Litcius/Paper detail

Gravitational Collider Physics via Pulsar–Black Hole Binaries II: Fine and Hyperfine Structures Are Favored

Xi Tong, Yi Wang, Hui-Yu Zhu

2022The Astrophysical Journal20 citationsDOIOpen Access PDF

Abstract

Abstract A rotating black hole can be clouded by light bosons via superradiance and thus acquire an atom-like structure. If such a gravitational atom system is accompanied by a pulsar, the pulsar can trigger transitions between energy levels of the gravitational atom, and these transitions can be detected by pulsar timing. We show that in such pulsar–black hole systems, fine and hyperfine structure transitions are more likely to be probed than the Bohr transition. Also, the calculation of these fine and hyperfine structure transitions are under better analytic control. Thus, these fine and hyperfine structure transitions are more ideal probes in the search for gravitational collider signals in pulsar–black hole systems.

Topics & Concepts

PhysicsPulsarHyperfine structureBlack hole (networking)AstrophysicsSuperradianceBinary pulsarGravitational energyGravitational waveBosonMillisecond pulsarAstronomyParticle physicsQuantum mechanicsLaserComputer networkLink-state routing protocolComputer scienceRouting (electronic design automation)Routing protocolPulsars and Gravitational Waves ResearchRadio Astronomy Observations and TechnologyCosmology and Gravitation Theories
Gravitational Collider Physics via Pulsar–Black Hole Binaries II: Fine and Hyperfine Structures Are Favored | Litcius