Esdaile, James and Glazebrook, Karl and Labbé, Ivo and Taylor, Edward and Schreiber, Corentin and Nanayakkara, Themiya and Kacprzak, Glenn G. and Oesch, Pascal A. and Tran, Kim-Vy H. and Papovich, Casey and Spitler, Lee and Straatman, Caroline M. S. (2021) Consistent Dynamical and Stellar Masses with Potential Light IMF in Massive Quiescent Galaxies at 3 < z < 4 Using Velocity Dispersions Measurements with MOSFIRE. The Astrophysical Journal, 908 (2). L35. ISSN 2041-8213
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Abstract
We present the velocity dispersion measurements of four massive ∼1011M⊙ quiescent galaxies at 3.2 < z < 3.7 based on deep H and K-band spectra using the Keck/MOSFIRE near-infrared spectrograph. We find high velocity dispersions of order σe ∼250 km s−1 based on strong Balmer absorption lines, and we combine these with size measurements based on HST/WFC3 F160W imaging to infer dynamical masses. The velocity dispersions are broadly consistent with the high stellar masses and small sizes. Together with evidence for quiescent stellar populations, the spectra confirm the existence of a population of massive galaxies that formed rapidly and quenched in the early universe z > 4. Investigating the evolution at constant velocity dispersion between z ∼3.5 and z ∼2, we find a large increase in effective radius 0.35 ± 0.12 dex and in dynamical-to-stellar mass ratio $\langle \mathrm{log}({M}_{\mathrm{dyn}}/M* )\rangle $ of 0.33 ± 0.08 dex, with low expected contribution from dark matter. The dynamical masses for our z ∼3.5 sample are consistent with the stellar masses for a Chabrier initial mass function (IMF), with the ratio $\langle \mathrm{log}({M}_{\mathrm{dyn}}/{M}_{\mathrm{Ch}}^{* })\rangle =-0.13\pm 0.10$ dex suggesting an IMF lighter than Salpeter may be common for massive quiescent galaxies at z > 3. This is surprising in light of the Salpeter or heavier IMFs found for high velocity dispersion galaxies at z ∼2 and cores of present-day ellipticals, which these galaxies are thought to evolve into. Future imaging and spectroscopic observations with resolved kinematics using the upcoming James Webb Space Telescope could rule out potential systematics from rotation and confirm these results.
Item Type: | Article |
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Subjects: | Institute Archives > Physics and Astronomy |
Depositing User: | Managing Editor |
Date Deposited: | 16 May 2023 04:53 |
Last Modified: | 15 Jan 2024 03:48 |
URI: | http://eprint.subtopublish.com/id/eprint/2263 |