Litcius/Paper detail

Fully Relativistic Treatment of Extreme Mass-Ratio Inspirals in Collisionless Environments

Rodrigo Vicente, Theophanes K. Karydas, Gianfranco Bertone

2025Physical Review Letters13 citationsDOIOpen Access PDF

Abstract

Future mHz gravitational wave interferometers will precisely probe massive black hole environments, such as accretion disks, cold dark matter overdensities, and clouds of ultralight bosons, as long as we can accurately model the dephasing they induce on the waveform of extreme mass-ratio inspirals (EMRIs). Most existing models rely on extrapolations from Newtonian results to model the interaction of the small black hole in an EMRI system with the environment surrounding the massive black hole. Here, we present a fully relativistic formalism to model such interaction with collisionless environments, focusing on the case of cold dark matter overdensities, like "spikes" and "mounds." We implement our new formalism in the fastemriwaveforms framework, and show that the resulting waveforms are significantly different from those based on a Newtonian treatment of environmental effects. Our results indicate that a fully relativistic treatment is essential to capture the environmental dephasing of gravitational wave signals from EMRIs accurately.

Topics & Concepts

PhysicsGravitational waveDephasingFormalism (music)Relativistic quantum chemistryBlack hole (networking)WaveformGravitationAstronomical interferometerNewtonian fluidDark matterCold dark matterAstrophysicsObservableClassical mechanicsCosmologyBinary black holeArms raceRelativistic particleQuantum electrodynamicsAstronomyGravitational collapsePrimordial black holeRotating black holePulsars and Gravitational Waves ResearchAstrophysical Phenomena and ObservationsCosmology and Gravitation Theories