Piezoelectric effect and diode effect in anapole and monopole superconductors

Chazono, Michiya; Kanasugi, Shota; Kitamura, Taisei; Yanase, Youichi

doi:10.1103/physrevb.107.214512

“…called superconducting piezoelectric effect (Chazono et al, 2023(Chazono et al, , 2022. As in the case of the magnetizationsupercurrent correlation, the superconducting piezoelectric effect is clearly distinguished from the conventional (inverse) piezoelectric and magnetopiezoelectric effects in terms of the fields stimulating the strain, since the latter two effects are involved in the electric field and ohmic current, respectively.…”

Section: Parity-violating Superconducting Responsesmentioning

confidence: 99%

Photocurrent response in parity-time symmetric current-ordered states

Watanabe

¹

,

Yanase

²

2021

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Parity-time-reversal symmetry (PT symmetry), a symmetry for the combined operations of space inversion (P) and time reversal (T ), is a fundamental concept of physics and characterizes the functionality of materials as well as P and T symmetries. In particular, the PT -symmetric systems can be found in the centrosymmetric crystals undergoing the parity-violating magnetic order which we call the odd-parity magnetic multipole order. While this spontaneous order leaves PT symmetry intact, the simultaneous violation of P and T symmetries gives rise to various emergent responses that are qualitatively different from those allowed by the nonmagnetic P-symmetry breaking or by the ferromagnetic order. In this review, we introduce candidates hosting the intriguing spontaneous order and overview the characteristic physical responses. Various off-diagonal and/or nonreciprocal responses are identified, which are closely related to the unusual electronic structures such as hidden spin-momentum locking and asymmetric band dispersion. Contents I. Introduction II. Magnetic Parity Violation and Space-Time Symmetry A. Parity-time-reversal symmetry and parity violations B. Hidden Magnetic Degrees of Freedom in Crystals C. Multipolar degree of freedom of visible antiferromagnets III. Emergent Responses of PT -symmetric magnets A. Electric-Magnetic Classification of Response Function B. Magnetic Counterpart of Piezoelectric Effect C. Nonreciprocal Property of Electronic Transport and Optical Response 1. Nonreciprocal conductivity 2. Photocurrent generation IV. Availability of PT -symmetric Magnets and Physical Properties A. Switching the compensated magnets B. Control of electronic property with PT -symmetric magnetic order V.

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“…In the flatband systems [36,37,[47][48][49][50][51] the superfluid weight from Fermi-liquid theory vanishes, and the quantum geometric contribution determines the superfluid weight. The quantum geometry also plays essential roles in the monolayer FeSe [52] and some finite-momentum Cooper pairing states [53][54][55][56][57]. However, how quantum geometry affects the pairing mechanism of superconductivity has not been revealed.…”

mentioning

confidence: 99%

Spin-Triplet Superconductivity from Quantum-Geometry-Induced Ferromagnetic Fluctuation

Kitamura,

Daido,

Yanase

2024

Phys. Rev. Lett.

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We show that quantum geometry induces ferromagnetic fluctuation resulting in spin-triplet superconductivity. The criterion for ferromagnetic fluctuation is clarified by analyzing contributions from the effective mass and quantum geometry. When the non-Kramers band degeneracy is present near the Fermi surface, the Fubini-Study quantum metric strongly favors ferromagnetic fluctuation. Solving the linearized gap equation with the effective interaction obtained by the random phase approximation, we show that the spin-triplet superconductivity is mediated by quantum-geometry-induced ferromagnetic fluctuation.

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Magnetic parity violation and parity-time-reversal-symmetric magnets

Watanabe,

Yanase

2024

J. Phys.: Condens. Matter

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0

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Parity-time-reversal symmetry ( PT symmetry), a symmetry for the combined operations of space inversion ( P ) and time reversal ( T ), is a fundamental concept of physics and characterizes the functionality of materials as well as P and T symmetries. In particular, the PT -symmetric systems can be found in the centrosymmetric crystals undergoing the parity-violating magnetic order which we call the odd-parity magnetic multipole order. While this spontaneous order leaves PT symmetry intact, the simultaneous violation of P and T symmetries gives rise to various emergent responses that are qualitatively different from those allowed by the nonmagnetic P -symmetry breaking or by the ferromagnetic order. In this review, we introduce candidates hosting the intriguing spontaneous order and overview the characteristic physical responses. Various off-diagonal and/or nonreciprocal responses are identified, which are closely related to the unusual electronic structures such as hidden spin-momentum locking and asymmetric band dispersion.

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Piezoelectric effect and diode effect in anapole and monopole superconductors

Cited by 11 publications

References 72 publications

Photocurrent response in parity-time symmetric current-ordered states

Photocurrent response in parity-time symmetric current-ordered states

Spin-Triplet Superconductivity from Quantum-Geometry-Induced Ferromagnetic Fluctuation

Magnetic parity violation and parity-time-reversal-symmetric magnets

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