Stability of the Ground State of a Harmonic Oscillator in a Monochromatic Wave

Abstract

Classical and quantum dynamics of a harmonic oscillator in a monochromatic wave is studied in the exact resonance and near resonance cases. This model describes, in particular, a dynamics of a cold ion trapped in a linear ion trap and interacting with two lasers fields with close frequencies. Analytically and numerically a stability of the ``classical ground state'' (CGS) -- the vicinity of the point (x=0, p=0) -- is analyzed. In the quantum case, the method for studying a stability of the quantum ground state (QGS) is suggested, based on the quasienergy representation. The dynamics depends on four parameters: the detuning from the resonance, δ=-/ω, where and ω are, respectively, the wave and the oscillator's frequencies; the positive integer (resonance) number, ; the dimensionless Planck constant, h, and the dimensionless wave amplitude, ε. For δ=0, the CGS and the QGS are unstable for resonance numbers =1, 2. For small ε, the QGS becomes more stable with increasing δ and decreasing h. When ε increases, the influence of chaos on the stability of the QGS is analyzed for different parameters of the model, , δ and h.

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