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Uchino, Shun
Physical Review A, 106(5), p.053320_1 - 053320_14, 2022/11
Times Cited Count:5 Percentile:67.72(Optics)Motivated by realization of the dissipative quantum point contact in ultracold atomic gases, we investigate a two-terminal mesoscopic transport system in which a single-particle loss is locally present in a one-dimensional chain. By means of the Dyson equation approach in the Keldysh formalism that can incorporate dissipative effects, we reveal analytic structures of the particle and energy currents whose formal expressions correspond to ones in certain three-terminal systems where the particle loss is absent. The obtained formulas are also consistent with non-hermitian and three-terminal Landauer-Buttiiker analyses. The universality on the current expressions holds regardless of quantum statistics and may be useful for understanding lossy two-terminal transport in terms of three-terminal transport and vice versa.
Sekino, Yuta*; Tajima, Hiroyuki*; Uchino, Shun
Physical Review Research (Internet), 4(4), p.043014_1 - 043014_16, 2022/10
We show that the optical spin conductivity being a small AC response of a bulk spin current and elusive in condensed matter systems can be measured in ultracold atoms. We demonstrate that this conductivity contains rich information on quantum states by analyzing experimentally achievable systems. The obtained conductivity spectra being absent in the Drude conductivity reflect quasiparticle excitations and non-Fermi liquid properties. Unlike its mass transport counterpart, the spin conductivity serves as a probe applicable to clean atomic gases without disorder and lattice potentials. Our formalism can be generalized to various systems such as spin-orbit coupled and nonequilibrium systems.
topological Fermi superfluidsTajima, Hiroyuki*; Sekino, Yuta*; Uchino, Shun
Physical Review B, 105(6), p.064508_1 - 064508_9, 2022/02
Times Cited Count:4 Percentile:59.24(Materials Science, Multidisciplinary)We theoretically investigate optical bulk spin transport properties in a spin- topological Fermi superfluid. We specifically consider a one-dimensional system with an inter-spin 
-wave interaction, which can be realized in ultracold-atom experiments. Developing the BCS-Leggett theory to describe the BCS to Bose-Einstein condensate evolution and the Z
topological phase transition in this system, we show how the spin transport reflects these many-body aspects. We find that the optical spin conductivity, which is a small AC response of a spin current, shows the spin-gapped spectrum in the wide parameter region and the gap closes at the Z topological phase transition point. Moreover, the validity of the low-energy effective model of the Majorana zero mode is discussed along the BCS-BEC evolution in connection with the scale invariance at -wave unitarity.
Uchino, Shun
Nihon Butsuri Gakkai-Shi, 76(1), p.4 - 12, 2021/01
Ultracold atomic gases allow us to simulate bare essentials of complicated quantum phenomena. Recently, atomtronics devices to simulate mesoscopic transport with ultracold atomics gases have been realized in experiments. In this article, we review recent progress of two-terminal transport in ultracold atomic gases, with a special focus on point contact transport in two-component Fermi gases.
Uchino, Shun
no journal, ,
Utracold atomic gases play crucial roles in revealing nontrivial quantum transport phenomena. In this presentation, I will discuss recent progresses on mesoscopic transport realized with ultracold atomic gases.
Uchino, Shun
no journal, ,
Quantum Transport that allow one to characterize quantum many-body systems plays a crucial role in condensed matter physics. In this presentation, I will explain what happens if the concept of quantum transport is applied to ultracold atomic gases.
