Diamagnetic mechanism of critical current non-reciprocity in multilayered superconductors

Sundaresh, Ananthesh; Väyrynen, Jukka I.; Lyanda-Geller, Yuli; Rokhinson, Leonid P.

doi:10.1038/s41467-023-36786-5

Cited by 33 publications

(16 citation statements)

References 38 publications

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“…As for the mechanism of the SDE, while the intrinsic mechanism based on the asymmetry of the band structure has been proposed, [16][17][18] several extrinsic mechanisms have also been reported. [5,[13][14][15] In this study, we demonstrated a zero-field SDE with an efficiency of up to 40% in Fe-inserted non-centrosymmetric Nb/V/Ta superconducting artificial superlattices. The polarity and magnitude of the zero-field SDE were controlled by the direction of magnetization, suggesting the existence of an effective exchange field on the Cooper pairs.…”

Section: Introductionmentioning

confidence: 59%

“…To gain further insight into the observed SDE, we investigated possible extrinsic contributions, such as asymmetric edges, [14] Meisner screening currents originating from magnetization, [14] and Josephson vortices. [15] When superconductivity breaks from the edge of the sample, the sign of Q should change depending on which end of the sample the superconductivity starts to break from. First, we verified the contribution of asymmetric edges [14] by examining the reproducibility of Q.…”

Section: Resultsmentioning

confidence: 99%

“…Third, we evaluated the contribution of the Josephson vortices, which induce the non-reciprocal critical current with oscillation for a magnetic field in superconducting multilayers. [15] We assumed that Fe (1.0 nm) forms a ferromagnetic Josephson barrier. The magnetic flux Φ was calculated considering the area S ( = 0.001 × 210 𝜇m 2 ), which is defined by the thickness of the Fe layer and the length between two electrodes.…”

Section: Resultsmentioning

confidence: 99%

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Magnetization Control of Zero‐Field Intrinsic Superconducting Diode Effect

et al. 2023

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The superconducting diode effect (SDE), which causes a superconducting state in one direction and a normal‐conducting state in another, has significant potential for developing ultralow power consumption circuits and non‐volatile memory. However, the practical control of the SDE necessities the precise tuning of current, temperature, magnetic field, or magnetism. Therefore, the mechanisms of the SDE must be understood to develop novel materials and devices capable of realizing the SDE under more controlled and robust conditions. This study demonstrates an intrinsic zero‐field SDE with an efficiency of up to 40% in Fe/Pt‐inserted non‐centrosymmetric Nb/V/Ta superconducting artificial superlattices. The polarity and magnitude of the zero‐field SDE are controllable by the direction of magnetization, indicating that the effective exchange field acts on Cooper pairs. Furthermore, the first‐principles calculation indicates that the SDE can be enhanced by an asymmetric configuration of proximity induced magnetic moments in superconducting layers, which induces a magnetic toroidal moment. This study has important implications regarding the development of novel materials and devices that can effectively control the SDE. Moreover, the magnetization control of the SDE is expected to aid in the designing of superconducting quantum devices and establishing a material platform for topological superconductors.

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Section: Introductionmentioning

confidence: 59%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Magnetization Control of Zero‐Field Intrinsic Superconducting Diode Effect

et al. 2023

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“…Type II superconductors (type II SCs) are distinguished by their characteristic mixed state in the phase diagram due to the appearance of superconducting vortices [1]. The dynamics of these Abrikosov vortices can be modified by applied current, external magnetic field, sample geometry/confinement [2,3], and magnetic proximity effect [4][5][6], thereby opening various possibilities for controlling device properties, for instance, the superconducting diode effect (SDE) [7][8][9]. The appearance of nonreciprocal current-voltage characteristics in a superconductor has received revived interest following the observation of field-free superconducting rectification effects in van der Waals heterostructures (vdWHs) and multilayered Rashba superconductors [10,11].…”

Section: Introductionmentioning

confidence: 99%

Flux-pinning mediated superconducting diode effect in NbSe₂/CrGeTe₃ heterostructure

Mehrnejat,

Hatnean,

Rosamond

et al. 2024

2D Mater.

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In ferromagnet/superconductor bilayer systems, dipolar fields from the ferromagnet can create asymmetric energy barriers for the formation and dynamics of vortices through flux pinning. Conversely, the flux emanating from vortices can pin the domain walls of the ferromagnet, thereby creating asymmetric critical currents. Here, we report the observation of a superconducting diode effect in a NbSe2/CrGeTe3 van der Waals heterostructure in which the magnetic domains of CrGeTe3 control the Abrikosov vortex dynamics in NbSe2. In addition to extrinsic vortex pinning mechanisms at the edges of NbSe2, flux-pinning-induced bulk pinning of vortices can alter the critical current. This asymmetry can thus be explained by considering the combined effect of this bulk pinning mechanism along with the vortex tilting induced by the Lorentz force from the transport current in the NbSe2/CrGeTe3 heterostructure. We also provide evidence of critical current modulation by flux pinning depending on the history of the field setting procedure. Our results suggest a method of controlling the efficiency of the superconducting diode effect in magnetically coupled van der Waals superconductors, where dipolar fields generated by the magnetic layer can be used to modulate the dynamics of the superconducting vortices in the superconductors.

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“…In the meantime, it has been realized that higher superconducting diode efficiency can be achieved in properly designed nanostructures in which the time-reversal symmetry is broken via trapped fluxes or an external magnetic field. − However, a magnetic field is often undesired for integrating the devices in superconducting circuits. In this work, we rectify this problem by creating superconducting diodes which can operate at zero external magnetic field and achieve efficiency approaching 100%.…”

mentioning

confidence: 99%

Nonreciprocal Supercurrents in a Field-Free Graphene Josephson Triode

et al. 2023

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Superconducting diodes are proposed nonreciprocal circuit elements that should exhibit nondissipative transport in one direction while being resistive in the opposite direction. Multiple examples of such devices have emerged in the past couple of years; however, their efficiency is typically limited, and most of them require a magnetic field to function. Here we present a device that achieves efficiencies approaching 100% while operating at zero field. Our samples consist of a network of three graphene Josephson junctions linked by a common superconducting island, to which we refer as a Josephson triode. The three-terminal nature of the device inherently breaks the inversion symmetry, and the control current applied to one of the contacts breaks the time-reversal symmetry. The triode's utility is demonstrated by rectifying a small (nA scale amplitude) applied square wave. We speculate that devices of this type could be realistically employed in the modern quantum circuits.

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Diamagnetic mechanism of critical current non-reciprocity in multilayered superconductors

Cited by 33 publications

References 38 publications

Magnetization Control of Zero‐Field Intrinsic Superconducting Diode Effect

Magnetization Control of Zero‐Field Intrinsic Superconducting Diode Effect

Flux-pinning mediated superconducting diode effect in NbSe₂/CrGeTe₃ heterostructure

Nonreciprocal Supercurrents in a Field-Free Graphene Josephson Triode

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Diamagnetic mechanism of critical current non-reciprocity in multilayered superconductors

Cited by 33 publications

References 38 publications

Magnetization Control of Zero‐Field Intrinsic Superconducting Diode Effect

Magnetization Control of Zero‐Field Intrinsic Superconducting Diode Effect

Flux-pinning mediated superconducting diode effect in NbSe2/CrGeTe3 heterostructure

Nonreciprocal Supercurrents in a Field-Free Graphene Josephson Triode

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Product

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Flux-pinning mediated superconducting diode effect in NbSe₂/CrGeTe₃ heterostructure