Classification of extremely metal-poor stars: absent region in A(C)-[Fe/H] plane and the role of dust cooling

TL;DR

This paper investigates the formation conditions of extremely metal-poor stars, emphasizing the role of dust cooling and proposing a universal criterion based on observed abundance limits and grain properties.

Contribution

It introduces a new universal condition for EMP star formation based on dust cooling, linking grain properties to observed abundance thresholds and redefining classification boundaries.

Findings

Dust cooling is essential for low-mass star formation in EMP stars.

A universal abundance condition for EMP star formation is established.

A new boundary for classifying C-enhanced and C-normal EMP stars is proposed.

Abstract

Extremely metal-poor (EMP) stars are the living fossils with records of chemical enrichment history at the early epoch of galaxy formation. By the recent large observation campaigns, statistical samples of EMP stars have been obtained. This motivates us to reconsider their classification and formation conditions. From the observed lower-limits of carbon and iron abundances of Acr(C) ~ 6 and [Fe/H]cr ~ -5 for C-enhanced EMP (CE-EMP) and C-normal EMP (CN-EMP) stars, we confirm that gas cooling by dust thermal emission is indispensable for the fragmentation of their parent clouds to form such low-mass, i.e., long-lived stars, and that the dominant grain species are carbon and silicate, respectively. We constrain the grain radius r_i^{cool} of a species i and condensation efficiency f_{ij} of a key element j as r_C^{cool}/f_{C, C} = 10 um and r_Sil^{cool}/f_{Sil, Mg} = 0.1 um to reproduce Acr(C) and [Fe/H]cr, which give a universal condition 10^{[C/H]-2.30} + 10^[Fe/H] > 10^{-5.07} for the formation of every EMP star. Instead of the conventional boundary [C/Fe] = 0.7 between CE- and CN-EMP stars, this condition suggests a physically meaningful boundary [C/Fe]_{b} = 2.30 above and below which carbon and silicate grains are dominant coolants, respectively.