Abstract
Abstract
The ratio of baryonic-to-dark matter in present-day galaxies constrains galaxy formation theories and can be determined empirically via the baryonic Tully–Fisher relation (BTFR), which compares a galaxy’s baryonic mass (M
bary) to its maximum rotation velocity (V
max). The BTFR is well determined at M
bary > 108
M
⊙, but poorly constrained at lower masses due to small samples and the challenges of measuring rotation velocities in this regime. For 25 galaxies with high-quality data and M
bary ≲ 108
M
⊙, we estimate M
bary from infrared and H i observations and V
max from the H i gas rotation. Many of the V
max values are lower limits because the velocities are still rising at the edge of the detected H i disks (R
max); consequently, most of our sample has lower velocities than expected from extrapolations of the BTFR at higher masses. To estimate V
max, we map each galaxy to a dark matter halo assuming density profiles with and without cores. In contrast to noncored profiles, we find the cored profile rotation curves are still rising at R
max values, similar to the data. When we compare the V
max values derived from the cored density profiles to our M
bary measurements, we find a turndown of the BTFR at low masses that is consistent with Λ cold dark matter predictions and implies baryon fractions of 1%–10% of the cosmic value. Although we are limited by the sample size and assumptions inherent in mapping measured rotational velocities to theoretical rotation curves, our results suggest that galaxy formation efficiency drops at masses below M
bary ∼ 108
M
⊙, corresponding to M
200 ∼ 1010
M
⊙.
Funder
Rutgers, The State University of New Jersey
Publisher
American Astronomical Society
Subject
Space and Planetary Science,Astronomy and Astrophysics
Cited by
8 articles.
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