11,494 research outputs found
Quantum spin Hall effect induced by electric field in silicene
We investigate the transport properties in a zigzag silicene nanoribbon in
the presence of an external electric field. The staggered sublattice potential
and two kinds of Rashba spin-orbit couplings can be induced by the external
electric field due to the buckled structure of the silicene. A bulk gap is
opened by the staggered potential and gapless edge states appear in the gap by
tuning the two kinds of Rashba spin-orbit couplings properly. Furthermore, the
gapless edge states are spin-filtered and are insensitive to the non-magnetic
disorder. These results prove that the quantum spin Hall effect can be induced
by an external electric field in silicene, which may have certain practical
significance in applications for future spintronics device.Comment: 4 pages, 5 figure
Pure spin current in a two-dimensional topological insulator
We predict a mechanism to generate a pure spin current in a two-dimensional
topological insulator. As the magnetic impurities exist on one of edges of the
two-dimensional topological insulator, a gap is opened in the corresponding
gapless edge states but another pair of gapless edge states with opposite spin
are still protected by the time-reversal symmetry. So the conductance plateaus
with the half-integer values can be obtained in the gap induced by
magnetic impurities, which means that the pure spin current can be induced in
the sample. We also find that the pure spin current is insensitive to weak
disorder. The mechanism to generate pure spin currents is generalized for
two-dimensional topological insulators.Comment: 5 pages, 6 figure
Large field homogeneous illumination in microwave-induced thermoacoustic tomography based on a quasi-conical spiral antenna
Conventional helical and horn antennas based on frequency selective surfaces have been used to provide microwave illumination in microwave-induced thermoacoustic tomography (TAT). However, the electromagnetic waves radiated from the conventional antennas are not circularly polarized and thus impair image quality. In addition, conventional antennas can provide uniform radiations only within a relatively small area and thus limit their clinical applications (e.g., breast imaging). To address these problems, we propose a quasi-conical log-spiral antenna for homogenous illumination over a large field. We theoretically and experimentally validated this approach. Tissue-mimicking phantoms were imaged. The antenna produced not only an electric field with a circular polarization but also a homogeneous illumination area with a 10 cm diameter. Accordingly, our method has advanced TAT by improving microwave illumination
Large field homogeneous illumination in microwave-induced thermoacoustic tomography based on a quasi-conical spiral antenna
Conventional helical and horn antennas based on frequency selective surfaces have been used to provide microwave illumination in microwave-induced thermoacoustic tomography (TAT). However, the electromagnetic waves radiated from the conventional antennas are not circularly polarized and thus impair image quality. In addition, conventional antennas can provide uniform radiations only within a relatively small area and thus limit their clinical applications (e.g., breast imaging). To address these problems, we propose a quasi-conical log-spiral antenna for homogenous illumination over a large field. We theoretically and experimentally validated this approach. Tissue-mimicking phantoms were imaged. The antenna produced not only an electric field with a circular polarization but also a homogeneous illumination area with a 10 cm diameter. Accordingly, our method has advanced TAT by improving microwave illumination
- …