Octupolar test of general relativity

TL;DR

This paper uses gravitational wave data from GW190412 and GW190814 to test the octupolar modes predicted by general relativity, confirming their consistency and measuring the octupolar tail contribution for the first time.

Contribution

It provides the first measurement of the octupolar tail contribution and constrains deviations in the radiative mass octupole modes using LIGO/Virgo data.

Findings

Constraints on PN phase deformation parameters consistent with GR

First measurement of octupolar tail contribution in gravitational waves

Future observations will tighten these constraints.

Abstract

Compact binaries with unequal masses and whose orbits are not aligned with the observer's line of sight are excellent probes of gravitational radiation beyond the quadrupole approximation. Among the compact binaries observed so far, strong evidence of octupolar modes is seen in GW190412 and GW190814, two binary black holes observed during the first half of the third observing run of LIGO/Virgo observatories. These two events, therefore, provide a unique opportunity to test the consistency of the octupolar modes with the predictions of general relativity (GR). In the post-Newtonian (PN) approximation to GR, the gravitational-wave phasing has known dependencies on different radiative multipole moments, including the mass octupole. This permits the use of publicly released posteriors of the PN phase deformation parameters for placing constraints on the deformations to the different PN components of the radiative mass octupole denoted by $\delta \mu_{3n}$. Combining the posteriors on $\delta \mu_{3n}$ from these two events, we deduce a joint bound (at 90% credibility) on the first three PN order terms in the radiative octupoles to be $\delta \mu_{30}=-0.07^{+0.11}_{-0.12}$, $\delta \mu_{32}=0.48^{+0.93}_{-1.15}$, and $\delta \mu_{33}=-0.32^{+1.67}_{-0.62}$, consistent with GR predictions. Among these, the measurement of $\delta \mu_{33}$ for the first time confirms the well-known octupolar tail contribution, a novel nonlinear effect due to the scattering of the octupolar radiation by the background spacetime, is consistent with the predictions of GR. Detection of similar systems in the future observing runs should further tighten these constraints.