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2D condensation model for the inner Solar Nebula: an enstatite-rich environment

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posted on 2024-07-26, 14:00 authored by F. C. Pignatale, Kurt LiffmanKurt Liffman, Sarah MaddisonSarah Maddison, Geoffrey BrooksGeoffrey Brooks
Infrared observations provide the dust composition in the protoplanetary discs surface layers, but cannot probe the dust chemistry in the mid-plane, where planet formation occurs. Meteorites show that dynamics was important in determining the dust distribution in the Solar Nebula and needs to be considered if we are to understand the global chemistry in discs. 1D radial condensation sequences can only simulate one disc layer at a time and cannot describe the global chemistry or the complexity of meteorites. To address these limitations, we compute for the first time the 2D distribution of condensates in the inner Solar Nebula using a thermodynamic equilibrium model, and derive time-scales for vertical settling and radial migration of dust. We find two enstatite-rich zones within 1 au from the young Sun: a band similar to 0.1 au thick in the upper optically-thin layer of the disc interior to 0.8 au, and in the optically-thick disc mid-plane out to similar to 0.4 au. The two enstatite-rich zones support recent evidence that Mercury and enstatite chondrites (ECs) shared a bulk material with similar composition. Our results are also consistent with infrared observation of protoplanetary disc which show emission of enstatite-rich dust in the inner surface of discs. The resulting chemistry and dynamics suggests that the formation of the bulk material of ECs occurred in the inner surface layer of the disc, within 0.4 au. We also propose a simple alternative scenario in which gas fractionation and vertical settling of the condensates lead to an enstatite-chondritic bulk material.

Funding

Commonwealth Scientific and Industrial Research Organisation

Agence Nationale de la Recherche

History

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ISSN

0035-8711

Journal title

Mon. Not. R. Astron. Soc.

Volume

457

Issue

2

Pagination

11 pp

Publisher

Oxford University Press

Copyright statement

This article has been accepted for publication in the Monthly Notices of the Royal Astronomical Society. Copyright © 2016 The Authors. Published by Oxford University Press on behalf of the Royal Astronomical Society.

Language

eng

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