Minding the gap: GW190521 as a straddling binary

Abstract

Models for black hole (BH) formation from stellar evolution robustly predict the existence of a pair-instability supernova (PISN) mass gap in the range 50 to 120 solar masses. This theoretical prediction is supported by the binary black holes (BBHs) of LIGO/Virgo's first two observing runs, whose component masses are well-fit by a power law with a maximum mass cutoff at mmax=40.8+11.8-4.4\,M. Meanwhile, the BBH event GW190521 has a reported primary mass of m1=85+21-14\,M, firmly above the inferred mmax, and secondary mass m2=66+17-18\,M. Rather than concluding that both components of GW190521 belong to a new population of mass-gap BHs, we explore the conservative scenario in which GW190521's secondary mass belongs to the previously-observed population of BHs. We replace the default priors on m1 and m2, which assume that BH detector-frame masses are uniformly distributed, with this population-informed prior on m2, finding m2<48\,M at 90\% credibility. Moreover, because the total mass of the system is better constrained than the individual masses, the population prior on m2 automatically increases the inferred m1 to sit above the gap (39\% for m1 > 120\,M, or 25\% probability for m1>130\,M). As long as the prior odds for a double-mass-gap BBH are smaller than 1:15, it is more likely that GW190521 straddles the pair-instability gap. We argue that GW190521 may be the first example of a straddling binary black hole, composed of a conventional stellar mass BH and a BH from the ``far side' of the PISN mass gap.