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Quantum versus classical phase-locking transition in a driven-chirped oscillator

Quantum Physics 2015-05-27 v2 Superconductivity Atomic Physics Plasma Physics

Abstract

Classical and quantum-mechanical phase locking transition in a nonlinear oscillator driven by a chirped frequency perturbation is discussed. Different limits are analyzed in terms of the dimensionless parameters % P_{1}=\epsilon /\sqrt{2m\hbar \omega_{0}\alpha} and P2=(3β)/(4mα)P_{2}=(3\hbar \beta)/(4m\sqrt{\alpha}) (ϵ,\epsilon, α,\alpha, β\beta and ω0\omega_{0} being the driving amplitude, the frequency chirp rate, the nonlinearity parameter and the linear frequency of the oscillator). It is shown that for P2P1+1P_{2}\ll P_{1}+1, the passage through the linear resonance for P1P_{1} above a threshold yields classical autoresonance (AR) in the system, even when starting in a quantum ground state. In contrast, for % P_{2}\gg P_{1}+1, the transition involves quantum-mechanical energy ladder climbing (LC). The threshold for the phase-locking transition and its width in P1P_{1} in both AR and LC limits are calculated. The theoretical results are tested by solving the Schrodinger equation in the energy basis and illustrated via the Wigner function in phase space.

Keywords

Cite

@article{arxiv.1104.3296,
  title  = {Quantum versus classical phase-locking transition in a driven-chirped oscillator},
  author = {I. Barth and L. Friedland and O. Gat and A. G. Shagalov},
  journal= {arXiv preprint arXiv:1104.3296},
  year   = {2015}
}
R2 v1 2026-06-21T17:55:10.549Z