# Testing the chondrule-rich accretion model for planetary embryos using   calcium isotopes

**Authors:** Elsa Amsellem, Fr\'ed\'eric Moynier, Emily A. Pringle, Audrey Bouvier,, Heng Chen, James M. D. Day

arXiv: 1704.05726 · 2017-04-24

## TL;DR

This study analyzes calcium isotopic compositions in chondrites and planetary bodies to evaluate the chondrule-rich accretion model for Earth's formation, finding similarities between Earth, Mars, and chondrules that support this model.

## Contribution

It provides new calcium isotope data for chondrites and chondrules, supporting the idea that Earth and Mars accreted from chondrule-rich materials.

## Key findings

- Most carbonaceous chondrites are enriched in lighter Ca isotopes compared to Earth.
- Enstatite chondrites have Ca isotopic compositions similar to Earth.
- Earth, Mars, and chondrules share similar Ca isotope signatures, supporting chondrule-rich accretion models.

## Abstract

Understanding the composition of raw materials that formed the Earth is a crucial step towards understanding the formation of terrestrial planets and their bulk composition. Calcium is the fifth most abundant element in terrestrial planets and, therefore, is a key element with which to trace planetary composition. However, in order to use Ca isotopes as a tracer of Earth's accretion history, it is first necessary to understand the isotopic behavior of Ca during the earliest stages of planetary formation. Chondrites are some of the oldest materials of the Solar System, and the study of their isotopic composition enables understanding of how and in what conditions the Solar System formed. Here we present Ca isotope data for a suite of bulk chondrites as well as Allende (CV) chondrules. We show that most groups of carbonaceous chondrites (CV, CI, CR and CM) are significantly enriched in the lighter Ca isotopes ($\delta^{44/40}Ca$ = +0.1 to +0.93 permill) compared with bulk silicate Earth ($\delta^{44/40}Ca$ = +1.05 $\pm$ 0.04 permill, Huang et al., 2010) or Mars, while enstatite chondrites are indistinguishable from Earth in Ca isotope composition ($\delta^{44/40}Ca$ = +0.91 to +1.06 permill). Chondrules from Allende are enriched in the heavier isotopes of Ca compared to the bulk and the matrix of the meteorite ($\delta^{44/40}Ca$ = +1.00 to +1.21 permill). This implies that Earth and Mars have Ca isotope compositions that are distinct from most carbonaceous chondrites but that may be like chondrules. This Ca isotopic similarity between Earth, Mars, and chondrules is permissive of recent dynamical models of planetary formation that propose a chondrule-rich accretion model for planetary embryos.

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Source: https://tomesphere.com/paper/1704.05726