Nernst effect in anisotropic four-terminal topological nodal-line semimetals.

The Nernst effect is the transverse mode of thermoelectric transport, in which a longitudinal thermal gradient induces a transverse current in the conductor while under a perpendicular magnetic field. Here the Nernst effect in a mesoscopic topological nodal-line semimetals (TNLSMs) system of four-terminal cross-bar with the spin-orbit coupling under a perpendicular magnetic field is studied. The Nernst coefficientNcin two non-equivalen connection modes (kz-ymode andkx-ymode) is calculated based on the tight-binding Hamiltonian combined with the nonequilibrium Green's function method. When the magnetic field is absent withφ = 0.0, the Nernst coefficientNc=0is exactly regardless of the temperature. When the magnetic field is not zero, the Nernst coefficient exhibits a series of densely oscillating peaks. The height of peak strongly depends on the magnetic field, and the Nernst coefficient is an even function of the Fermi energyEFsatisfying the symmetrical propertyNc(-EF)=Nc(EF). The Nernst coefficient is also closely related to the temperatureT. When the temperature is very low (orT→0), the Nernst coefficient depends linearly on temperature. In the presence of a strong magnetic field, the Nernst coefficient shows peaks when the Fermi energy crosses the Landau levels. Under the weak magnetic field, the influence of spin-orbit coupling in TNLSMs materials on Nernst effect is very obvious. In the presence of the mass term, thePT-symmetry of the system is destroyed, the nodal ring of TNLSMs is broken and an energy gap will be opened. The Nernst coefficientNchas a large value in the energy gap, which is very promising for the application of the transverse thermoelectric transport.

[Astrocytes as therapeutic targets after spinal cord injury].

Spinal cord injury (SCI) is a challenging medical problem in the field of neurology, showing high incidence rate, disability rate, treatment cost and low-aged trend. Despite the clinical application of drug intervention, surgical treatment and modern rehabilitation training, no ideal curative effect has been achieved. Therefore, future study is necessary to clarify detailed pathological mechanism of SCI and identify the potential target cells for therapeutic intervention. In the central nervous system (CNS), astrocytes are the most abundant and widely distributed glial cells which play multiple key roles in maintaining homeostasis of the CNS in physiological and pathological conditions. Increasing evidence indicates that astrocytes are ideal therapeutic target cells for SCI. Here, we review current knowledge of the roles of astrocytes in the pathological reaction after SCI, astroglial transplantation and astrocyte reprogramming.