92,090 research outputs found
Hole tunneling times in GaAs/AlAs double-barrier structures
We have calculated hole tunneling times in GaAs/AlAs double-barrier structures taking quantum well band-mixing effects into account. Our results indicate that for sufficiently high hole temperatures and concentrations, band-mixing effects reduce average hole tunneling times from the pure heavy hole value to values comparable to electron tunneling times in the same structure. For very low hole temperatures and concentrations, band mixing is less important and average hole tunneling times should approach the pure heavy hole value. These results provide an explanation for previously reported experimental results in which electrons and holes were found to be characterized by very similar tunneling times
Superoscillations and tunneling times
It is proposed that superoscillations play an important role in the
interferences which give rise to superluminal effects. To exemplify that, we
consider a toy model which allows for a wave packet to travel, in zero time and
negligible distortion a distance arbitrarily larger than the width of the wave
packet. The peak is shown to result from a superoscillatory superposition at
the tail. Similar reasoning applies to the dwell time.Comment: 12 page
Delay time computation for relativistic tunneling particles
We study the tunneling zone solutions of a one-dimensional electrostatic
potential for the relativistic (Dirac to Klein-Gordon) wave equation when the
incoming wave packet exhibits the possibility of being almost totally
transmitted through the barrier. The transmission probabilities, the phase
times and the dwell times for the proposed relativistic dynamics are obtained
and the conditions for the occurrence of accelerated tunneling transmission are
all quantified. We show that, in some limiting cases, the analytical
difficulties that arise when the stationary phase method is employed for
obtaining phase (traversal) tunneling times are all overcome. Lessons
concerning the phenomenology of the relativistic tunneling suggest revealing
insights into condensed-matter experiments using electrostatic barriers for
which the accelerated tunneling effect can be observed.Comment: 17 pages, 4 figure
A probability distribution for quantum tunneling times
We propose a general expression for the probability distribution of
real-valued tunneling times of a localized particle, as measured by the
Salecker-Wigner-Peres quantum clock. This general expression is used to obtain
the distribution of times for the scattering of a particle through a static
rectangular barrier and for the tunneling decay of an initially bound state
after the sudden deformation of the potential, the latter case being relevant
to understand tunneling times in recent attosecond experiments involving strong
field ionization.Comment: 14 pages, 8 Figure
Tunneling times with covariant measurements
We consider the time delay of massive, non-relativistic, one-dimensional
particles due to a tunneling potential. In this setting the well-known Hartman
effect asserts that often the sub-ensemble of particles going through the
tunnel seems to cross the tunnel region instantaneously. An obstacle to the
utilization of this effect for getting faster signals is the exponential
damping by the tunnel, so there seems to be a trade-off between speedup and
intensity. In this paper we prove that this trade-off is never in favor of
faster signals: the probability for a signal to reach its destination before
some deadline is always reduced by the tunnel, for arbitrary incoming states,
arbitrary positive and compactly supported tunnel potentials, and arbitrary
detectors. More specifically, we show this for several different ways to define
``the same incoming state'' and ''the same detector'' when comparing the
settings with and without tunnel potential. The arrival time measurements are
expressed in the time-covariant approach, but we also allow the detection to be
a localization measurement at a later time.Comment: 12 pages, 2 figure
Tunneling Time in Ultrafast Science is Real and Probabilistic
We compare the main competing theories of tunneling time against experimental
measurements using the attoclock in strong laser field ionization of helium
atoms. Refined attoclock measurements reveal a real and not instantaneous
tunneling delay time over a large intensity regime, using two different
experimental apparatus. Only two of the theoretical predictions are compatible
within our experimental error: the Larmor time, and the probability
distribution of tunneling times constructed using a Feynman Path Integral (FPI)
formulation. The latter better matches the observed qualitative change in
tunneling time over a wide intensity range, and predicts a broad tunneling time
distribution with a long tail. The implication of such a probability
distribution of tunneling times, as opposed to a distinct tunneling time,
challenges how valence electron dynamics are currently reconstructed in
attosecond science. It means that one must account for a significant
uncertainty as to when the hole dynamics begin to evolve.Comment: 11 pages, 4 figure
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