Can asteroid-mass PBHDM be compatible with catalyzed phase transition interpretation of PTA?
Abstract
Primordial black holes (PBHs) can catalyze first-order phase transitions (FOPTs) in their vicinity, potentially modifying the gravitational wave (GW) signals from PTs. In this study, we present the first comprehensive analysis of this catalytic effect during supercooled PTs within the high PBH number density regime. Applying the analytical model with envelope approximation, we derive the general expressions of GW spectrum in the presence of PBHs. We find that at relatively small PBH number densities, the GW signals are amplified due to the large-size bubbles. While higher PBH number densities suppress GW signals, since the accelerated PT progresses too rapidly. We further extend our findings to the bulk flow model and to scalar-induced GWs (SIGWs) generated during PTs. By conducting data fitting with the NANOGrav 15-year dataset, we find that the PBH catalytic effect significantly alters the estimation of PT parameters. Notably, our analysis of the bubble collision GWs reveals that, the asteroid-mass PBHs ($10^{-16} - 10^{-12} M_\odot$) as the whole dark matter is incompatible with the PT interpretation of pulsar timing array signals. However, incorporating SIGWs can reduce this incompatibility for PBHs in the mass range $10^{-14} - 10^{-12} M_\odot$.