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Adiabatic Waveforms from Extreme-Mass-Ratio Inspirals: An Analytical Approach

Soichiro Isoyama, Ryuichi Fujita, Alvin J. K. Chua, Hiroyuki Nakano, Adam Pound, Norichika Sago

2022Physical Review Letters76 citationsDOIOpen Access PDF

Abstract

Scientific analysis for the gravitational wave detector LISA will require theoretical waveforms from extreme-mass-ratio inspirals (EMRIs) that extensively cover all possible orbital and spin configurations around astrophysical Kerr black holes. However, on-the-fly calculations of these waveforms have not yet overcome the high dimensionality of the parameter space. To confront this challenge, we present a user-ready EMRI waveform model for generic (eccentric and inclined) orbits in Kerr spacetime, using an analytical self-force approach. Our model accurately covers all EMRIs with arbitrary inclination and black hole spin, up to modest eccentricity (≲0.3) and separation (≳2-10 M from the last stable orbit). In that regime, our waveforms are accurate at the leading "adiabatic" order, and they approximately capture transient self-force resonances that significantly impact the gravitational wave phase. The model fills an urgent need for extensive waveforms in ongoing data-analysis studies, and its individual components will continue to be useful in future science-adequate waveforms.

Topics & Concepts

Gravitational wavePhysicsWaveformMass ratioEccentricity (behavior)Adiabatic processOrbit (dynamics)Black hole (networking)GravitationClassical mechanicsAstrophysicsQuantum mechanicsAerospace engineeringComputer scienceRouting protocolPolitical scienceLink-state routing protocolEngineeringVoltageComputer networkLawRouting (electronic design automation)Pulsars and Gravitational Waves ResearchAstrophysical Phenomena and ObservationsGamma-ray bursts and supernovae
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