Effective gravitational wave stress-energy tensor in alternative theories of gravity

Author(s)

Stein, Leo Chaim; Yunes, Nicolas

Abstract

The inspiral of binary systems in vacuum is controlled by the stress-energy of gravitational radiation and any other propagating degrees of freedom. For gravitational waves, the dominant contribution is characterized by an effective stress-energy tensor at future null infinity. We employ perturbation theory and the short-wavelength approximation to compute this stress-energy tensor in a wide class of alternative theories. We find that this tensor is generally a modification of that first computed by Isaacson, where the corrections can dominate over the general relativistic term. In a wide class of theories, however, these corrections identically vanish at asymptotically flat, future, null infinity, reducing the stress-energy tensor to Isaacson’s. We exemplify this phenomenon by first considering dynamical Chern-Simons modified gravity, which corrects the action via a scalar field and the contraction of the Riemann tensor and its dual. We then consider a wide class of theories with dynamical scalar fields coupled to higher-order curvature invariants and show that the gravitational wave stress-energy tensor still reduces to Isaacson’s. The calculations presented in this paper are crucial to perform systematic tests of such modified gravity theories through the orbital decay of binary pulsars or through gravitational wave observations.

Date issued

2011-03

URI

http://hdl.handle.net/1721.1/67445

Department

Massachusetts Institute of Technology. Department of Physics
MIT Kavli Institute for Astrophysics and Space Research

Journal

Physical Review D

Publisher

American Physical Society

Citation

Stein, Leo, and Nicolás Yunes. “Effective gravitational wave stress-energy tensor in alternative theories of gravity.” Physical Review D 83.6 064038 (2011) [19 pages]. © 2011 American Physical Society.

Version: Final published version

ISSN

1550-7998

1550-2368