Bound on quantum fluctuations in gravitational waves from LIGO-Virgo

We derive some of the central equations governing quantum fluctuations in gravitational waves, making use of general relativity as a sensible effective quantum theory at large distances. We begin with a review of classical gravitational waves in general relativity, including the energy in each mode....

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Bibliographic Details
Published in:Journal of cosmology and astroparticle physics 2023-03, Vol.2023 (3), p.9
Main Authors: Hertzberg, Mark P., Litterer, Jacob A.
Format: Article
Language:English
Subjects:
Fluctuations
gravitational wave detectors
Gravitational waves
gravitational waves / theory
Perturbation
Quantum fields in curved spacetimes
quantum gravity phenomenology
Quantum mechanics
Quantum theory
Relativity
Squeezed states (quantum theory)
Theory of relativity
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Summary:We derive some of the central equations governing quantum fluctuations in gravitational waves, making use of general relativity as a sensible effective quantum theory at large distances. We begin with a review of classical gravitational waves in general relativity, including the energy in each mode. We then form the quantum ground state and coherent state, before then obtaining an explicit class of squeezed states. Since existing gravitational wave detections arise from merging black holes, and since the quantum nature of black holes remains puzzling, one can be open-minded to the possibility that the wave is in an interesting quantum mechanical state, such as a highly squeezed state. We compute the time and space two-point correlation functions for the quantized metric perturbations. We then constrain its amplitude with LIGO-Virgo observations. Using existing LIGO-Virgo data, we place a bound on the (exponential) squeezing parameter of the quantum gravitational wave state of  ζ < 41.
ISSN:1475-7516
1475-7516
DOI:10.1088/1475-7516/2023/03/009