Moderately volatile element behaviour at high temperature determined from nuclear detonation

J. M.D. Day; F. Moynier; P. A. Sossi; K. Wang; A. P. Meshik; O. V. Pravdivtseva; D. R. Pettit

doi:10.7185/geochemlet.2014

Moderately volatile element behaviour at high temperature determined from nuclear detonation

J. M.D. Day, F. Moynier, P. A. Sossi, K. Wang, A. P. Meshik, O. V. Pravdivtseva, D. R. Pettit

Research output: Contribution to journal › Article › peer-review

21 Scopus citations

Abstract

The first nuclear detonation, at the Trinity test site, is an analogue for high temperature volatile loss during planet formation processes. We report Cu isotope and abundance data, comparing them with Zn and K isotopes in trinitite glasses sampled with distance from the detonation centre. Copper concentrations drop, and isotopic compositions become ~0.3 % higher with proximity to the detonation. Relative sensitivity to high temperature evaporative isotopic fractionation processes occur in the order: Zn > Cu >> K. Lower volatility of K relative to Cu and Zn results from its low activity coefficient in silicate melts. Lunar mare basalt and some tektite Cu, Zn and K isotope compositions can be modelled using empirical fractionation factors (α) derived from trinitite. Combined with isotopic variations measured in mare basalts, the results support volatile loss during a magma ocean phase for the Moon.

Original language	English
Pages (from-to)	54-60
Number of pages	7
Journal	Geochemical Perspectives Letters
Volume	13
DOIs	https://doi.org/10.7185/geochemlet.2014
State	Published - Apr 16 2020

Access to Document

10.7185/geochemlet.2014

Cite this

@article{714bf1dd7ba749869b158246787d13f0,

title = "Moderately volatile element behaviour at high temperature determined from nuclear detonation",

abstract = "The first nuclear detonation, at the Trinity test site, is an analogue for high temperature volatile loss during planet formation processes. We report Cu isotope and abundance data, comparing them with Zn and K isotopes in trinitite glasses sampled with distance from the detonation centre. Copper concentrations drop, and isotopic compositions become \textasciitilde{}0.3 \% higher with proximity to the detonation. Relative sensitivity to high temperature evaporative isotopic fractionation processes occur in the order: Zn > Cu >> K. Lower volatility of K relative to Cu and Zn results from its low activity coefficient in silicate melts. Lunar mare basalt and some tektite Cu, Zn and K isotope compositions can be modelled using empirical fractionation factors (α) derived from trinitite. Combined with isotopic variations measured in mare basalts, the results support volatile loss during a magma ocean phase for the Moon.",

author = "Day, \{J. M.D.\} and F. Moynier and Sossi, \{P. A.\} and K. Wang and Meshik, \{A. P.\} and Pravdivtseva, \{O. V.\} and Pettit, \{D. R.\}",

note = "Publisher Copyright: {\textcopyright} 2020 The Authors Published by the European Association of Geochemistry",

year = "2020",

month = apr,

day = "16",

doi = "10.7185/geochemlet.2014",

language = "English",

volume = "13",

pages = "54--60",

journal = "Geochemical Perspectives Letters",

issn = "2410-339X",

}

TY - JOUR

T1 - Moderately volatile element behaviour at high temperature determined from nuclear detonation

AU - Day, J. M.D.

AU - Moynier, F.

AU - Sossi, P. A.

AU - Wang, K.

AU - Meshik, A. P.

AU - Pravdivtseva, O. V.

AU - Pettit, D. R.

PY - 2020/4/16

Y1 - 2020/4/16

N2 - The first nuclear detonation, at the Trinity test site, is an analogue for high temperature volatile loss during planet formation processes. We report Cu isotope and abundance data, comparing them with Zn and K isotopes in trinitite glasses sampled with distance from the detonation centre. Copper concentrations drop, and isotopic compositions become ~0.3 % higher with proximity to the detonation. Relative sensitivity to high temperature evaporative isotopic fractionation processes occur in the order: Zn > Cu >> K. Lower volatility of K relative to Cu and Zn results from its low activity coefficient in silicate melts. Lunar mare basalt and some tektite Cu, Zn and K isotope compositions can be modelled using empirical fractionation factors (α) derived from trinitite. Combined with isotopic variations measured in mare basalts, the results support volatile loss during a magma ocean phase for the Moon.

AB - The first nuclear detonation, at the Trinity test site, is an analogue for high temperature volatile loss during planet formation processes. We report Cu isotope and abundance data, comparing them with Zn and K isotopes in trinitite glasses sampled with distance from the detonation centre. Copper concentrations drop, and isotopic compositions become ~0.3 % higher with proximity to the detonation. Relative sensitivity to high temperature evaporative isotopic fractionation processes occur in the order: Zn > Cu >> K. Lower volatility of K relative to Cu and Zn results from its low activity coefficient in silicate melts. Lunar mare basalt and some tektite Cu, Zn and K isotope compositions can be modelled using empirical fractionation factors (α) derived from trinitite. Combined with isotopic variations measured in mare basalts, the results support volatile loss during a magma ocean phase for the Moon.

UR - https://www.scopus.com/pages/publications/85088944316

U2 - 10.7185/geochemlet.2014

DO - 10.7185/geochemlet.2014

M3 - Article

AN - SCOPUS:85088944316

SN - 2410-339X

VL - 13

SP - 54

EP - 60

JO - Geochemical Perspectives Letters

JF - Geochemical Perspectives Letters

ER -

Moderately volatile element behaviour at high temperature determined from nuclear detonation

Abstract

Access to Document

Other files and links

Fingerprint

Cite this