Constraining phases of quark matter with studies ofr-mode damping in compact stars

Abstract

With the goal of constraining the phase of matter at high density, we study $r$-mode damping in the color-flavor-locked phase with kaon condensation (CFL-K0) and contrast it with the CFL phase. The mode frequencies in these phases are found to differ very slightly. While the bulk viscosity in either phase is only effective at damping the $r$-mode at temperatures $T\ensuremath{\gtrsim}{10}^{11}$ K, the shear viscosity in the CFL-K0 phase is the only effective damping agent all the way down to temperatures $T\ensuremath{\gtrsim}{10}^{8}$ K characteristic of cooling neutron stars. However, it cannot keep the star from becoming unstable to gravitational wave emission for rotation frequencies $\ensuremath{\nu}\ensuremath{\approx}56$--11 Hz at $T\ensuremath{\approx}{10}^{8}$--${10}^{9}$ K. Stars composed almost entirely of CFL or CFL-K0 matter are ruled out by observation of rapidly rotating neutron stars, indicating that dissipation at the quark-hadron interface or nuclear crust interface must play a key role in damping the instability.