📝 SummarXiv

Abstract

When compact objects -- neutron stars and black holes -- are formed in a supernova explosion, they may receive a high velocity at formation, which may reach or even exceed $\approx{1000}$~km~s$^{-1}$ for neutron stars and hundreds of km~s$^{-1}$ for black holes. The origin of the kick is intimately related to supernova physics. A better understanding of kick properties from astronomical observations will shed light on the unsolved problems of these explosions, such as the exact conditions leading to exotic electron capture and ultra-stripped supernovae. Compact object kicks are profoundly important in several areas of astrophysics. First, being a result of supernova explosions, the kick velocity distribution must be explained in the framework of the supernova mechanism. Second, the kick magnitudes and directions influence many aspects of the evolution of binary systems, including the rate of compact object coalescences observable through gravitational waves. Third, the evolution of isolated neutron stars depends on their spatial velocities relative to the surrounding medium. Finally, knowledge of the kick velocity distribution is significant in predicting future observational results and their interpretation. For example, it is expected that the Roman space telescope will discover many microlensing events related to neutron stars and black holes; accurate estimates require precise kinematic properties of these compact objects.