Prague Relativistic Astrophysics

Ondrej Pejcha

Abstract: Many massive stars explode as core-collapse supernovae. Supernova simulations show that the shock wave accompanying formation of the proto-neutron star evolves into a quasi-static accretion shock and it proves difficult to revive its outward propagation. The stalled accretion shock turns into explosion when the neutrino luminosity from the collapsed core exceeds a critical value L_crit (the "neutrino mechanism"). I will show the connection between the steady-state isothermal accretion flows with bounding shocks and the neutrino mechanism: there is a maximum, critical sound speed above which it is impossible to maintain accretion with a standoff shock. I will derive the "antesonic" condition, which characterizes the transition to explosion over a broad range in accretion rate, PNS properties and microphysics. Additionally, I will characterize the effects of accretion luminosity and collective neutrino oscillations on L_crit. The physics of the explosion mechanism and the progenitor structure are imprinted in the observed distribution of neutron star masses. I will use Bayesian analysis to model the double neutron star mass distribution to infer the properties of the progenitor binary population, fallback during the explosion, and constrain the mass coordinate where the explosion develops.

The Physics of the Neutrino Mechanism of Core-collapse Supernovae
http://adsabs.harvard.edu/abs/2012ApJ...746..106P

Effect of collective neutrino oscillations on the neutrino mechanism
of core-collapse supernovae
http://adsabs.harvard.edu/abs/2012MNRAS.425.1083P

The observed neutron star mass distribution as a probe of the
supernova explosion mechanism
http://adsabs.harvard.edu/abs/2012MNRAS.424.1570P

The progenitor dependence of the neutrino mechanism of core-collapse supernovae
Pejcha & Thompson, in preparation