks scatter more than it would be expected from a single stage differentiation event as implied from nearly uniform μ142Nd values, suggesting that the previously described decoupling of Hf and Nd isotopes is not a primordial magma ocean signature. Instead, we conclude that some of second stage processes like younger mantle depletion events or recycling of subducted material affected the 147Sm[sbnd]143Nd isotope systematics. The preservation of pristine whole-rock isochrons largely rules out a significant disturbance by younger alteration events. Based on isotope and trace element modelling, we argue that the temporal evolution of coupled 142,143Nd/144Nd isotope compositions in the ambient mantle beneath the Isua rocks is best explained by the progressive admixture of material to the Isua mantle source that must have had present-day-like μ142Nd compositions. In contrast, Mesoarchean mafic rocks from the ∼3.08 Ga Ivisaartoq greenstone belt and the 2.97 Ga inner Ameralik Fjord region as well as a 2.0 Ga Proterozoic dike within that region all have higher μ142Nd values as would be expected from our simple replenishment model. This argues for reworking of older Isua crustal material that carried elevated μ142Nd compositions.",

keywords = "Archean, Hadean differentiation, Isua supracrustal belt: 142Nd, Mantle heterogeneity, MC ICP-MS",

author = "Eric Hasenstab-D{\"u}beler and Jonas Tusch and Hoffmann, {J. Elis} and Mario Fischer-G{\"o}dde and Kristoffer Szilas and Carsten M{\"u}nker",

note = "Publisher Copyright: {\textcopyright} 2022",

year = "2022",

doi = "10.1016/j.chemgeo.2022.121141",

language = "English",

volume = "614",

journal = "Chemical Geology",

issn = "0009-2541",

publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Temporal evolution of 142Nd signatures in SW Greenland from high precision MC-ICP-MS measurements

AU - Hasenstab-Dübeler, Eric

AU - Tusch, Jonas

AU - Hoffmann, J. Elis

AU - Fischer-Gödde, Mario

AU - Szilas, Kristoffer

AU - Münker, Carsten

PY - 2022

Y1 - 2022

N2 - Measurements of 142Nd isotope signatures in Archean rocks are a powerful tool to investigate the earliest silicate differentiation events on Earth. Here, we introduce a new analytical protocol that allows high precision radiogenic and mass-independent Nd isotope measurements by MC-ICP-MS. To validate our method, we have measured well-characterized ∼3.72 to ∼3.8 Ga samples from the Eoarchean Itsaq Gneiss Complex and associated supracrustal belts, as well as Mesoarchean greenstones and a Proterozoic dike in SW Greenland, including lithostratigraphic units that were previously analyzed for 142-143Nd isotope systematics, by both TIMS and MC-ICP-MS. Our μ142Nd values for ∼3.72 to ∼3.8 Ga rocks from the Isua region range from +9.2 ± 2.6 to +13.2 ± 1.1 ppm and are in good agreement with previous studies. Using coupled 142,143Nd/144Nd isotope systematics from our data for ∼3.8 Ga mafic-ultramafic successions from the Isua region, we can confirm previous age constraints on the earliest silicate differentiation events with differentiation age of 4.390−0.060+0.045 Ga. Moreover, we can resolve a statistically significant decrease of 142Nd/144Nd isotope compositions in the ambient mantle of SW Greenland that already started to commence by Eoarchean time, between ∼3.8 Ga (μ142Nd = +13.0 ± 1.1) and ∼ 3.72 Ga (μ142Nd = +9.8 ± 1.0). Even lower but homogeneous μ142Nd values of +3.8 ± 1.1 are found in ∼3.4 Ga mantle-derived rocks from the Ameralik dike swarms. Our study reveals that ε143Nd(i) and εHf(i) values of Isua rocks scatter more than it would be expected from a single stage differentiation event as implied from nearly uniform μ142Nd values, suggesting that the previously described decoupling of Hf and Nd isotopes is not a primordial magma ocean signature. Instead, we conclude that some of second stage processes like younger mantle depletion events or recycling of subducted material affected the 147Sm[sbnd]143Nd isotope systematics. The preservation of pristine whole-rock isochrons largely rules out a significant disturbance by younger alteration events. Based on isotope and trace element modelling, we argue that the temporal evolution of coupled 142,143Nd/144Nd isotope compositions in the ambient mantle beneath the Isua rocks is best explained by the progressive admixture of material to the Isua mantle source that must have had present-day-like μ142Nd compositions. In contrast, Mesoarchean mafic rocks from the ∼3.08 Ga Ivisaartoq greenstone belt and the 2.97 Ga inner Ameralik Fjord region as well as a 2.0 Ga Proterozoic dike within that region all have higher μ142Nd values as would be expected from our simple replenishment model. This argues for reworking of older Isua crustal material that carried elevated μ142Nd compositions.

AB - Measurements of 142Nd isotope signatures in Archean rocks are a powerful tool to investigate the earliest silicate differentiation events on Earth. Here, we introduce a new analytical protocol that allows high precision radiogenic and mass-independent Nd isotope measurements by MC-ICP-MS. To validate our method, we have measured well-characterized ∼3.72 to ∼3.8 Ga samples from the Eoarchean Itsaq Gneiss Complex and associated supracrustal belts, as well as Mesoarchean greenstones and a Proterozoic dike in SW Greenland, including lithostratigraphic units that were previously analyzed for 142-143Nd isotope systematics, by both TIMS and MC-ICP-MS. Our μ142Nd values for ∼3.72 to ∼3.8 Ga rocks from the Isua region range from +9.2 ± 2.6 to +13.2 ± 1.1 ppm and are in good agreement with previous studies. Using coupled 142,143Nd/144Nd isotope systematics from our data for ∼3.8 Ga mafic-ultramafic successions from the Isua region, we can confirm previous age constraints on the earliest silicate differentiation events with differentiation age of 4.390−0.060+0.045 Ga. Moreover, we can resolve a statistically significant decrease of 142Nd/144Nd isotope compositions in the ambient mantle of SW Greenland that already started to commence by Eoarchean time, between ∼3.8 Ga (μ142Nd = +13.0 ± 1.1) and ∼ 3.72 Ga (μ142Nd = +9.8 ± 1.0). Even lower but homogeneous μ142Nd values of +3.8 ± 1.1 are found in ∼3.4 Ga mantle-derived rocks from the Ameralik dike swarms. Our study reveals that ε143Nd(i) and εHf(i) values of Isua rocks scatter more than it would be expected from a single stage differentiation event as implied from nearly uniform μ142Nd values, suggesting that the previously described decoupling of Hf and Nd isotopes is not a primordial magma ocean signature. Instead, we conclude that some of second stage processes like younger mantle depletion events or recycling of subducted material affected the 147Sm[sbnd]143Nd isotope systematics. The preservation of pristine whole-rock isochrons largely rules out a significant disturbance by younger alteration events. Based on isotope and trace element modelling, we argue that the temporal evolution of coupled 142,143Nd/144Nd isotope compositions in the ambient mantle beneath the Isua rocks is best explained by the progressive admixture of material to the Isua mantle source that must have had present-day-like μ142Nd compositions. In contrast, Mesoarchean mafic rocks from the ∼3.08 Ga Ivisaartoq greenstone belt and the 2.97 Ga inner Ameralik Fjord region as well as a 2.0 Ga Proterozoic dike within that region all have higher μ142Nd values as would be expected from our simple replenishment model. This argues for reworking of older Isua crustal material that carried elevated μ142Nd compositions.

KW - Archean

KW - Hadean differentiation

KW - Isua supracrustal belt: 142Nd

KW - Mantle heterogeneity

KW - MC ICP-MS

U2 - 10.1016/j.chemgeo.2022.121141

DO - 10.1016/j.chemgeo.2022.121141

M3 - Journal article

AN - SCOPUS:85141443488

VL - 614

JO - Chemical Geology

JF - Chemical Geology

SN - 0009-2541

M1 - 121141

ER -

ID: 329289717