dc.description.abstract |
The idea of wave packet, that clarified many conceptual difficulties, has more recently
been revisited to address interferometric and dynamical issues. Present work focuses on
the spatio-temporal dynamics of the quantum wave packets in the Fermi-Ulam
Accelerator Model. The specific system considered here is a one-dimensional box under
periodic oscillations at one boundary. Such a seemingly simple system can be mapped to
non-trivial problems like BEC trapped in an oscillating cavity or dynamics of atomic
wave packet in different potential in presence or absence of gravitational field. The
system is shown to display rich dynamical features including transitions from regular to
stochastic and further to chaotic domain in classical phase space. We have obtained the
approximated eigen-value solutions of the problem through time dependent
Schrodinger’s equation under rescaling transformations that effectively replace moving
boundary with a static one. Consequently the running time becomes a nonlinear function
of the continuously changing boundary. Based on these solutions, revivals or the
resurrection of the original wave packet, in the driven and un-driven Fermi-Ulam model
are presented. Such revivals correspond to the constructive interference whereas the wave
packet’s collapse owes to destructive interference. Furthermore, interplay of constructive
and destructive interferences also readily mimics the fractional revivals. It is further
demonstrated that initial position and momentum play a highly crucial role in the
emergent revival and fractional revival patterns. It is shown that the symmetries exhibited
by such structures in un-driven systems are usually lost under driven conditions and the
revival/fractional revival times can only be predicted through a transcendental equation
whose solution mainly depends on the strength of the external driving force. In present
thesis we have proposed a comprehensive mathematical technique to calculate these
hitherto unpredictable times. In addition, a graphical method is also suggested to observe
these asymmetric revival/fractional revival times. This apparent asymmetry, do display
an overall periodicity over a comparatively long span covering many times of revivals. It
is found that whenever the ratio between the period of wall oscillation and quantum
revival time `α/β' is a rational number then the revivals time shows a periodicity after β
viinumber of revival times over α wall oscillation. Standard tools of autocorrelation and
quantum carpets, a consequence of quantum interference, have been employed for visual
manifestation of these revivals. These carpets amply demonstrate the explicit asymmetric
shifting of revival times for the driven case. These micro changes exhibited in quantum
carpet morphologies consequently yield amended phase velocities associated with the
canals and ridges in the driven framework.
Furthermore, to grasp the quantum phase space dynamics in its entirety, we have also
utilized the more sophisticated techniques of the Wigner function and information
entropy. It is demonstrated mathematically that revivals not apparent via autocorrelation
become prominent in the Wigner phase space description along with the appearance of
smooth mini wave packets in the fractional revivals. These interference patterns emerge
due to the state vector formed through the linear combination of Gaussians with different
positions and momenta having pure Gaussian as well as oscillatory terms. Moreover, the
information entropy, like the Wigner function also predicts the revivals when and where
they happen. Thus a rich pattern of fractional revivals, including some altogether new
ones, are observed through this tool in both driven and un-driven situations. Finally we
have elucidated various scenarios including cold atoms in magneto-optical traps where
such a system can be experimentally realized along with the suggestions for future work
in this specific domain. |
en_US |