Non-Hermitian quantum impurity systems in and out of equilibrium: noninteracting case

Yoshimura, Takato; Bidzhiev, Kemal; Saleur, Hubert

doi:10.48550/arxiv.2002.08478

Cited by 2 publications

(2 citation statements)

References 33 publications

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“…From a broader perspective, a non-Hermitian TLL has also been discussed by Affleck et al [654] in the context of vortex pinnings originally discussed by Hatano and Nelson for a singleparticle lattice model [71]. The analogous winding RG flows have also been discussed in the non-Hermitian Kondo models [649,655,656] (Fig. 28(d)), where the Bethe-ansatz techniques have been found to remain useful.…”

Section: Criticality Dynamics and Chaosmentioning

confidence: 91%

Non-Hermitian Physics

Ashida,

Gong,

Ueda

2020

Preprint

129

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A review is given on the foundations and applications of non-Hermitian classical and quantum physics. First, key theorems and central concepts in non-Hermitian linear algebra, including Jordan normal form, biorthogonality, exceptional points, pseudo-Hermiticity and parity-time symmetry, are delineated in a pedagogical and mathematically coherent manner. Building on these, we provide an overview of how diverse classical systems, ranging from photonics, mechanics, electrical circuits, acoustics to active matter, can be used to simulate non-Hermitian wave physics. In particular, we discuss rich and unique phenomena found therein, such as unidirectional invisibility, enhanced sensitivity, topological energy transfer, coherent perfect absorption, single-mode lasing, and robust biological transport. We then explain in detail how non-Hermitian operators emerge as an effective description of open quantum systems on the basis of the Feshbach projection approach and the quantum trajectory approach. We discuss their applications to physical systems relevant to a variety of fields, including atomic, molecular and optical physics, mesoscopic physics, and nuclear physics with emphasis on prominent phenomena/subjects in quantum regimes, such as quantum resonances, superradiance, continuous quantum Zeno effect, quantum critical phenomena, Dirac spectra in quantum chromodynamics, and nonunitary conformal field theories. Finally, we introduce the notion of band topology in complex spectra of non-Hermitian systems and present their classifications by providing the proof, firstly given by this review in a complete manner, as well as a number of instructive examples. Other topics related to non-Hermitian physics, including nonreciprocal transport, speed limits, nonunitary quantum walk, are also reviewed.

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Section: Criticality Dynamics and Chaosmentioning

confidence: 91%

Non-Hermitian Physics

Ashida,

Gong,

Ueda

2020

Preprint

129

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“…Part of the reason is that the corresponding quantum system must be open (i.e., non-Hermitian), which is typically more difficult to control both in experiment and theory compared with closed (i.e., Hermitian) systems. In recent years, however, there is rapidly growing interest in studying non-Hermitian quantum systems [13,14] due to the advances in atomic-molecular-optical experiments allowing control over open quantum systems [15,16] and theoretical developments exploring quantum critical phenomena [17][18][19][20][21] and topological phases [22][23][24][25][26][27][28]. We are therefore in position to ask whether there exist new phases of matter induced by activity (i.e., non-Hermitian terms that can be interpreted as self-driving) in quantum many-body systems, and if so, how they can be realized in experiments.…”

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confidence: 99%

Activity-induced phase transition in a quantum many-body system

Adachi,

Takasan,

Kawaguchi

2020

Preprint

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A crowd of nonequilibrium entities can show phase transition behaviours that are prohibited in conventional equilibrium setups. One of the simplest and well-studied phenomena observed in such active matter is the motility-induced phase separation (MIPS), where self-propelled particles spontaneously aggregate. An interesting question is whether a similar activity-driven phase transition occurs in a pure quantum system. Here we introduce a non-Hermitian quantum many-body model that undergoes quantum phase transitions, which includes the analogue of the classical MIPS within its parameter space. The phase diagram, which can be experimentally tested in an open quantum system, indicates that the addition of spin-dependent asymmetric hopping to a simple model of hard-core bosons is sufficient to induce flocking as well as phase separation. Moreover, we find that the quantum phase transitions in the model are equivalent to the transitions of dynamical paths in classical kinetics upon the application of biasing fields. This example demonstrates that quantum systems can indeed show activity-induced phase transitions, and sheds light on the rich connection between classical nonequilibrium kinetics and non-Hermitian quantum physics.

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Non-Hermitian quantum impurity systems in and out of equilibrium: noninteracting case

Cited by 2 publications

References 33 publications

Non-Hermitian Physics

Non-Hermitian Physics

Activity-induced phase transition in a quantum many-body system

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