Litcius/Paper detail

Nitrogen sequestration in the core at megabar pressure and implications for terrestrial accretion

Dongyang Huang, Julien Siebert, Paolo A. Sossi, Edith Kubik, Guillaume Avice, Motohiko Murakami

2024Geochimica et Cosmochimica Acta15 citationsDOIOpen Access PDF

Abstract

Nitrogen (N) is the most abundant element in Earth’s atmosphere, but is extremely depleted in the silicate Earth. However, it is not clear whether core sequestration or early atmospheric loss was responsible for this depletion. Here we study the effect of core formation on the inventory of nitrogen using laser-heated diamond anvil cells. We find that, due to the simultaneous dissolution of oxygen in the metal, N becomes much less siderophile (iron-loving) at pressures and temperatures up to 104 GPa and 5000 K, a thermodynamic condition relevant to the bottom of the magma ocean in the aftermath of the moon-forming giant impact. Using a core-mantle-atmosphere coevolution model, we show that the impact-induced processes (core formation and/or atmospheric loss) are unlikely to account for the observed N anomaly, which is instead best explained by the accretion of mainly N-poor impactors. The terrestrial volatile pattern requires severe N depletion on precursor bodies, prior to their accretion to the proto-Earth.

Topics & Concepts

Accretion (finance)GeologyEarth scienceCore (optical fiber)AstrobiologyGeochemistryEnvironmental scienceMaterials sciencePhysicsAstrophysicsComposite materialAstro and Planetary ScienceHigh-pressure geophysics and materialsGeological and Geochemical Analysis