Using the evolution operator method, we derive the exact propagator of the generalized parametric oscillator in its more general form. This result is exploited to obtain the exact wavefunction of a damped and driven, inverted harmonic oscillator of the Caldirola-Kanai type, taking a Gaussian wavepacket as the initial state. We discuss the tunnelling process of such a system. The probability density and the persistence probability are evaluated. The expression for the sojourn time is derived for a small external force, and is the sum of two terms, whose explicit forms are obtained in the case of an extended wavepacket. The first term is an increasing function of the dissipation parameter gamma, whereas the second one is strictly due to the presence of the driving force.
Baskoutas, S., Jannussis, A., Mignani, R. (1993). QUANTUM TUNNELING OF A DAMPED AND DRIVEN, INVERTED HARMONIC-OSCILLATOR. JOURNAL OF PHYSICS. A, MATHEMATICAL AND GENERAL, 26(23), 7137-7147 [10.1088/0305-4470/26/23/048].
QUANTUM TUNNELING OF A DAMPED AND DRIVEN, INVERTED HARMONIC-OSCILLATOR
MIGNANI, ROBERTO
1993-01-01
Abstract
Using the evolution operator method, we derive the exact propagator of the generalized parametric oscillator in its more general form. This result is exploited to obtain the exact wavefunction of a damped and driven, inverted harmonic oscillator of the Caldirola-Kanai type, taking a Gaussian wavepacket as the initial state. We discuss the tunnelling process of such a system. The probability density and the persistence probability are evaluated. The expression for the sojourn time is derived for a small external force, and is the sum of two terms, whose explicit forms are obtained in the case of an extended wavepacket. The first term is an increasing function of the dissipation parameter gamma, whereas the second one is strictly due to the presence of the driving force.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.