4,330 research outputs found
Hopping conductivity in the quantum Hall effect -- revival of universal scaling
We have measured the temperature dependence of the conductivity
of a two-dimensional electron system deep into the localized regime of the
quantum Hall plateau transition. Using variable-range hopping theory we are
able to extract directly the localization length from this experiment. We
use our results to study the scaling behavior of as a function of the
filling factor distance to the critical point of the transition.
We find for all samples a power-law behavior
with a universal scaling exponent as proposed theoretically
Conductance fluctuations at the quantum Hall plateau transition
We analyze the conductance fluctuations observed in the quantum Hall regime
for a bulk two-dimensional electron system in a Corbino geometry. We find that
characteristics like the power spectral density and the temperature dependence
agree well with simple expectations for universal conductance fluctuations in
metals, while the observed amplitude is reduced. In addition, the dephasing
length , which governs the temperature dependence of
the fluctuations, is surprisingly different from the scaling length
governing the width of the quantum Hall plateau
transition
High Frequency Conductivity in the Quantum Hall Regime
We have measured the complex conductivity of a two-dimensional
electron system in the quantum Hall regime up to frequencies of 6 GHz at
electron temperatures below 100 mK. Using both its imaginary and real part we
show that can be scaled to a single function for different
frequencies and for all investigated transitions between plateaus in the
quantum Hall effect. Additionally, the conductivity in the variable-range
hopping regime is used for a direct evaluation of the localization length
. Even for large filing factor distances from the critical
point we find with a scaling exponent
Real-time path integral approach to nonequilibrium many-body quantum system
A real-time path integral Monte Carlo approach is developed to study the
dynamics in a many-body quantum system until reaching a nonequilibrium
stationary state. The approach is based on augmenting an exact reduced equation
for the evolution of the system in the interaction picture which is amenable to
an efficient path integral (worldline) Monte Carlo approach. Results obtained
for a model of inelastic tunneling spectroscopy reveal the applicability of the
approach to a wide range of physically important regimes, including high
(classical) and low (quantum) temperatures, and weak (perturbative) and strong
electron-phonon couplings.Comment: 5 pages, 2 figure
Tuning the onset voltage of resonant tunneling through InAs quantum dots by growth parameters
We investigated the size dependence of the ground state energy in
self-assembled InAs quantum dots embedded in resonant tunneling diodes.
Individual current steps observed in the current-voltage characteristics are
attributed to resonant single-electron tunneling via the ground state of
individual InAs quantum dots. The onset voltage of the first step observed is
shown to decrease systematically from 200 mV to 0 with increasing InAs
coverage. We relate this to a coverage-dependent size of InAs dots grown on
AlAs. The results are confirmed by atomic force micrographs and
photoluminescence experiments on reference samples.Comment: 3 pages, 3 figure
Spin Blockade in Capacitively Coupled Quantum Dots
We present transport measurements on a lateral double dot produced by
combining local anodic oxidation and electron beam lithography. We investigate
the tunability of our device and demonstrate, that we can switch between
capacitive and tunnel coupling. In the regime of capacitive coupling we observe
the phenomenon of spin blockade in a magnetic field and analyze the influence
of capacitive interdot coupling on this effect.Comment: 4 pages, 3 figure
Giant anisotropy of Zeeman splitting of quantum confined acceptors in Si/Ge
Shallow acceptor levels in Si/Ge/Si quantum well heterostructures are
characterized by resonant tunneling spectroscopy in the presence of high
magnetic fields. In a perpendicular magnetic field we observe a linear Zeeman
splitting of the acceptor levels. In an in-plane field, on the other hand, the
Zeeman splitting is strongly suppressed. This anisotropic Zeeman splitting is
shown to be a consequence of the huge light hole-heavy hole splitting caused by
a large biaxial strain and a strong quantum confinement in the Ge quantum well.Comment: 5 figures, 4 page
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