English

Resonance Photon Generation in a Vibrating Cavity

Quantum Physics 2016-09-08 v1 High Energy Physics - Theory

Abstract

The problem of photon creation from vacuum due to the nonstationary Casimir effect in an ideal one-dimensional Fabry--Perot cavity with vibrating walls is solved in the resonance case, when the frequency of vibrations is close to the frequency of some unperturbed electromagnetic mode: ωw=p(πc/L0)(1+δ)\omega_w=p(\pi c/L_0)(1+\delta), δ1|\delta|\ll 1, (p=1,2,...). An explicit analytical expression for the total energy in all the modes shows an exponential growth if δ|\delta| is less than the dimensionless amplitude of vibrations ϵ1\epsilon\ll 1, the increment being proportional to pϵ2δ2p\sqrt{\epsilon^2-\delta^2}. The rate of photon generation from vacuum in the (j+ps)th mode goes asymptotically to a constant value cp2sin2(πj/p)ϵ2δ2/[πL0(j+ps)]cp^2\sin^2(\pi j/p)\sqrt{\epsilon^2-\delta^2}/[\pi L_0 (j+ps)], the numbers of photons in the modes with indices p,2p,3p,... being the integrals of motion. The total number of photons in all the modes is proportional to p3(ϵ2δ2)t2p^3(\epsilon^2-\delta^2) t^2 in the short-time and in the long-time limits. In the case of strong detuning δ>ϵ|\delta|>\epsilon the total energy and the total number of photons generated from vacuum oscillate with the amplitudes decreasing as (ϵ/δ)2(\epsilon/\delta)^2 for ϵδ\epsilon\ll|\delta|. The special cases of p=1 and p=2 are studied in detail.

Cite

@article{arxiv.quant-ph/9810077,
  title  = {Resonance Photon Generation in a Vibrating Cavity},
  author = {V. V. Dodonov},
  journal= {arXiv preprint arXiv:quant-ph/9810077},
  year   = {2016}
}

Comments

23 pages, Latex2e with iopart.cls, no figures, to appear in J. Phys. A