Abundance Effects from Protoplanetary Disk Outflows

TL;DR

This paper demonstrates that star formation outflows naturally cause observed abundance differences in stars and primitive materials, aligning with empirical data without requiring complex mechanisms.

Contribution

It shows that protoplanetary disk outflows inherently produce the observed abundance variations, providing a unified explanation based on star formation processes.

Findings

Outflows cause differential abundance effects consistent with observations.

Trends and magnitudes match observed differences in stars and chondrites.

Effects are significant enough to influence entire stellar convection zones.

Abstract

Systematic abundance differences that depend on the condensation temperatures of elements have been observed, in particular for stars similar to the Sun; solar twins and solar analogs. Similar differences have also recently been shown to exist between solar abundances and abundances of refractory elements in primitive chondrites. Numerous mechanisms have been proposed to account for these effects, including also differences observed in binary systems. Rather than relying on specific mechanisms, this paper aims to show that the observed effects are a natural and unavoidable outcome of the star formation process itself, in which the associated outflows (winds and jets) carry away material, with efficiency varying with condensation temperature. By using analysis based on modeling results and scaling laws, the trends and magnitudes of the effects are investigated, in three contexts: 1) with respect to differences between the Sun and solar twins, 2) with respect to differences between the Sun and CI-chondrites, and 3) with respect to differences between members of binaries. It is shown that protoplanetary disk outflows indeed are expected to have differential abundance effects, with trends and magnitudes consistent with observed abundance effects. The qualitative as well as semi-quantitative character of the effects are reproduced, in all three contexts. The results demonstrate that the observed systematic differences are likely results of the disk outflows associated with the accretion process. In contrast to mechanisms relying on the tiny mass of planets leaving an observable signature, outflows carry away masses similar to the entire mass of the star, thus much more easily resulting in differential effects with the magnitudes observed, without for example having to assume that the abundance differences are limited to the convection zones of the stars.