Testing general relativity with TianQin: the prospect of using the inspiral signals of black hole binaries

Abstract

In this paper, we carry out a systematic study of the prospect of testing general relativity with the inspiral signals of black hole binaries that could be detected with TianQin. The study is based on the parameterized post-Einsteinian (ppE) waveform, so that many modified gravity theories can be covered simultaneously. We consider black hole binaries with total masses ranging from 10 M107 M and ppE corrections at post-Newtonian (PN) orders ranging from -4PN to 2PN. Compared to the current ground-based detectors, TianQin can improve the constraints on the ppE phase parameter β by orders of magnitude. For example, the improvement at the -4PN and 2PN orders can be about 13 and 3 orders of magnitude (compared to the results from GW150914), respectively. Compared to future ground-based detectors, such as ET, TianQin is expected to be superior below the -1PN order, and for corrections above the -0.5PN order, TianQin is still competitive near the large mass end of the low mass range [10 M, \,103 M]\,. Compared to the future space-based detector LISA, TianQin can be competitive in the lower mass end as the PN order is increased. For example, at the -4PN order, LISA is always superior for sources more massive than about 30 M\,, while at the 2PN order, TianQin becomes competitive for sources less massive than about 104 M. We also study the scientific potentials of detector networks involving TianQin, LISA and ET, and discuss the constraints on specific theories such as the dynamic Chern-Simons theory and the Einstein-dilaton Gauss-Bonnet theory.