Even-odd flux quanta effect in the Fraunhofer oscillations of an edge-channel Josephson junction

Baxevanis, B.; Ostroukh, Viacheslav; Beenakker, C. W. J.

doi:10.1103/physrevb.91.041409

Cited by 32 publications

(41 citation statements)

References 26 publications

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“…As was already mentioned, substantial deviations from the conventional Fraunhofer pattern occur at t ≫ 1. Equations (8) and ( The hallmarks of the "modified Fraunhofer" pattern (1) are displayed graphically in Fig. 3.…”

Section: Qualitative Considerations and Main Resultsmentioning

confidence: 99%

Edge effects in the magnetic interference pattern of a ballistic SNS junction

2016

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We investigate the Josephson critical current Ic(Φ) of a wide superconductor-normal metalsuperconductor (SNS) junction as a function of the magnetic flux Φ threading it. Electronic trajectories reflected from the side edges alter the function Ic(Φ) as compared to the conventional Fraunhofer-type dependence. At weak magnetic fields, B Φ0/d 2 , the edge effect lifts zeros in Ic(Φ) and gradually shifts the minima of that function toward half-integer multiples of the flux quantum. At B > Φ0/d 2 , the edge effect leads to an accelerated decay of the critical current Ic(Φ) with increasing Φ. At larger fields, eventually, the system is expected to cross into a regime of "classical" mesoscopic fluctuations that is specific for wide ballistic SNS junctions with rough edges.

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Section: Qualitative Considerations and Main Resultsmentioning

confidence: 99%

Edge effects in the magnetic interference pattern of a ballistic SNS junction

2016

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“…The phenomenological model proposed by Baxevanis et al considers both single edge and crossed Andreev states [27]. In our device we expect the lowest order crossed Andreev states to contribute most because of the short coherence length.…”

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confidence: 90%

“…This process alone is independent of the flux through the junction, but still adds to the critical current [27]. Higher order processes that include an electron that encircles the junction completely pick up an h/e phase when a flux quantum threads through the junction, hence the supercurrent becomes h/e periodic [28].…”

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confidence: 99%

h/e Superconducting Quantum Interference through Trivial Edge States in InAs

et al. 2018

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Josephson junctions defined in strong spin orbit semiconductors are highly interesting for the search for topological systems. However, next to topological edge states that emerge in a sufficient magnetic field, trivial edge states can also occur. We study the trivial edge states with superconducting quantum interference measurements on non-topological InAs Josephson junctions. We observe a SQUID pattern, an indication of superconducting edge transport. Also, a remarkable h/e SQUID signal is observed that, as we find, stems from crossed Andreev states.Topological systems are a hot topic in condensed matter physics [1]. This is largely motivated by the existence of states at the interface between two topologically distinct phases, for example helical edge states in a quantum spin Hall insulator (QSHI) [2, 3]. Inducing superconductivity in these edge states would form a topological superconductor [1]. Superconducting edge transport has already been found in materials that are predicted to be QSHI [4, 5]. However, edge states can also have a non-topological origin. Trivial edge conduction is found in InAs alongside the chiral edge states in the QH regime [6] and recently in the proposed QSHI InAs/GaSb as well [7,8]. To be able to discriminate between topological and trivial states it is crucial to study transport through trivial edges also and clarify differences and similarities between them. In this work we study the superconducting transport through trivial edge states in non-topological InAs Josephson junctions using superconducting quantum interference (SQI) measurements. We find supercurrent carried by these edge states and an intriguing h/e periodic signal in a superconducting quantum interference device (SQUID) geometry.Trivial edge states arise when the Fermi level resides in the band gap in the bulk, while being pinned in the conduction band at the surface.Then, band bending leads to electron accumulation at that surface as schematically drawn in Fig. 1(a). The Fermi level pinning can have several origins: truncating the Bloch functions in space [9,10], a work function difference [11], the built-in electric field in a heterostack [12] and the surface termination [13]. In our 2D InAs Josephson junctions the accumulation surface is located at the edge of the mesa that is defined by wet etching. The quantum well is MBE grown on a GaSb substrate serving as a global bottom gate [14]. The superconducting electrodes are made of sputtered NbTiN with a spacing of 500 nm and a width of 4 µm. A SiN x dielectric separates the top gate from the heterostructure. Electrical quasi-four terminal measurements [see Fig.1(b)] are performed in a dilution refrigerator with an electron temperature of 60 mK unless stated otherwise.The electron density in the InAs quantum well is altered by using the electrostatic gates, V tg and V bg , located above and below the 2DEG. Decreasing the density subsequently increases the normal state resistance R n and reduces the switching current I s as shown in Fig. 2(a). A full resistance map ...

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“…In this work, we propose a device to investigate the quantum interference of edge supercurrents in 2D TIs. The quantum interference of supercurrents carried by the two edges of the Josephson junction has been studied by analysing their flux dependence [55,58]. Here we aim to probe the density of states of a single proximized edge via a normal tunnel probe, see Fig.…”

Section: Introductionmentioning

confidence: 99%

Topological SQUIPT Based on Helical Edge States in Proximity to Superconductors

et al. 2018

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We propose a device based on a topological Josephson junction where the helical edge states of a two-dimensional topological insulator are in close proximity to two superconducting leads. The presence of a magnetic flux through the junction leads to a Doppler shift in the spectrum of Andreev bound states, and affects the quantum interference between proximized edge states. We inspect the emergent features, accessing the density of states through a tunnel-coupled metallic probe, thus realizing a Topological Superconducting Quantum Interference Proximity Transistor (TSQUIPT). We calculate the expected performances of this new device, concluding that it can be used as a sensitive, absolute magnetometer due to the voltage drop across the junction decaying to a constant value as a function of the magnetic flux. Contrary to conventional SQUID and SQUIPT designs, no ring structure is needed. The findings pave the way for novel and sensitive devices based on hybrid devices that exploit helical edge states. arXiv:1801.10078v1 [cond-mat.mes-hall]

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Even-odd flux quanta effect in the Fraunhofer oscillations of an edge-channel Josephson junction

Cited by 32 publications

References 26 publications

Edge effects in the magnetic interference pattern of a ballistic SNS junction

Edge effects in the magnetic interference pattern of a ballistic SNS junction

h/e Superconducting Quantum Interference through Trivial Edge States in InAs

Topological SQUIPT Based on Helical Edge States in Proximity to Superconductors

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