Gravitational wave signals in an Unruh–DeWitt detector

Prokopec, Tomislav

doi:10.1088/1361-6382/acabf5

Class. Quantum Grav.

2023

DOI: 10.1088/1361-6382/acabf5

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Gravitational wave signals in an Unruh–DeWitt detector

Tomislav Prokopec¹

Abstract: We ﬁrstly generalize the massive scalar propagator for gravitational waves propagating on Minkowski space obtained recently in Ref. [1]. We then use this propagator to study the response of a freely falling Unruh-DeWitt detector to a gravitational wave backg round. We ﬁnd that a freely falling detector completely cancels the eﬀect of the deformation of the invariant distance induced by the gravitational waves, such that the only eﬀect comes from an increased average size of scalar ﬁeld vacuum ﬂuctuations, the … Show more

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2024

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Cited by 2 publications

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Atomic electron transitions of hydrogen-like atoms induced by gravitational waves

Chen,

Chiou

2024

Class. Quantum Grav.

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As a realistic model of a quantum system of matter, this paper investigates the gravitational-wave effects on a hydrogen-like atom using a first-principles approach. By formulating the tetrad formalism of linearized gravity, we naturally incorporate gravitational-wave effects through minimal coupling in the covariant Dirac equation. The atomic electron transition rates induced by the gravitational wave are calculated using first-order perturbation theory, revealing a distinctive selection rule along with Fermi's golden rule. This rule can be elegantly understood in terms of gravitons as massless spin-2 particles. Our results suggest the existence of gravitons and may lead to a novel approach to probing ultra-high-frequency gravitational waves (UHF-GWs).

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Atomic electron transitions of hydrogen-like atoms induced by gravitational waves

Chen,

Chiou

2024

Class. Quantum Grav.

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Detecting gravitational waves via coherence degradation induced by the Unruh effect

Barros,

Costa

2024

Eur. Phys. J. C

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We investigate the effects of a gravitational wave background on the coherence degradation induced by the Unruh effect of a uniformly accelerated single-qubit and quantum interferometric circuit. In both systems, we use the formalism of the evolution of the density matrix of the detector-field system, where after the interaction the field degrees of freedom are traced out to obtain the reduced density matrix of the detector. In this background, we calculate the quantum coherence and interferometric visibility in the long-wavelength regime and large interaction time. Our results indicate that the gravitational wave transfers energy to the internal states of the detector, causing, together with the Unruh effect, changes in them, amplifying the coherence degradation of the system. This amplification occurs when the polarization modes of the gravitational wave are in resonance and have modulated amplitudes. For the case of a short-wavelength, the detector does not respond to the gravitational wave because its oscillation is so fast that the detector does not have time to respond within the system timescale. Therefore, it is possible to detect the signature of gravitational waves in the coherence degradation induced by the Unruh effect within the regimes studied here.

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Gravitational wave signals in an Unruh–DeWitt detector

Cited by 2 publications

References 20 publications

Atomic electron transitions of hydrogen-like atoms induced by gravitational waves

Atomic electron transitions of hydrogen-like atoms induced by gravitational waves

Detecting gravitational waves via coherence degradation induced by the Unruh effect

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