Evidence for nucleosynthetic enrichment of the protosolar molecular cloud core by multiple supernova events

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Evidence for nucleosynthetic enrichment of the protosolar molecular cloud core by multiple supernova events. / Schiller, Martin; Paton, Chad; Bizzarro, Martin.

In: Geochimica et Cosmochimica Acta, Vol. 149, 2015, p. 88-102.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Schiller, M, Paton, C & Bizzarro, M 2015, 'Evidence for nucleosynthetic enrichment of the protosolar molecular cloud core by multiple supernova events', Geochimica et Cosmochimica Acta, vol. 149, pp. 88-102. https://doi.org/10.1016/j.gca.2014.11.005

APA

Schiller, M., Paton, C., & Bizzarro, M. (2015). Evidence for nucleosynthetic enrichment of the protosolar molecular cloud core by multiple supernova events. Geochimica et Cosmochimica Acta, 149, 88-102. https://doi.org/10.1016/j.gca.2014.11.005

Vancouver

Schiller M, Paton C, Bizzarro M. Evidence for nucleosynthetic enrichment of the protosolar molecular cloud core by multiple supernova events. Geochimica et Cosmochimica Acta. 2015;149:88-102. https://doi.org/10.1016/j.gca.2014.11.005

Author

Schiller, Martin ; Paton, Chad ; Bizzarro, Martin. / Evidence for nucleosynthetic enrichment of the protosolar molecular cloud core by multiple supernova events. In: Geochimica et Cosmochimica Acta. 2015 ; Vol. 149. pp. 88-102.

Bibtex

@article{ce6f8a29b32c49e491afbcaacbd5ac67,
title = "Evidence for nucleosynthetic enrichment of the protosolar molecular cloud core by multiple supernova events",
abstract = "The presence of isotope heterogeneity of nucleosynthetic origin amongst meteorites and their components provides a record of the diverse stars that contributed matter to the protosolar molecular cloud core. Understanding how and when the solar system's nucleosynthetic heterogeneity was established and preserved within the solar protoplanetary disk is critical for unraveling the earliest formative stages of the solar system. Here, we report calcium and magnesium isotope measurements of primitive and differentiated meteorites as well as various types of refractory inclusions, including refractory inclusions (CAIs) formed with the canonical 26Al/27Al of ~5×10-5 (26Al decays to 26Mg with a half-life of ~0.73Ma) and CAIs that show fractionated and unidentified nuclear effects (FUN-CAIs) to understand the origin of the solar system's nucleosynthetic heterogeneity. Bulk analyses of primitive and differentiated meteorites along with canonical and FUN-CAIs define correlated, mass-independent variations in 43Ca, 46Ca and 48Ca. Moreover, sequential dissolution experiments of the Ivuna carbonaceous chondrite aimed at identifying the nature and number of presolar carriers of isotope anomalies within primitive meteorites have detected the presence of multiple carriers of the short-lived 26Al nuclide as well as carriers of anomalous and uncorrelated 43Ca, 46Ca and 48Ca compositions, which requires input from multiple and recent supernovae sources. We infer that the solar system's correlated nucleosynthetic variability reflects unmixing of old, galactically-inherited homogeneous dust from a new, supernovae-derived dust component formed shortly prior to or during the evolution of the giant molecular cloud parental to the protosolar molecular cloud core. This implies that similarly to 43Ca, 46Ca and 48Ca, the short-lived 26Al nuclide was heterogeneously distributed in the inner solar system at the time of CAI formation.",
author = "Martin Schiller and Chad Paton and Martin Bizzarro",
year = "2015",
doi = "10.1016/j.gca.2014.11.005",
language = "English",
volume = "149",
pages = "88--102",
journal = "Geochimica et Cosmochimica Acta",
issn = "0016-7037",
publisher = "Pergamon Press",

}

RIS

TY - JOUR

T1 - Evidence for nucleosynthetic enrichment of the protosolar molecular cloud core by multiple supernova events

AU - Schiller, Martin

AU - Paton, Chad

AU - Bizzarro, Martin

PY - 2015

Y1 - 2015

N2 - The presence of isotope heterogeneity of nucleosynthetic origin amongst meteorites and their components provides a record of the diverse stars that contributed matter to the protosolar molecular cloud core. Understanding how and when the solar system's nucleosynthetic heterogeneity was established and preserved within the solar protoplanetary disk is critical for unraveling the earliest formative stages of the solar system. Here, we report calcium and magnesium isotope measurements of primitive and differentiated meteorites as well as various types of refractory inclusions, including refractory inclusions (CAIs) formed with the canonical 26Al/27Al of ~5×10-5 (26Al decays to 26Mg with a half-life of ~0.73Ma) and CAIs that show fractionated and unidentified nuclear effects (FUN-CAIs) to understand the origin of the solar system's nucleosynthetic heterogeneity. Bulk analyses of primitive and differentiated meteorites along with canonical and FUN-CAIs define correlated, mass-independent variations in 43Ca, 46Ca and 48Ca. Moreover, sequential dissolution experiments of the Ivuna carbonaceous chondrite aimed at identifying the nature and number of presolar carriers of isotope anomalies within primitive meteorites have detected the presence of multiple carriers of the short-lived 26Al nuclide as well as carriers of anomalous and uncorrelated 43Ca, 46Ca and 48Ca compositions, which requires input from multiple and recent supernovae sources. We infer that the solar system's correlated nucleosynthetic variability reflects unmixing of old, galactically-inherited homogeneous dust from a new, supernovae-derived dust component formed shortly prior to or during the evolution of the giant molecular cloud parental to the protosolar molecular cloud core. This implies that similarly to 43Ca, 46Ca and 48Ca, the short-lived 26Al nuclide was heterogeneously distributed in the inner solar system at the time of CAI formation.

AB - The presence of isotope heterogeneity of nucleosynthetic origin amongst meteorites and their components provides a record of the diverse stars that contributed matter to the protosolar molecular cloud core. Understanding how and when the solar system's nucleosynthetic heterogeneity was established and preserved within the solar protoplanetary disk is critical for unraveling the earliest formative stages of the solar system. Here, we report calcium and magnesium isotope measurements of primitive and differentiated meteorites as well as various types of refractory inclusions, including refractory inclusions (CAIs) formed with the canonical 26Al/27Al of ~5×10-5 (26Al decays to 26Mg with a half-life of ~0.73Ma) and CAIs that show fractionated and unidentified nuclear effects (FUN-CAIs) to understand the origin of the solar system's nucleosynthetic heterogeneity. Bulk analyses of primitive and differentiated meteorites along with canonical and FUN-CAIs define correlated, mass-independent variations in 43Ca, 46Ca and 48Ca. Moreover, sequential dissolution experiments of the Ivuna carbonaceous chondrite aimed at identifying the nature and number of presolar carriers of isotope anomalies within primitive meteorites have detected the presence of multiple carriers of the short-lived 26Al nuclide as well as carriers of anomalous and uncorrelated 43Ca, 46Ca and 48Ca compositions, which requires input from multiple and recent supernovae sources. We infer that the solar system's correlated nucleosynthetic variability reflects unmixing of old, galactically-inherited homogeneous dust from a new, supernovae-derived dust component formed shortly prior to or during the evolution of the giant molecular cloud parental to the protosolar molecular cloud core. This implies that similarly to 43Ca, 46Ca and 48Ca, the short-lived 26Al nuclide was heterogeneously distributed in the inner solar system at the time of CAI formation.

U2 - 10.1016/j.gca.2014.11.005

DO - 10.1016/j.gca.2014.11.005

M3 - Journal article

C2 - 25684790

AN - SCOPUS:84913534879

VL - 149

SP - 88

EP - 102

JO - Geochimica et Cosmochimica Acta

JF - Geochimica et Cosmochimica Acta

SN - 0016-7037

ER -

ID: 137271886