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Main Authors: Kong, Zhihui, Liu, Beibei, ZhangZhou, J., Tang, Haolan, Deng, Zhengbin, Xia, Qun-Ke, Grimm, Simon L., Lee, Man Hoi, Huang, Yi, Qin, Liping, Jiang, Jonathan H.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.30783
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author Kong, Zhihui
Liu, Beibei
ZhangZhou, J.
Tang, Haolan
Deng, Zhengbin
Xia, Qun-Ke
Grimm, Simon L.
Lee, Man Hoi
Huang, Yi
Qin, Liping
Jiang, Jonathan H.
author_facet Kong, Zhihui
Liu, Beibei
ZhangZhou, J.
Tang, Haolan
Deng, Zhengbin
Xia, Qun-Ke
Grimm, Simon L.
Lee, Man Hoi
Huang, Yi
Qin, Liping
Jiang, Jonathan H.
contents The distinct physical and geochemical differences between Earth and Mars provide fundamental constraints on terrestrial planet formation, yet a self-consistent framework linking dynamical and chemical aspects remains elusive. Here we present an integrated modeling framework that couples high-resolution N-body simulations with impact-driven metal-silicate equilibration to track the dynamical accretion history and chemical differentiation for Earth and Mars. Using a narrow ring planetesimal accretion scenario, we show that Earth and Mars analogs naturally sample systematically different solid reservoirs within the protoplanetary disk. Earth analogs preferentially accrete reduced material around the planetesimal ring center, whereas Mars analogs acquire a larger fraction of oxidized material exterior to the ring. This leads to diverse bulk redox states, with composition further modified by impact-dependent pressure-temperature equilibration conditions during core formation. As a result, Earth analogs experience deeper equilibration and more efficient transfer of iron into the core, producing mantles with low iron oxide contents and larger core mass fractions. In contrast, Mars analogs equilibrate at shallower conditions, retain more iron in their mantles, and develop smaller cores. Our results demonstrate that the dynamical and geochemical differences between Earth and Mars emerge from the coupled effects of accretion pathways, the disk's radial redox structure and impact-controlled differentiation, rather than from any single process. Our unified framework physically explains the geochemical diversity of terrestrial planets and offers a potential pathway to interpret compositions of rocky planets in exoplanetary systems.
format Preprint
id arxiv_https___arxiv_org_abs_2605_30783
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Coupling dynamical accretion and chemical differentiation: a unified framework for Earth-Mars diversity
Kong, Zhihui
Liu, Beibei
ZhangZhou, J.
Tang, Haolan
Deng, Zhengbin
Xia, Qun-Ke
Grimm, Simon L.
Lee, Man Hoi
Huang, Yi
Qin, Liping
Jiang, Jonathan H.
Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
The distinct physical and geochemical differences between Earth and Mars provide fundamental constraints on terrestrial planet formation, yet a self-consistent framework linking dynamical and chemical aspects remains elusive. Here we present an integrated modeling framework that couples high-resolution N-body simulations with impact-driven metal-silicate equilibration to track the dynamical accretion history and chemical differentiation for Earth and Mars. Using a narrow ring planetesimal accretion scenario, we show that Earth and Mars analogs naturally sample systematically different solid reservoirs within the protoplanetary disk. Earth analogs preferentially accrete reduced material around the planetesimal ring center, whereas Mars analogs acquire a larger fraction of oxidized material exterior to the ring. This leads to diverse bulk redox states, with composition further modified by impact-dependent pressure-temperature equilibration conditions during core formation. As a result, Earth analogs experience deeper equilibration and more efficient transfer of iron into the core, producing mantles with low iron oxide contents and larger core mass fractions. In contrast, Mars analogs equilibrate at shallower conditions, retain more iron in their mantles, and develop smaller cores. Our results demonstrate that the dynamical and geochemical differences between Earth and Mars emerge from the coupled effects of accretion pathways, the disk's radial redox structure and impact-controlled differentiation, rather than from any single process. Our unified framework physically explains the geochemical diversity of terrestrial planets and offers a potential pathway to interpret compositions of rocky planets in exoplanetary systems.
title Coupling dynamical accretion and chemical differentiation: a unified framework for Earth-Mars diversity
topic Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
url https://arxiv.org/abs/2605.30783