Tungsten isotope evolution during Earth's formation and new constraints on the viability of accretion simulations

TL;DR

This study refines Earth's tungsten isotope evolution models by integrating advanced impact simulations and isotopic data, providing new constraints on Earth's accretion timeline and the Moon's formation age.

Contribution

It introduces a multistage core-formation model incorporating impact melting and isotopic evolution, reducing uncertainties in Earth's accretion chronology.

Findings

Only one N-body simulation matches Earth's W isotope anomaly.

The Moon's formation likely occurred between 53-183 million years after solar system start.

The duration of magma ocean solidification significantly influences tungsten isotope signatures.

Abstract

The Hf-W isotopic system is the reference chronometer for determining the chronology of Earth's accretion and differentiation. However, its results depend strongly on uncertain parameters, including the extent of metal-silicate equilibration and the siderophility of tungsten. Here we show that a multistage core-formation model based on N-body accretion simulations, element mass balance and metal-silicate partitioning, largely eliminates these uncertainties. We modified the original model of Rubie et al. (2015) by including (1) smoothed particle hydrodynamics estimates of the depth of melting caused by giant impacts and (2) the isotopic evolution of 182W. We applied two metal-silicate fractionation mechanisms: one when the metal delivered by the cores of large impactors equilibrates with only a small fraction of the impact-induced magma pond and the other when metal delivered by small impactors emulsifies in global magma oceans before undergoing progressive segregation. The latter is crucial for fitting the W abundance and 182W anomaly of Earth's mantle. In addition, we show, for the first time, that the duration of magma ocean solidification has a major effect on Earth's tungsten isotope anomaly. We re-evaluate the six Grand Tack N-body simulations of Rubie et al. (2015). Only one reproduces epsilon182W=1.9+/-0.1 of Earth's mantle, otherwise accretion is either too fast or too slow. Depending on the characteristics of the giant impacts, results predict that the Moon formed either 143-183 Myr or 53-62 Myr after the start of the solar system. Thus, independent evaluations of the Moon's age provide an additional constraint on the validity of accretion simulations.