http://arxiv.org/abs/2011.13942
The angular velocity with which galactic bars rotate is intimately linked to the amount of dark matter in the inner regions of their host galaxies. In particular, dark matter haloes act to slow down bars via torques exerted through dynamical friction. Observational studies of barred galaxies tend to find that bars rotate fast, while hydrodynamical cosmological simulations of galaxy formation and evolution in the $\Lambda$CDM framework have previously found that bars slow down excessively. This has led to a growing tension between fast bars and the $\Lambda$CDM cosmological paradigm. In this study we use a suite of state-of-the-art, high resolution, cosmological zoom-in simulations of galaxy formation and evolution to show that bars can, in fact, remain fast within the $\Lambda$CDM cosmological paradigm. In our simulations, bars form in galaxies that have higher stellar-to-dark matter ratios and are more baryon-dominated than in previous cosmological simulations; this suggests that in order for bars to remain fast, massive spiral galaxies must lie above the commonly used abundance matching relation. While this work may resolve the aforementioned tension between fast bars and $\Lambda$CDM, it accentuates the recently reported discrepancy between the dynamically inferred stellar-to-dark matter ratios of massive spirals and those inferred from abundance matching. Our results highlight the potential of using bar dynamics to constrain models of galaxy formation and evolution.
F. Fragkoudi, R. Grand, R. Pakmor, et. al.
Tue, 1 Dec 20
102/108
Comments: 27 pages, 10 figures; Resubmitted after first round of comments from the reviewers
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