13,636 research outputs found
Ground state and edge excitations of quantum Hall liquid at filling factor 2/3
We present a numerical study of fractional quantum Hall liquid at Landau
level filling factor in a microscopic model including long-range
Coulomb interaction and edge confining potential, based on the disc geometry.
We find the ground state is accurately described by the particle-hole conjugate
of a Laughlin state. We also find there are two counter-propagating
edge modes, and the velocity of the forward-propagating mode is larger than the
backward-propagating mode. The velocities have opposite responses to the change
of the background confinement potential. On the other hand changing the
two-body Coulomb potential has qualitatively the same effect on the velocities;
for example we find increasing layer thickness (which softens of the Coulomb
interaction) reduces both the forward mode and the backward mode velocities.Comment: 12 pages, 13 figure
The Universal Edge Physics in Fractional Quantum Hall Liquids
The chiral Luttinger liquid theory for fractional quantum Hall edge transport
predicts universal power-law behavior in the current-voltage (-)
characteristics for electrons tunneling into the edge. However, it has not been
unambiguously observed in experiments in two-dimensional electron gases based
on GaAs/GaAlAs heterostructures or quantum wells. One plausible cause is the
fractional quantum Hall edge reconstruction, which introduces non-chiral edge
modes. The coupling between counterpropagating edge modes can modify the
exponent of the - characteristics. By comparing the fractional
quantum Hall states in modulation-doped semiconductor devices and in graphene
devices, we show that the graphene-based systems have an experimental
accessible parameter region to avoid the edge reconstruction, which is suitable
for the exploration of the universal edge tunneling exponent predicted by the
chiral Luttinger liquid theory.Comment: 7 pages, 6 figure
A unified control strategy for inductor-based active battery equalisation schemes
© 2018 by the authors. Licensee MDPI, Basel, Switzerland. Series battery equalisation can improve battery charge and discharge reliability and extend battery life. Inductor-based battery equalisation schemes have the advantages of simple topologies and control strategies. According to the energy transfer pathway, inductor-based battery equalisation schemes can be divided into cell-to-cell and cell-to-pack equalisation schemes. The control strategies of the cell-to-cell schemes are simple; the inductor can only transfer energy between the neighbouring cells, so the equalisation speed is low. The cell-to-pack schemes are able to accomplish energy transfer between the cells and pack by charging and discharging the inductors. The equalisation speed is high, but the control strategies may be complex. In this paper, different equalisation topologies are reviewed, then a unified control strategy which is applicable to all of the inductor-based equalisation topologies is proposed. The equalisation speeds and efficiencies of these different schemes, including the newly-proposed unified control strategy, are analysed and compared. Based on the theoretical analysis, simulations, and experimental verifications, it is concluded that this unified control strategy can perform the battery equalisation process quickly and efficiently
Simultaneous Metal-Insulator and Antiferromagnetic Transitions in Orthorhombic Perovskite Iridate Sr0.94Ir0.78O2.68 Single Crystals
The orthorhombic perovskite SrIrO3 is a semimetal, an intriguing exception in
iridates where the strong spin-orbit interaction coupled with electron
correlations tends to impose a novel insulating state. We report results of our
investigation of bulk single-crystal Sr0.94Ir0.78O2.68 or Ir-deficient,
orthorhombic perovskite SrIrO3. It retains the same crystal structure as
stoichiometric SrIrO3 but exhibits a sharp, simultaneous antiferromagnetic
(AFM) and metal-insulator (MI) transition at 185 K. Above it, the basal-plane
resistivity features an extended regime of almost linear-temperature dependence
up to 800 K but the strong electronic anisotropy renders an insulating behavior
in the out-of-plane resistivity. The Hall resistivity undergoes an abrupt sign
change and grows below 40 K, which along with the Sommerfeld constant of 20
mJ/mole K2 suggests a multiband effect. All results including our
first-principles calculations underscore a delicacy of the metallic state in
SrIrO3 that is in close proximity to an AFM insulating state. The contrasting
ground states in isostructural Sr0.94Ir0.78O2.68 and SrIrO3 illustrate a
critical role of even slight lattice distortions in rebalancing the ground
state in the iridates. Finally, the observed simultaneous AFM and MI
transitions reveal a direct correlation between the magnetic transition and
formation of a charge gap in the iridate, which is conspicuously absent in
Sr2IrO4.Comment: 5 figure
A Flexible Black-Box Model for Conducted Emission Predictions with Different Switching Frequencies
Black-box modeling technique is an efficient approach to represent the electromagnetic interference behavior of power converters, whose presence may cause malfunctioning in adjacent electronic devices. Although developing a black-box model is simpler and less demanding than extracting an explicit circuit model, model effectiveness is limited to certain operating conditions, such as a fixed modulation strategy. In this work, a flexible black-box model is proposed, which can be effectively used for prediction also in case of different modulation conditions without requiring a new estimation of model parameters if modulation parameter (such as the switching frequency) changes. Flexibility is achieved by modeling time-domain noise waveforms using an analytical curve-fitting model or an autoregressive model, whose accuracy is compared in time and frequency domain. The proposed model is experimentally verified on a boost converter operated with different switching frequencies
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