Unblocking of stellar electron capture for neutron-rich N=50 nuclei at finite temperature

Abstract

We have calculated electron capture rates for neutron-rich N=50 nuclei (78Ni, 82Ge, 86Kr, 88Sr) within the Thermal QRPA approach at temperatures T=0, corresponding to capture on the ground-state, and at T=10 GK (0.86 MeV), which is a typical temperature at which the N=50 nuclei are abundant during a supernova collapse. In agreement with recent experiments, we find no Gamow-Teller (GT+) strength at low excitation energies, E<7 MeV, caused by Pauli blocking induced by the N=50 shell gap. At the astrophysically relevant temperatures this Pauli blocking of the GT+ strength is overcome by thermal excitations across the Z=40 proton and N=50 neutron shell gaps, leading to a sizable GT contribution to the electron capture. At the high densities, at which the N=50 nuclei are important for stellar electron capture, forbidden transitions contribute noticeably to the capture rate. Our results indicate that the neutron-rich N=50 nuclei do not serve as an obstacle of electron capture during the supernova collapse.