# Initial Conditions of Planet Formation: Time Constraints from Small Bodies and the Lifetime of Reservoirs in the Solar Protoplanetary Disk

**Authors:** Maria Schönbächler, Audrey Bouvier, Noriko T. Kita, Thomas S. Kruijer

PMC · DOI: 10.1007/s11214-025-01216-z · Space Science Reviews · 2025-10-17

## TL;DR

This paper reviews how and when planets began to form in our solar system, using clues from meteorites and isotope data to track early events like dust accumulation and differentiation of small bodies.

## Contribution

The paper integrates multiple isotope chronometers and nucleosynthetic data to constrain the timing and spatial distribution of planet formation processes in the early solar system.

## Key findings

- CAI formation likely occurred over ∼0.3 million years with a homogeneous 26Al distribution in the disk.
- Silicate differentiation on small bodies began within the first few million years of the solar system.
- NC and CC reservoirs in the protoplanetary disk formed within 1 million years and remained isolated for several million years.

## Abstract

This review explores the timescales of the initial phase of planet formation, from nebular dust (CAIs and chondrules) to planetesimal accretion and differentiation, using evidence from meteorite research. Aluminium-Mg systematics of CAIs indicate either an extended period of CAI formation (∼0.3 Ma) or an initial 26Al heterogeneity, with evidence supporting a homogeneous 26Al abundance in the protoplanetary disk. Thermal and aqueous alteration on the parent body can disturb the U-Pb and Al-Mg chronometers in chondrules. Focusing on relatively robust isochron data from plagioclase of pristine (types ≤3.05) chondrites indicates a shift in chondrule formation locations, moving from the inner to the outer disk over time. Ages of basaltic achondrites show that silicate differentiation on small bodies was well underway within the first few million years (Ma) of our solar system. Their age record, however, reveals inconsistencies between different chronometers, partly caused by (i) secondary disturbances due to thermal metamorphism, aqueous alteration, or impacts, (ii) the presence of xenolithic minerals, and (iii) potentially variable initial 26Al abundances due to disturbances at the mineral scale. Nucleosynthetic isotope data indicate that parent bodies of iron and stony meteorites formed in two distinct regions within the protoplanetary disk: the inner, non-carbonaceous (NC) and the outer, carbonaceous (CC) region. Based on Hf-W chronometry it has been demonstrated that NC and CC parent bodies of magmatic iron meteorites segregated their cores within ∼1–3 Ma after CAI formation, implying that parent body accretion occurred within <1 Ma in both reservoirs. Combining accretion ages with nucleosynthetic data further reveals that, at first order, NC and CC reservoirs in the solar protoplanetary disk were established within 1 Ma and existed over several Ma with limited exchange between them. In the CR chondrite accretion region of the disk, planetary bodies formed over at least 3 Ma, while in most other regions, formation spanned at least 1 Ma, with minimal changes in nucleosynthetic isotope compositions. Aerodynamical size sorting of dust likely introduced or amplified some of these variations.

## Full-text entities

- **Chemicals:** CR (MESH:D002857), Al (MESH:D000535), Pb (MESH:D007854), silicate (MESH:D017640), Mg (MESH:D008274), 26Al (MESH:C000615298), stony (-), iron (MESH:D007501)

## Full text

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## Figures

14 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12534327/full.md

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Source: https://tomesphere.com/paper/PMC12534327