The interstellar medium and feedback in the progenitors of the compact passive galaxies at z~2

TL;DR

This study investigates the interstellar medium and feedback mechanisms in compact, star-forming galaxies at z~3, proposing they are likely progenitors of quenched, passive galaxies at z~2 due to their energetic feedback and rapid evolution.

Contribution

It provides observational evidence linking the properties of compact Lyman-break galaxies at z~3 to their potential as progenitors of passive galaxies at z~2, highlighting differences in feedback and metallicity.

Findings

Candidates have faster ISM gas velocities and broader velocity spreads.

Candidates show stronger metal-rich Wolf-Rayet star signatures.

Candidates exhibit properties suggesting they quench sooner than non-candidates.

Abstract

Quenched galaxies at z>2 are nearly all very compact relative to z~0, suggesting a physical connection between high stellar density and efficient, rapid cessation of star-formation. We present restframe UV spectra of Lyman-break galaxies (LBGs) at z~3 selected to be candidate progenitors of quenched galaxies at z~2 based on their compact restframe optical sizes and high surface density of star-formation. We compare their UV properties to those of more extended LBGs of similar mass and star formation rate (non-candidates). We find that candidate progenitors have faster ISM gas velocities and higher equivalent widths of interstellar absorption lines, implying larger velocity spread among absorbing clouds. Candidates deviate from the relationship between equivalent widths of Lyman-alpha and interstellar absorption lines in that their Lyman-alpha emission remains strong despite high interstellar absorption, possibly indicating that the neutral HI fraction is patchy such that Lyman-alpha photons can escape. We detect stronger CIV P-Cygni features (emission and absorption) and HeII emission in candidates, indicative of larger populations of metal rich Wolf-Rayet stars compared to non-candidates. The faster bulk motions, broader spread of gas velocity, and Lyman-alpha properties of candidates are consistent with their ISM being subject to more energetic feedback than non-candidates. Together with their larger metallicity (implying more evolved star-formation activity) this leads us to propose, if speculatively, that they are likely to quench sooner than non-candidates, supporting the validity of selection criteria used to identify them as progenitors of z~2 passive galaxies. We propose that massive, compact galaxies undergo more rapid growth of stellar mass content, perhaps because the gas accretion mechanisms are different, and quench sooner than normally-sized LBGs at these early epochs.