Evanescent Gravitational Waves

Sebastian Golat; Eugene Lim; Francisco Rodriguez Fortuno

doi:10.1103/PhysRevD.101.084046

Evanescent Gravitational Waves

Sebastian Golat, Eugene Lim, Francisco Rodriguez Fortuno

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Abstract

We describe the properties of evanescent gravitational waves (EGWs)—wave solutions of Einstein equations which decay exponentially in some direction while propagating in another. Evanescent waves are well known in acoustics and optics and have recently received much attention due to their extraordinary properties such as their transverse spin and spin-momentum locking. We show that EGWs possess similarly remarkable properties, carrying transverse spin angular momenta and driving freely falling test masses along in elliptical trajectories. Hence, test masses on a plane transverse to the direction of propagation exhibit correlated vector and scalarlike deformation—correlations which can be used to distinguish it from modified gravity. We demonstrate that EGWs are present and dominant in the vicinity of subwavelength sources such as orbiting binaries.

Original language	English
Article number	084046
Journal	Physical Review D
Volume	101
Issue number	8
DOIs	https://doi.org/10.1103/PhysRevD.101.084046
Publication status	Published - 22 Apr 2020

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title = "Evanescent Gravitational Waves",

abstract = "We describe the properties of evanescent gravitational waves (EGWs)—wave solutions of Einstein equations which decay exponentially in some direction while propagating in another. Evanescent waves are well known in acoustics and optics and have recently received much attention due to their extraordinary properties such as their transverse spin and spin-momentum locking. We show that EGWs possess similarly remarkable properties, carrying transverse spin angular momenta and driving freely falling test masses along in elliptical trajectories. Hence, test masses on a plane transverse to the direction of propagation exhibit correlated vector and scalarlike deformation—correlations which can be used to distinguish it from modified gravity. We demonstrate that EGWs are present and dominant in the vicinity of subwavelength sources such as orbiting binaries.",

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AU - Rodriguez Fortuno, Francisco

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AB - We describe the properties of evanescent gravitational waves (EGWs)—wave solutions of Einstein equations which decay exponentially in some direction while propagating in another. Evanescent waves are well known in acoustics and optics and have recently received much attention due to their extraordinary properties such as their transverse spin and spin-momentum locking. We show that EGWs possess similarly remarkable properties, carrying transverse spin angular momenta and driving freely falling test masses along in elliptical trajectories. Hence, test masses on a plane transverse to the direction of propagation exhibit correlated vector and scalarlike deformation—correlations which can be used to distinguish it from modified gravity. We demonstrate that EGWs are present and dominant in the vicinity of subwavelength sources such as orbiting binaries.

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JO - Physical Review D

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Evanescent Gravitational Waves

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