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Main Authors: Vorobyov, Eduard I., Whalen, Daniel J., Latif, Muhammad A., Skliarevskii, Alexander M., Jessop, Christopher, Matsukoba, Ryoki, Hosokawa, Takashi, Nandal, Devesh
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.08375
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author Vorobyov, Eduard I.
Whalen, Daniel J.
Latif, Muhammad A.
Skliarevskii, Alexander M.
Jessop, Christopher
Matsukoba, Ryoki
Hosokawa, Takashi
Nandal, Devesh
author_facet Vorobyov, Eduard I.
Whalen, Daniel J.
Latif, Muhammad A.
Skliarevskii, Alexander M.
Jessop, Christopher
Matsukoba, Ryoki
Hosokawa, Takashi
Nandal, Devesh
contents Primordial, or Pop III, supernovae (SNe) were the first, great nucleosynthetic engines in the Universe, forging the heavy elements required for the later formation of planets, and life. Past studies suggest that the rise of planet formation was gradual, and did not peak until about half of the present age of the Universe after cosmic mean metallicities exceeded a critical value. Here we show that planetesimals, the precursors of terrestrial planets, can form around low-mass, long-lived stars in the debris of the first cosmic explosions 200 Myr after the Big Bang, before the first galaxies and far earlier than previously thought. Pop III pair-instability SNe, which can eject over 100 solar masses of metals, produced dense cloud cores that were enriched to metallicities $\gtrsim$ 0.1 Z$_{\odot}$. One such core in our cosmological simulation with a Jeans mass of just 1 - 2 M$_{\odot}$ collapsed to a protoplanetary disk in which several Earth masses of planetesimals formed 0.46 - 1.1 AU from their parent 0.7 M$_{\odot}$ star. The protoplanetary disk has H$_2$O mass fractions that are only a factor of a few less than in the Solar System today, and planetesimal formation occurs within the water snowline of the star. This raises the possibility of subsequent enrichment of the first planets in the Universe with water, in direct analogy to Earth in the Solar system.
format Preprint
id arxiv_https___arxiv_org_abs_2501_08375
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Planetesimals Formed in H$_2$O-Rich Disks at Cosmic Dawn
Vorobyov, Eduard I.
Whalen, Daniel J.
Latif, Muhammad A.
Skliarevskii, Alexander M.
Jessop, Christopher
Matsukoba, Ryoki
Hosokawa, Takashi
Nandal, Devesh
Astrophysics of Galaxies
Primordial, or Pop III, supernovae (SNe) were the first, great nucleosynthetic engines in the Universe, forging the heavy elements required for the later formation of planets, and life. Past studies suggest that the rise of planet formation was gradual, and did not peak until about half of the present age of the Universe after cosmic mean metallicities exceeded a critical value. Here we show that planetesimals, the precursors of terrestrial planets, can form around low-mass, long-lived stars in the debris of the first cosmic explosions 200 Myr after the Big Bang, before the first galaxies and far earlier than previously thought. Pop III pair-instability SNe, which can eject over 100 solar masses of metals, produced dense cloud cores that were enriched to metallicities $\gtrsim$ 0.1 Z$_{\odot}$. One such core in our cosmological simulation with a Jeans mass of just 1 - 2 M$_{\odot}$ collapsed to a protoplanetary disk in which several Earth masses of planetesimals formed 0.46 - 1.1 AU from their parent 0.7 M$_{\odot}$ star. The protoplanetary disk has H$_2$O mass fractions that are only a factor of a few less than in the Solar System today, and planetesimal formation occurs within the water snowline of the star. This raises the possibility of subsequent enrichment of the first planets in the Universe with water, in direct analogy to Earth in the Solar system.
title Planetesimals Formed in H$_2$O-Rich Disks at Cosmic Dawn
topic Astrophysics of Galaxies
url https://arxiv.org/abs/2501.08375