Effective action approach to higher-order relativistic tidal interactions in binary systems and their effective one body description
Abstract
The gravitational-wave signal from inspiralling neutron-star-neutron-star (or black-hole-neutron-star) binaries will be influenced by tidal coupling in the system. An important science goal in the gravitational-wave detection of these systems is to obtain information about the equation of state of neutron star matter via the measurement of the tidal polarizability parameters of neutron stars. To extract this piece of information will require accurate analytical descriptions both of the motion and the radiation of tidally interacting binaries. We improve the analytical description of the late inspiral dynamics by computing the next-to-next-to-leading-order relativistic correction to the tidal interaction energy. Our calculation is based on an effective-action approach to tidal interactions and on its transcription within the effective-one-body formalism. We find that second-order relativistic effects (quadratic in the relativistic gravitational potential u=G(m1+m2)/(c2r)) significantly increase the effective tidal polarizability of neutron stars by a distance-dependent amplification factor of the form 1+α1u+α2u2+⋯ where, say, for an equal-mass binary, α1=5/4=1.25 (as previously known) and α2=85/14≃6.07143 (as determined here for the first time). We argue that higher-order relativistic effects will lead to further amplification, and we suggest a Padé-type way of resumming them. We recommend testing our results by comparing resolution-extrapolated numerical simulations of inspiralling binary neutron stars to their effective one-body description.
- Publication:
-
Physical Review D
- Pub Date:
- June 2012
- DOI:
- 10.1103/PhysRevD.85.124034
- arXiv:
- arXiv:1202.3565
- Bibcode:
- 2012PhRvD..85l4034B
- Keywords:
-
- 04.30.-w;
- 04.25.Nx;
- Gravitational waves: theory;
- Post-Newtonian approximation;
- perturbation theory;
- related approximations;
- General Relativity and Quantum Cosmology
- E-Print:
- 29 pages, Physical Review D, to appear