Nonreciprocal transport in gate-induced polar superconductor SrTiO
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Itahashi, Yuki M.; Ideue, Toshiya; Saito, Yu; Shimizu, Sunao; Ouchi, Takumi; Nojima, Tsutomu; Iwasa, Yoshihiro

doi:10.1126/sciadv.aay9120

Cited by 102 publications

(66 citation statements)

References 42 publications

(127 reference statements)

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“…Moreover, nonreciprocal transport is observed, which reflects the ratio of odd versus even pairing interactions. A similar highlight was observed in a gate-induced 2D SC of interfacial STO [44]. Due to its Rashba-type spin orbit interaction, it reveals nonreciprocal transport, where the inequivalent rightward and leftward currents reflect simultaneous spatial inversion and time-reversal symmetry breaking-an exciting prospect of forthcoming research on STO.…”

Section: Routes Of Srtio 3 Toward Ferroelectricity and Other Collective Statessupporting

confidence: 64%

SrTiO3—Glimpses of an Inexhaustible Source of Novel Solid State Phenomena

et al. 2020

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The purpose of this selective review is primarily to demonstrate the large versatility of the insulating quantum paraelectric perovskite SrTiO3 explained in “Introduction” part, and “Routes of SrTiO3 toward ferroelectricity and other collective states” part. Apart from ferroelectricity under various boundary conditions, it exhibits regular electronic and superconductivity via doping or external fields and is capable of displaying diverse coupled states. “Magnetoelectric multiglass (Sr,Mn)TiO3” part, deals with mesoscopic physics of the solid solution SrTiO3:Mn2+. It is at the origin of both polar and spin cluster glass forming and is altogether a novel multiferroic system. Independent transitions at different glass temperatures, power law dynamic criticality, divergent third-order susceptibilities, and higher order magneto-electric interactions are convincing fingerprints.

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Section: Routes Of Srtio 3 Toward Ferroelectricity and Other Collective Statessupporting

confidence: 64%

SrTiO3—Glimpses of an Inexhaustible Source of Novel Solid State Phenomena

et al. 2020

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“…These include superconducting non-centrosymmetric gated-MoS 2 12 , Bi 2 Te 3 /FeTe heterostructures 13 and MoGe/Y 3 Fe 5 O 12 bilayers 14 , where the nonreciprocal response is markedly enhanced by several orders of magnitude compared to non-superconducting systems due to the large energy scale difference between the Fermi energy and the superconducting gap 12 , 15 . Apart from being a powerful tool to study the interplay between superconductivity and chirality in non-centrosymmetric superconductors 6 , 16 , nonreciprocal charge transport also promises great potential in superconducting device applications such as vortex diodes 17 and flux lenses 18 , both of which are in great demand for future electrical circuits.…”

Section: Introductionmentioning

confidence: 99%

Nonreciprocal superconducting NbSe2 antenna

Zhang

Zou

et al. 2020

Nat Commun

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The rise of two-dimensional (2D) crystalline superconductors has opened a new frontier of investigating unconventional quantum phenomena in low dimensions. However, despite the enormous advances achieved towards understanding the underlying physics, practical device applications like sensors and detectors using 2D superconductors are still lacking. Here, we demonstrate nonreciprocal antenna devices based on atomically thin NbSe2. Reversible nonreciprocal charge transport is unveiled in 2D NbSe2 through multi-reversal antisymmetric second harmonic magnetoresistance isotherms. Based on this nonreciprocity, our NbSe2 antenna devices exhibit a reversible nonreciprocal sensitivity to externally alternating current (AC) electromagnetic waves, which is attributed to the vortex flow in asymmetric pinning potentials driven by the AC driving force. More importantly, a successful control of the nonreciprocal sensitivity of the antenna devices has been achieved by applying electromagnetic waves with different frequencies and amplitudes. The device’s response increases with increasing electromagnetic wave amplitude and exhibits prominent broadband sensing from 5 to 900 MHz.

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“…Such a UMR sparks a surge of interest in realizing two-terminal rectification, memory, and logic devices 7 , 14 , 15 . To date, more efforts to hunt for the materials with larger γ values by taking the spin–orbit interaction and Fermi energy into account are being made in interface/surface Rashba systems 9 , 15 , 16 . However, given the low Rashba spin splitting energy, e.g., 3 meV (~35 k B ) in LaAlO 3 /SrTiO 3 9 , 5 meV (~58 k B ) in Ge(111) 15 , nonreciprocal transport can only be observed at very low temperature, and here γ -value decreases dramatically with increasing temperature due to the thermal fluctuation.…”

Section: Introductionmentioning

confidence: 99%

Nonreciprocal charge transport up to room temperature in bulk Rashba semiconductor α-GeTe

et al. 2021

Nat Commun

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Nonmagnetic Rashba systems with broken inversion symmetry are expected to exhibit nonreciprocal charge transport, a new paradigm of unidirectional magnetoresistance in the absence of ferromagnetic layer. So far, most work on nonreciprocal transport has been solely limited to cryogenic temperatures, which is a major obstacle for exploiting the room-temperature two-terminal devices based on such a nonreciprocal response. Here, we report a nonreciprocal charge transport behavior up to room temperature in semiconductor α-GeTe with coexisting the surface and bulk Rashba states. The combination of the band structure measurements and theoretical calculations strongly suggest that the nonreciprocal response is ascribed to the giant bulk Rashba spin splitting rather than the surface Rashba states. Remarkably, we find that the magnitude of the nonreciprocal response shows an unexpected non-monotonical dependence on temperature. The extended theoretical model based on the second-order spin–orbit coupled magnetotransport enables us to establish the correlation between the nonlinear magnetoresistance and the spin textures in the Rashba system. Our findings offer significant fundamental insight into the physics underlying the nonreciprocity and may pave a route for future rectification devices.

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Nonreciprocal transport in gate-induced polar superconductor SrTiO ₃

Cited by 102 publications

References 42 publications

SrTiO3—Glimpses of an Inexhaustible Source of Novel Solid State Phenomena

SrTiO3—Glimpses of an Inexhaustible Source of Novel Solid State Phenomena

Nonreciprocal superconducting NbSe2 antenna

Nonreciprocal charge transport up to room temperature in bulk Rashba semiconductor α-GeTe

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Nonreciprocal transport in gate-induced polar superconductor SrTiO 3

Cited by 102 publications

References 42 publications

SrTiO3—Glimpses of an Inexhaustible Source of Novel Solid State Phenomena

SrTiO3—Glimpses of an Inexhaustible Source of Novel Solid State Phenomena

Nonreciprocal superconducting NbSe2 antenna

Nonreciprocal charge transport up to room temperature in bulk Rashba semiconductor α-GeTe

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Product

Resources

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Nonreciprocal transport in gate-induced polar superconductor SrTiO ₃