Mechanically generating entangled photons from the vacuum: A microwave circuit-acoustic resonator analog of the oscillatory Unruh effect

“…Independent of their possible connection to black holes, the unusual features predicted to occur in radiation fields produced by moving mirror models are interesting in themselves, especially as they confront the tension between quantum purity and apparent thermality. The availability of arrays containing very large numbers of mirrors whose orientation can be programmed flexibly might offer another road (in addition to [4][5][6][7]) to realizing such models.…”

Section: Summary and Discussionmentioning

confidence: 99%

“…In the context of quantum field theory, moving mirror models consider the effect of imposing boundary conditions on a moving surface [1][2][3]. In recent years the subject has attracted renewed interest, prompted in part by significant experimental developments [4][5][6][7] (and see below) and in part by the continuing debate about the ultimate fate of an evaporating black hole, including the "firewall" proposal of Almheiri et al [8], and the "fuzzball" proposal of Mathur [9]. Moving mirror models are thought to provide useful idealizations [10,11] of black hole evaporation [12], though it remains unclear how far the analogy can be taken.…”

Section: Introductionmentioning

confidence: 99%

Moving mirror model for quasithermal radiation fields

Good¹,

Linder²,

Wilczek³

2020

Phys. Rev. D

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We analyze the flow of energy and entropy emitted by a class of moving mirror trajectories which provide models for important aspects of the radiation fields produced by black hole evaporation. The mirror radiation fields provide natural, concrete examples of processes that follow thermal distributions for long periods, accompanied by transients which are brief and carry little net energy, yet ultimately represent pure quantum states. A burst of negative energy flux is a generic feature of these fields, but it need not be prominent.

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“…The DCE can, in principle, also be directly implemented in cavity-optomechanical systems [30][31][32][33][34][35][36][37][38][39]. But it requires a mechanical frequency ω m to be very close to the cavity frequency ω c , or even a single-photon optomechanical coupling g 0 to reach the ultrastrongcoupling regime g 0 /ω m 0.1 [36,39].…”

Section: Introductionmentioning

confidence: 99%

Emission of photon pairs by mechanical stimulation of the squeezed vacuum

et al. 2019

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To observe the dynamical Casimir effect (DCE) induced by a moving mirror is a long-standing challenge because the mirror velocity needs to approach the speed of light. Here, we present an experimentally feasible method for observing this mechanical DCE in an optomechanical system. It employs a detuned, parametric driving to squeeze a cavity mode, so that the mechanical mode, with a typical resonance frequency, can parametrically and resonantly couple to the squeezed cavity mode, thus leading to a resonantly amplified DCE in the squeezed frame. The DCE process can be interpreted as mechanically-induced two-photon hyper-Raman scattering in the laboratory frame. Specifically, a photon pair of the parametric driving absorbs a single phonon and then is scattered into an anti-Stokes sideband. We also find that the squeezing, which additionally induces and amplifies the DCE, can be extremely small. Our method requires neither an ultra-high mechanical-oscillation frequency (i.e., a mirror moving at nearly the speed of light) nor an ultrastrong single-photon optomechanical coupling and, thus, could be implemented in a wide range of physical systems.

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Mechanically generating entangled photons from the vacuum: A microwave circuit-acoustic resonator analog of the oscillatory Unruh effect

Cited by 30 publications

References 33 publications

Fifty Years of the Dynamical Casimir Effect

Fifty Years of the Dynamical Casimir Effect

Moving mirror model for quasithermal radiation fields

Emission of photon pairs by mechanical stimulation of the squeezed vacuum

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