Litcius/Paper detail

Transition from inspiral to plunge: A complete near-extremal trajectory and associated waveform

Ollie Burke, J. R. Gair, Joan Simón

2020Physical review. D/Physical review. D.35 citationsDOIOpen Access PDF

Abstract

We extend the Ori and Thorne (OT) procedure to compute the transition from an adiabatic inspiral into a geodesic plunge for any spin, with emphasis on near-extremal ones. Our analysis revisits the validity of the approximations made in OT. In particular, we discuss possible effects coming from eccentricity and nongeodesic past-history of the orbital evolution. We find three different scaling regimes according to whether the mass ratio is much smaller, of the same order or much larger than the near extremal parameter describing how fast the primary black hole rotates. Eccentricity and nongeodesic past-history corrections are always subleading, indicating that the quasicircular approximation applies throughout the transition regime. However, we show that the OT assumption that the energy and angular momentum evolve linearly with proper time must be modified in the near-extremal regime. Using our transition equations, we describe an algorithm to compute the full worldline in proper time for an extreme mass ratio inspiral (EMRI) and the resultant gravitational waveform in the high spin limit.

Topics & Concepts

PhysicsGeodesicEccentricity (behavior)ScalingAngular momentumSpin (aerodynamics)GravitationAdiabatic processWaveformClassical mechanicsBlack hole (networking)Theoretical physicsGeometryQuantum mechanicsMathematicsVoltageComputer networkLawRouting (electronic design automation)Computer scienceThermodynamicsLink-state routing protocolPolitical scienceRouting protocolPulsars and Gravitational Waves ResearchAstrophysical Phenomena and ObservationsBlack Holes and Theoretical Physics
Transition from inspiral to plunge: A complete near-extremal trajectory and associated waveform | Litcius