How Low Can Q Go?

Abstract

Gravitational instability plays a substantial role in the evolution of galaxies. Various schemes to include it in galaxy evolution models exist, generally assuming that the Toomre Q parameter is self-regulated to Qcrit, the critical Q dividing stable from unstable conditions in a linear stability analysis. This assumption is in tension with observational estimates of Q that find values far below any plausible value of Qcrit. While the observations are subject to some uncertainty, this tension can more easily be relieved on the theoretical side by relaxing the common assumption that Q Qcrit. Based on observations of both z 2 disks and local face-on galaxies, we estimate the effect of gravitational instability necessary to balance out every other physical process that affects Q. In particular we find that the disk's response to low Q values can be described by simple functions that depend only on Q. These response functions allow galaxies to maintain Q values below Qcrit in equilibrium over a wide range of parameters. Extremely low values of Q are predicted when the gas surface density is greater than 103 M pc-2, the rotation curve provides minimal shear, the orbital time becomes long, and/or when the gas is much more unstable than the stellar component. We suggest that these response functions should be used in place of the Q Qcrit ansatz.