Stability of the Accretion Flows with Stalled Shocks in Core-Collapse Supernovae

Abstract

Bearing in mind the application to the theory of core-collapse supernovae, we performed a global linear analysis on the stability of spherically symmetric accretion flows through a standing shock wave onto a proto neutron star. As unperturbed flows, we adopted the spherically symmetric steady solutions to the Euler equations obtained with realistic equation of state and formulae for neutrino reaction rates taken into account. Then we solved the equations for linear perturbations numerically, and obtained the eigen frequencies and eigen functions. We found (1) the flows are stable for all modes if the neutrino luminosity is lower than 1× 1052 ergs/s for M=1.0M/ s. (2) For larger luminosities, the non-radial instabilities are induced, probably via the advection-acoustic cycles. Interestingly, the modes with =2 and 3 become unstable at first for relatively low neutrino luminosities, e.g. 2-3× 1052 ergs/s for the same accretion rate, whereas the =1 mode is the most unstable for higher luminosities, 3-7× 1052 ergs/s. These are all oscillatory modes. (3) For still larger luminosities, 7× 1052 ergs/s for M=1.0M/ s, non-oscillatory modes, both radial and non-radial, become unstable. These non-radial modes were identified as convection. We confirmed the results obtained by numerical simulations that the instabilities induced by the advection-acoustic cycles are more important than the convection for lower neutrino luminosities.

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