Gravitational Waves from the Collapse and Bounce of a Stellar Core in Tensor-Scalar Gravity

Tensor-scalar theory of gravity allows the generation of gravitational waves from astrophysical sources, like supernovae, even in the spherical case. That motivated us to study the collapse of a degenerate stellar core, within tensor-scalar gravity, leading to the formation of a neutron star through a bounce and the formation of a shock. This paper discusses the effects of the scalar field on the evolution of the system, as well as the appearance of strong nonperturbative effects of this scalar field (the so-called spontaneous scalarization). As a main result, we describe the resulting gravitational monopolar radiation (form and amplitude) and discuss the possibility of its detection by the gravitational detectors currently under construction, taking into account the existing constraints on the scalar field. From the numerical point of view, it is worthy to point out that we have developed a combined code that uses pseudo-spectral methods for the evolution of the scalar field and High-Resolution Shock-Capturing schemes, as well as for the evolution of the hydrodynamical system. Although this code has been used to integrate the field equations of that theory of gravity, in the spherically symmetric case, a by-product of the present work is to gain experience for an ulterior extension to multidimensional problems in Numerical Relativity of such numerical strategy.

[1]  M. Jacob,et al.  About Les Houches , 2002 .

[2]  J. Novak Neutron star transition to strong scalar field state in tensor scalar gravity , 1998, gr-qc/9806022.

[3]  T. Damour,et al.  Gravitational wave versus binary - pulsar tests of strong field gravity , 1998, gr-qc/9803031.

[4]  J. Novak Spherical neutron star collapse toward a black hole in a tensor-scalar theory of gravity , 1997, gr-qc/9707041.

[5]  F. Fidecaro,et al.  GRAVITATIONAL WAVES: Sources and Detectors: PROCEEDINGS OF THE INTERNATIONAL CONFERENCE , 1997 .

[6]  K. Nakao,et al.  Scalar gravitational wave from Oppenheimer-Snyder collapse in scalar - tensor theories of gravity , 1996, gr-qc/9611031.

[7]  X. Newhall,et al.  Relativity parameters determined from lunar laser ranging. , 1996, Physical review. D, Particles and fields.

[8]  T. Damour,et al.  Tensor-scalar gravity and binary-pulsar experiments. , 1996, Physical review. D, Particles and fields.

[9]  J. Martí,et al.  A new spherically symmetric general relativistic hydrodynamical code , 1995, astro-ph/9509121.

[10]  Shapiro,et al.  Collapse to black holes in Brans-Dicke theory. I. Horizon boundary conditions for dynamical spacetimes. , 1994, Physical review. D, Particles and fields.

[11]  Nakamura,et al.  Scalar-type gravitational wave emission from gravitational collapse in Brans-Dicke theory: Detectability by a laser interferometer. , 1994, Physical review. D, Particles and fields.

[12]  A. Polyakov,et al.  The string dilation and a least coupling principle , 1994, hep-th/9401069.

[13]  T. Damour,et al.  Nonperturbative strong-field effects in tensor-scalar theories of gravitation. , 1993, Physical review letters.

[14]  A 1D exact treatment of shock waves within spectral methods in plane geometry , 1991 .

[15]  T. Damour,et al.  Tensor-multi-scalar theories of gravitation , 1991 .

[16]  J. García-Bellido,et al.  Extended inflation in scalar-tensor theories of gravity , 1990 .

[17]  Saul A. Teukolsky,et al.  Black Holes, White Dwarfs, and Neutron Stars , 1983 .

[18]  Van Riper,et al.  The Hydrodynamics of Stellar Collapse , 1978 .

[19]  W. Arnett Neutrino trapping during gravitational collapse of stars. , 1977 .

[20]  S. Hawking Black holes in the Brans-Dicke , 1972 .

[21]  J. Oppenheimer,et al.  On Continued Gravitational Contraction , 1939 .