Equation of State Effects on Gravitational Waves from Rapidly Rotating Core Collapse

arXiv:1701.02752

Sherwood Richers (California Institute of Technology)
Christian Ott (California Institute of Technology)
Ernazar Abdikamalov (Nazarbayev University)
Evan O'Connor (North Carolina State University)
Chris Sullivan (Michigan State University)

Abstract

Gravitational waves (GWs) generated by the collapse, bounce, and early post-bounce phases of core-collapse supernovae vary depending on the details of a yet poorly constrained nuclear equation of state (EOS). To examine the effects different EOS have on the GWs we run 1764 two-dimensional core-collapse simulations that cover a parameter space of 98 different rotation profiles and 18 different EOS. We show that the effect of the EOS on post-bounce oscillations is parameterized entirely by the dynamical time of the protoneutron star at all rotation rates. We also show that all simulations follow a universal curve in peak frequency vs maximum rotation rate, and suggest that this relationship is caused by inertial effects at high rotation rates. We also run an additional 60 2D simulations with detailed electron capture rates during collapse, and find that GW bounce amplitudes are shifted by 25% and oscillation frequencies are modified by ∼ 100 Hz. We find that it is unlikely that observations of GWs from up to several milliseconds after bounce in a core-collapse supernova can elucidate the nature of the nuclear EOS, and that a consistent and detailed collapse-phase deleptonization treatment is required for robust signal predictions.

 

Rotation deforms the PNS and causes axisymmetric oscillations
The color map shows entropy. Blue regions belong to the inner core. The density contours show densities of 10^{13.5,13.75,14.0,14.25} from outer to inner. The vectors represent only the poloidal velocity (i.e. the rotational velocity is ignored) and are colored for visibility. At low rotation rates (left) the flow in the inner core is largely quadrupolar. At high rotation rates (right) rotation significantly deforms the inner core and couples to quadrupolar oscillations to higher-order modes.

 

 

Waveforms and spectra from core collapse simulations using 18 different equations of state
The time-domain waveforms (left panel) and Fourier transforms scaled by f (right panel) of signals from all 18 EOS for a moderately rotating core collapse. t_b is the bounce time, t_be is the end of the bounce signal, and \Delta h_+ is the amplitude of the bounce signal. The frequency of the post-bounce oscillations can be seen at the peak of each spectrum.

 

Universal relationship for the frequency of post-bounce oscillations
The GW frequency from all EOS and all rotation profiles follow this simple relationship. The kink and rising frequencies with rotation are likely caused by inertial (i.e. Coriolis and/or centrifugal) effects on the oscillations.

Provided Data and Scripts

We provide gravitational waveforms, Ye(rho) profiles, and reduced data from our simulations hosted by zenodo.org at the following URL: https://zenodo.org/record/201145. The data are citable with 10.5281/zenodo.201145. They are licensed under the Creative Commons Attribution 4.0 license. When using the data, please also cite our paper.

The scripts used for data analysis are provided here.