68 research outputs found
On the Origin of the Anomalous Upper Critical Field in Quasi-One-Dimensional Superconductors
Upper critical field, H_c2, in quasi-1D superconductors is investigated by
the weak coupling renormalization group technique. It is shown that H_c2
greatly exceeds not only the Pauli limit, but also the conventional
paramagnetic limit of the Flude-Ferrell-Larkin-Ovchinnikov (FFLO) state. This
increase is mainly due to quasi-1D fluctuations effect as triggered by
interference between unconventional superconductivity and density-wave
instabilities. Our results give a novel viewpoint on the large H_c2 observed in
TMTSF-salts in terms of a d-wave FFLO state that is predicted to be verified by
the H_c2 measurements under pressure.Comment: 5 pages, 4 figure
Quantum--classical correspondence and dissipative to dissipationless crossover in magnetotransport phenomena
The three-dimensional magneto-conductivity tensor was derived in a gauge
invariant form based on the Kubo formula considering the quantum effect under a
magnetic field, such as the Landau quantization and the quantum oscillations.
We analytically demonstrated that the quantum formula of the
magneto-conductivity can be obtained by adding a quantum oscillation factor to
the classical formula. This result establishes the quantum--classical
correspondence, which has long been missing in magnetotransport phenomena.
Moreover, we found dissipative-to-dissipationless crossover in the Hall
conductivity by paying special attention to the analytic properties of thermal
Green's function. Finally, by calculating the magnetoresistance of semimetals,
we identified a phase shift in quantum oscillation originating from the
dissipationless transport predominant at high fields
Nonperturbative Matrix Mechanics Approach to Spin-Split Landau Levels and the g Factor in Spin-Orbit Coupled Solids
We propose a fully quantum approach to nonperturbatively calculate the spin-split Landau levels and g factor of various spin-orbit coupled solids based on the kâ‹…p theory in the matrix mechanics representation. The new method considers the detailed band structure and the multiband effect of spin-orbit coupling irrespective of the magnetic-field strength. We show an application of this method to PbTe, a typical Dirac electron system. Contrary to popular belief, we show that the spin-splitting parameter M, which is the ratio of the Zeeman to cyclotron energy, exhibits a remarkable magnetic-field dependence. This field dependence can rectify the existing discrepancy between experimental and theoretical results. We also show that M evaluated from the fan diagram plot is different from that determined as the ratio of the Zeeman to cyclotron energy, which also overturns common belief
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