Abstract:
We consider the problem of the dynamics of a Gaussian wave packet in
a one-dimensional harmonic ocsillator interacting with a bath. This
problem arises in many chemical and biochemical applications related
to the dynamics of chemical reactions. We take the bath–oscillator
interaction into account in the framework of the Redfield theory. We
obtain closed expressions for Redfield-tensor elements, which allows
finding the explicit time dependence of the average vibrational
energy. We show that the energy loss rate is
temperature-independent, is the same for all wave packets, and
depends only on the spectral function of the bath. We determine
the degree of coherence of the vibrational motion as the trace of
the density-matrix projection on a coherently moving wave packet. We find
an explicit expression for the initial coherence loss rate, which
depends on the wave packet width and is directly proportional to
the intensity of the interaction with the bath. The minimum coherence
loss rate is observed for a "coherent" Gaussian wave packet whose
width corresponds to the oscillator frequency. We calculate
the limiting value of the degree of coherence for large times and show
that it is independent of the structural characteristics of the bath
and depends only on the parameters of the wave packet and on
the temperature. It is possible that residual coherence can be preserved
at low temperatures.
Keywords:quantum dissipation, Redfield theory, density matrix, harmonic oscillator, degree of coherence, wave packet.
Fulltext:
PDF file (433 kB)