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Gravitational-wave asteroseismology with fundamental modes from compact binary inspirals

Geraint Pratten, Patricia Schmidt, Tanja Hinderer

2020Nature Communications88 citationsDOIOpen Access PDF

Abstract

Gravitational waves (GWs) from binary neutron stars encode unique information about ultra-dense matter through characterisic signatures associated with a variety of phenomena including tidal effects during the inspiral. The main tidal signature depends predominantly on the equation of state (EoS)-related tidal deformability parameter Λ, but at late times is also characterised by the frequency of the star's fundamental oscillation mode (f-mode). In General Relativity and for nuclear matter, Λ and the f-modes are related by universal relations which may not hold for alternative theories of gravity or exotic matter. Independently measuring Λ and the f-mode frequency enables tests of gravity and the nature of compact binaries. Here we present directly measured constraints on the f-mode frequencies of the companions of GW170817. We also show that future GW detector networks will measure f-mode frequencies to within tens of Hz, enabling precision GW asteroseismology with binary inspiral signals alone.

Topics & Concepts

AsteroseismologyPhysicsGravitational waveNeutron starBinary numberGeneral relativityOscillation (cell signaling)GravitationSignature (topology)DetectorEquation of stateTheory of relativityTests of general relativityAstrophysicsMeasure (data warehouse)StarsClassical mechanicsVariety (cybernetics)NeutronGravitational-wave observatorySpectral signatureTidal forceBinary starTheoretical physicsComputational physicsLIGOBlack hole (networking)Fundamental frequencyPulsars and Gravitational Waves ResearchGamma-ray bursts and supernovaeScientific Research and Discoveries
Gravitational-wave asteroseismology with fundamental modes from compact binary inspirals | Litcius