Stellar-gas kinematic misalignments in EAGLE: lifetimes and longevity of misaligned galaxies

Maximilian K. Baker, Timothy A. Davis, Freeke van de Voort, Ilaria Ruffa

Published 2024-12-04Version 1

The dominant processes by which galaxies replenish their cold gas reservoirs remain disputed, especially in massive galaxies. Stellar-gas kinematic misalignments offer an opportunity to study these replenishment processes. However, observed distributions of these misalignments conflict with current models of gas replenishment in early-type galaxies (ETGs), with longer relaxation timescales suggested as a possible solution. We use the EAGLE simulation to explore the relaxation of unstable misaligned gas in galaxies with masses of $M_{*}\geqslant \mathrm{10^{9.5}}$ M$_\odot$ between $0<z<1$. We extract misalignments from formation to relaxation providing a sample of $\sim3200$ relaxations. We find relaxation timescales tend to be short-duration, with median lifetimes of $\sim0.5$ Gyr, though with a notable population of unstable misalignments lasting $\gtrsim1$ Gyr. Relaxation time distributions show a log-linear relationship, with $\approx20\%$ of unstable misalignments persisting for $\gtrsim3$ torquing times. Long-lived unstable misalignments are predominantly found in galaxies with higher stellar masses, lower star-forming gas fractions, higher ongoing gas inflow, and which reside in the centres of dense environments. Mergers only cause $\sim17\%$ of unstable misalignments in EAGLE. We conclude that, at least in EAGLE, unstable kinematic misalignments are not predominantly driven by gas-rich minor mergers. Additionally, processes that significantly extend relaxation times are not dominant in the galaxy population. Instead, we see a diverse formation pathway for misalignments such as through hot halo cooling.