The Kiloparsec-Scale Kinematics of High-Redshift Star-Forming Galaxies

TL;DR

This study investigates the internal motions of star-forming galaxies at redshift 2-3 using high-resolution spectroscopy, revealing diverse kinematic structures that challenge simple galaxy classification schemes.

Contribution

It provides detailed kinematic analysis of high-redshift galaxies with adaptive optics, highlighting the complexity beyond traditional disk or merger models.

Findings

Most galaxies show irregular or featureless velocity fields.

Velocity dispersions are high, suggesting non-rotational support.

Some galaxies exhibit signs of major mergers despite rotational features.

Abstract

We present the results of a spectroscopic survey of the kinematic structure of star-forming galaxies at redshift z ~ 2 - 3 using Keck/OSIRIS integral field spectroscopy. Our sample is comprised of 12 galaxies between redshifts z ~ 2.0 and 2.5 and one galaxy at z ~ 3.3 which are well detected in either HAlpha or [O III] emission. These observations were obtained in conjunction with the Keck laser guide star adaptive optics system, with a typical angular resolution after spatial smoothing ~ 0.15" (approximately 1 kpc at the redshift of the target sample). At most five of these 13 galaxies have spatially resolved velocity gradients consistent with rotation while the remaining galaxies have relatively featureless or irregular velocity fields. All of our galaxies show local velocity dispersions ~ 60 - 100 km/s, suggesting that (particularly for those galaxies with featureless velocity fields) rotation about a preferred axis may not be the dominant mechanism of physical support. While some galaxies show evidence for major mergers such evidence is unrelated to the kinematics of individual components (one of our strongest merger candidates also exhibits unambiguous rotational structure), refuting a simple bimodal disk/merger classification scheme. We discuss these data in light of complementary surveys and extant UV-IR spectroscopy and photometry, concluding that the dynamical importance of cold gas may be the primary factor governing the observed kinematics of z ~ 2 galaxies. We conclude by speculating on the importance of mechanisms for accreting low angular-momentum gas and the early formation of quasi-spheroidal systems in the young universe.(abridged)