SPONTANEOUS SYMMETRY-BREAKING OF RAPIDLY ROTATING STARS IN GENERAL-RELATIVITY

We investigate the effects of general relativity upon the nonaxisymmet ric ''bar'' mode secular instability of rapidly rotating stars, i.e., the relativistic and compressible analog of the transition from Maclau rin spheroids to Jacobi ellipsoids. Our method consists of perturbing a stationary axisymmetric configuration, constructed by a two-dimensio nal general relativistic numerical code, and taking into account only the dominant terms in the nonaxisymmetric part of the three-dimensiona l relativistic equations. For a polytropic equation of state, we have determined, as a function of the degree of relativity, the critical ad iabatic index gamma(crit) above which rapidly rotating stars can break their axial symmetry. A by-product of the present study is the confir mation of the Newtonian value gamma(crit) = 2.238 obtained by James. W e have also considered neutron star models constructed upon 12 nuclear matter equations of state taken from the literature. We found that fi ve equations of state from this sample allow the symmetry breaking for sufficiently high rotation velocities. For the others, the Keplerian velocity (mass shedding from the equator) is reached before the axisym metry is broken. Rotating neutron stars that break their axial symmetr y can be an important source of gravitational waves for the LIGO/VIRGO interferometric detectors.