Edge-mode superconductivity in a two-dimensional topological insulator

Pribiag, Vlad; Beukman, Arjan J. A.; Qu, Fanming; Cassidy, Maja; Charpentier, Christophe; Wegscheider, Werner; Kouwenhoven, Leo P.

doi:10.1038/nnano.2015.86

Cited by 237 publications

(274 citation statements)

References 37 publications

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“…The topological Altland-Zirnbauer ensembles still lack an experimental platform of similar versatility, but there is a great variety of candidate systems. We are particularly excited by the recent progress in quantum spin-Hall insulators (HgTe or InAs quantum wells) with superconducting electrodes (Hart et al, 2014;Knez, Du, and Sullivan, 2012;Pribiag et al, 2014). The quantum dot geometry of Fig.…”

Section: Discrete Vorticesmentioning

confidence: 99%

Random-matrix theory of Majorana fermions and topological superconductors

2015

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The theory of random matrices originated half a century ago as a universal description of the spectral statistics of atoms and nuclei, dependent only on the presence or absence of fundamental symmetries. Applications to quantum dots (artificial atoms) followed, stimulated by developments in the field of quantum chaos, as well as applications to Andreev billiards -quantum dots with induced superconductivity. Superconductors with topologically protected subgap states, Majorana zero-modes and Majorana edge modes, provide a new arena for applications of random-matrix theory. We review these recent developments, with an emphasis on electrical and thermal transport properties that can probe the Majorana fermions.

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Section: Discrete Vorticesmentioning

confidence: 99%

Random-matrix theory of Majorana fermions and topological superconductors

2015

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“…However, it is fair to say that it is very difficult to unambiguously probe the emergence of unconventional SC because -often times -conventional and unconventional signatures of SC look alike. Several recent experiments have demonstrated (as a first step towards the detection of unconventional SC) that helical liquids as boundary states of quantum spin Hall systems can indeed be brought in proximity to s-wave superconductors [10] and serve, for instance, as conducting channels of a Josephson junction [11,12]. Importantly, helicity guarantees perfect local Andreev reflection [13] -the conversion of an electron into a hole with opposite spin -at the interface between the normal and the proximity-induced superconducting region called NS junction.…”

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confidence: 99%

Odd-frequency triplet superconductivity at the helical edge of a topological insulator

2015

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Non-local pairing processes at the edge of a two-dimensional topological insulator in proximity to an s-wave superconductor are usually suppressed by helicity. However, additional proximity of a ferromagnetic insulator can substantially influence the helical constraint and therefore open a new conduction channel by allowing for crossed Andreev reflection (CAR) processes. We show a oneto-one correspondence between CAR and the emergence of odd-frequency triplet superconductivity. Hence, non-local transport experiments that identify CAR in helical liquids yield smoking-gun evidence for unconventional superconductivity. Interestingly, we identify a setup -composed of a superconductor flanked by two ferromagnetic insulators -that allows us to favor CAR over electron cotunneling which is known to be a difficult but essential task to be able to measure CAR. PACS numbers: 74.45.+c, 74.78.Na, 71.10.Pm, 74.20.Rp Introduction.-The influence of strong spin-orbit coupling and the constraint of time reversal symmetry are responsible for the appearance of helical electronic channels at the edge of two-dimensional (2D) topological insulators [1][2][3]. Ample evidence for the experimental detection of these edge states has been seen in transport [4][5][6] and scanning SQUID experiments [7]. Proximity of an ordinary s-wave superconductor can induce pairing at the helical edge [8,9]. Interestingly, the interplay of helicity and superconducting order gives rise to unconventional proximity-induced superconductivity (SC) in these systems. However, it is fair to say that it is very difficult to unambiguously probe the emergence of unconventional SC because -often times -conventional and unconventional signatures of SC look alike. Several recent experiments have demonstrated (as a first step towards the detection of unconventional SC) that helical liquids as boundary states of quantum spin Hall systems can indeed be brought in proximity to s-wave superconductors [10] and serve, for instance, as conducting channels of a Josephson junction [11,12]. Importantly, helicity guarantees perfect local Andreev reflection [13] -the conversion of an electron into a hole with opposite spin -at the interface between the normal and the proximity-induced superconducting region called NS junction. Evidently, perfect local Andreev reflection can give rise to sub-gap Andreev states, for instance, in Josephson junction setups. Among these sub-gap states, the one with zero excitation energy is its own chargeconjugate state. It has been coined Majorana (bound) state and has attracted a lot of attention because of potential applications of this anyonic state for topological quantum computing [14]. If a ferromagnet (FM) is placed in vicinity to the NS interface the Majorana (bound) state can be localized in the region between the FM and the SC [9]. This localization allows us to make a formal connection to the physics of a finite-size 1D p-wave topological superconductor [15], and its potential realizations in spin-orbit nanowires [16,17]. In this Letter, ...

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“…The broad conducting pathway that appears along the NS interface will be gapped by the superconducting proximity effect, but a narrow gapless channel may remain because superconductivity only becomes effective at some penetration length ξ 0 from the NS interface. (Reference [4] estimates ξ 0 240 nm, comparable to the estimated width of the edge states.) This channel provides a connection between the helical edge states that is nonhelical, meaning that either spin can propagate in both directions.…”

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confidence: 70%

“…Turning now to the experiment that motivated this analysis [4], we first of all notice that the observed even-odd effect appears already for the first few peaks around zero field. An explanation in terms of a Lorentz-force induced asymmetry in the current distribution is therefore unlikely [19][20][21][22][23].…”

Section: -2mentioning

confidence: 92%

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

2015

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We calculate the beating of h/2e and h/e periodic oscillations of the flux-dependent critical supercurrent I c ( ) through a quantum spin-Hall insulator between two superconducting electrodes. A conducting pathway along the superconductor connects the helical edge channels via a nonhelical channel, allowing an electron incident on the superconductor along one edge to be Andreev reflected along the opposite edge. In the limit of small Andreev reflection probability the resulting even-odd effect is described by I c ∝ | cos(e / ) + f |, with |f | 1 proportional to the probability for phase-coherent interedge transmission. Because the sign of f depends on microscopic details, a sample-dependent inversion of the alternation of large and small peaks is a distinctive feature of the beating mechanism for the even-odd effect. Superconductor-normal-metal-superconductor junctions with edge channel conduction in the normal region are governed by the interplay of charge e and charge 2e transport: Charge can only enter or exit the superconductor in units of 2e, but in the normal region this Cooper pair can be split over opposite edges, when an electron incident on the normalsuperconductor (NS) interface along one edge is Andreev reflected as a hole along the opposite edge.For quantum Hall edge channels this mechanism produces Fraunhofer oscillations (oscillations of the critical current with enclosed flux ) having a fundamental period of h/e, twice the usual periodicity [1]. These are chiral edge channels, so Andreev reflection along the edge of incidence is forbidden and only the circulating path of Fig. 1(a) contributes to the supercurrent. When the edge channels allow for propagation in both directions, the critical current includes the usual h/2e-periodic contributions from Andreev reflection along a single edge, and further h/e periodic contributions from circulating paths without charge transfer [ Fig. 1(b)].Here we investigate this beating of h/e and h/2e periodic contributions to the Fraunhofer oscillations. We are motivated by recent work on proximity induced superconductivity in quantum spin-Hall (QSH) insulators [2][3][4][5][6][7][8], which in one series of experiments [4] showed Fraunhofer oscillations with an even-odd effect: Large peaks in the critical current at even multiples of h/2e alternate with smaller peaks at odd multiples.The QSH insulator has helical edge channels (with direction of motion tied to the spin), so we consider that case in what follows (although the beating mechanism for the even-odd effect does not rely on helicity). Following Ref.[6] we assume that the superconductors dope the contacted QSH insulator, locally pushing the Fermi level in the conduction band. The broad conducting pathway that appears along the NS interface will be gapped by the superconducting proximity effect, but a narrow gapless channel may remain because superconductivity only becomes effective at some penetration length ξ 0 from the NS interface. (Reference [4] estimates ξ 0 240 nm, comparable to the estimated width o...

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Edge-mode superconductivity in a two-dimensional topological insulator

Cited by 237 publications

References 37 publications

Random-matrix theory of Majorana fermions and topological superconductors

Random-matrix theory of Majorana fermions and topological superconductors

Odd-frequency triplet superconductivity at the helical edge of a topological insulator

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

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