Low-T/|W| instabilities in differentially rotating proto-neutron stars with magnetic fields

Abstract

Recent hydrodynamical simulations have shown that differentially rotating neutron stars formed in core-collapse supernovae may develop global non-axisymmetric instabilities even when T/|W| (the ratio of the rotational kinetic energy T to the gravitational potential energy |W|) is relatively small (less than 0.1). Such low-T/|W| instability can give rise to efficient gravitational wave emission from the proto-neutron star. We investigate how this instability is affected by magnetic fields using a cylindrical stellar model. Wave absorption at the corotation resonance plays an important role in facilitating the hydrodynamic low-T/|W| instability. In the presence of a toroidal magnetic field, the corotation resonance is split into two magnetic resonances where wave absorptions take place. We show that the toroidal magnetic field suppresses the low-T/|W| instability when the total magnetic energy W B is of order 0.2\,T or larger, corresponding to toroidal fields of a few × 1016 G or stronger. Although poloidal magnetic fields do not influence the instability directly, they can affect the instability by generating toroidal fields through linear winding of the initial poloidal field and magneto-rotational instability. We show that an initial poloidal field with strength as small as 1014 G may suppress the low-T/|W| instability.