Constraining the mass of the graviton using coalescing black-hole binaries

Abstract

We study how well the mass of the graviton can be constrained from gravitational-wave (GW) observations of coalescing binary black holes. Whereas the previous investigations employed post-Newtonian (PN) templates describing only the inspiral part of the signal, the recent progress in analytical and numerical relativity has provided analytical waveform templates coherently describing the inspiral-merger-ringdown (IMR) signals. We show that a search for binary black holes employing IMR templates will be able to constrain the mass of the graviton much more accurately (about an order of magnitude) than a search employing PN templates. The best expected bound from GW observatories (lambdag > 7.8 x 1013 km from Adv. LIGO, lambdag > 7.1 x 1014 km from Einstein Telescope, and lambdag > 5.9 x 1017 km from LISA) are several orders-of-magnitude better than the best available model-independent bound (lambdag > 2.8 x 1012 km, from Solar system tests). Most importantly, GW observations will provide the first constraints from the highly dynamical, strong-field regime of gravity.