Effects of spin-orbit coupling and spatial symmetries on the Josephson current in SNS junctions

Rasmussen, Asbjørn; Danon, Jeroen; Suominen, Henri J.; Nichele, Fabrizio; Kjærgaard, Morten; Flensberg, Karsten

doi:10.1103/physrevb.93.155406

Cited by 53 publications

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“…This condition is protected by parity and time-reversal symmetries. However, the combined presence of spinorbit coupling and magnetic field breaks these symmetries [1] and can lead to a finite supercurrent even when the phase difference is zero [2,3]. This is the so called anomalous Josephson effectthe hallmark effect of superconducting spintronics -and can be characterized by the corresponding anomalous phase shift (φ 0 ) [4,5].…”

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confidence: 99%

“…This condition is protected by parity and time-reversal symmetries. However the presence of spin-orbit coupling along with the application of an in-plane magnetic field can break these symmetries [1]. This allows an anomalous phase (φ 0 ), which means that with no current flowing there can be a non-zero phase across the junction or, conversely, at zero phase a current can flow.…”

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confidence: 99%

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Gate controlled anomalous phase shift in Al/InAs Josephson junctions

et al. 2020

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In a standard Josephson junction the current is zero when the phase difference between the superconducting leads is zero. This condition is protected by parity and time-reversal symmetries. However, the combined presence of spinorbit coupling and magnetic field breaks these symmetries [1] and can lead to a finite supercurrent even when the phase difference is zero [2,3]. This is the so called anomalous Josephson effectthe hallmark effect of superconducting spintronics -and can be characterized by the corresponding anomalous phase shift (φ 0 ) [4,5]. We report the observation of a tunable anomalous Josephson effect in InAs/Al Josephson junctions measured via a superconducting quantum interference device (SQUID). By gate controlling the density of InAs we are able to tune the spin-orbit coupling of the Josephson junction by more than one order of magnitude. This gives us the ability to tune φ 0 , and opens several new opportunities for superconducting spintronics [6], and new possibilities for realizing and characterizing topological superconductivity [7][8][9].Superconductivity and magnetism have long been two of the main focuses of condensed matter physics. Interfacing materials with these two opposed types of electron order can serve as a platform to host many new phenomena. Recently these systems have drawn renewed theoretical and experimental attention in the context of superconducting spintronics [6] and in the search for Majorana fermions [10][11][12][13]. Novel heterostructures can provide the ingredients that are typically needed: superconducting pairing, breaking of time reversal symmetry, and strong spin-orbit coupling.A basic property of superconducting systems is that we can introduce a relation between charge current and the superconductor's phase. In the canonical example of a Josephson junction (JJ), this is the current-phase relationship (CPR), where φ is the phase difference between the two superconductors. Systems with nontrivial spin texture generally introduce a relationship between charge and spin. In the case of spin-orbit coupling this can manifest in many ways including the spin Hall effect and topological edge states [14].A hybrid system, combining spin-orbit coupling and superconductivity, results in a much richer physics where phase, charge current and spin are all interdependent. This gives rise to new phenomena such as an anomalous phase shift which is the hallmark effect of superconduct-ing spintronics [6]. In a standard JJ, the CPR always satisfies the condition I(φ = 0) = 0. This condition is protected by parity and time-reversal symmetries. However the presence of spin-orbit coupling along with the application of an in-plane magnetic field can break these symmetries [1]. This allows an anomalous phase (φ 0 ), which means that with no current flowing there can be a non-zero phase across the junction or, conversely, at zero phase a current can flow. This is also understood in the context of the spin-galvanic effect, also known as the inverse Edelstein effect. It states that in a norm...

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Gate controlled anomalous phase shift in Al/InAs Josephson junctions

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“…1(b), we again find a finite phase shift which results from the singlet-triplet mixing of the doubly occupied QD states. When the spin-orbit vector Ω and the magnetic field are orthogonal, the system is invariant under a composition of time reversal and mirroring in the plane perpendicular to Ω, under which the superconducting phase goes to opposite itself; because the energy must be invariant under this symmetry, there can be no terms that are odd in the superconducting phase difference in the Hamiltonian and thus no non-trivial phase offset [25,38]. However, unlike the ground state of the SC leads, the ground states of the TS leads transform nontrivially under the above transformations and we thus anticipate a nonzero phase shift.…”

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Detecting topological superconductivity with φ0 Josephson junctions

2017

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The interplay of superconductivity, magnetic fields, and spin-orbit interaction lies at the heart of topological superconductivity. Remarkably, the recent experimental discovery of ϕ0 Josephson junctions by Szombati et al. [1], characterized by a finite phase offset in the supercurrent, require the same ingredients as topological superconductors, which suggests a profound connection between these two distinct phenomena. Here, we theoretically show that a quantum dot ϕ0 Josephson junction can serve as a new qualitative indicator for topological superconductivity: Microscopically, we find that the phase shift in a junction of s−wave superconductors is due to the spin-orbit induced mixing of singly occupied states on the qantum dot, while for a topological superconductor junction it is due to singlet-triplet mixing. Because of this important difference, when the spin-orbit vector of the quantum dot and the external Zeeman field are orthogonal, the s-wave superconductors form a π Josephson junction while the topological superconductors have a finite offset ϕ0 by which topological superconductivity can be distinguished from conventional superconductivity. Our prediction can be immediately tested in nanowire systems currently used for Majorana fermion experiments and thus offers a new and realistic approach for detecting topological bound states. Non-abelian anyons are the building blocks of topological quantum computers [2]. The simplest realization of a non-abelian anyon are Majorana bound states (MBSs) in topological superconductors (TSs) [3]. It has been proposed that such a TS can be induced by an s-wave superconductor (SC) in systems of nanowires with spinorbit interaction (SOI) subject to a Zeeman field [4][5][6][7], in chains of magnetic atoms [8][9][10][11] and in topological insulators [12][13][14][15][16][17]. However, providing experimental evidence for the existence of this new phase of matter has remained a major challenge.Here we present a new qualitative indicator of MBS based on ϕ 0 Josephson junctions (ϕ 0 JJs). In ϕ 0 JJs the Josephson current is offset by a finite phase, ϕ 0 , so that a finite supercurrent flows even when the phase difference between the superconducting leads and the magnetic flux enclosed by the Josephson junction (JJ) vanishes. Such ϕ 0 JJs have been discussed in systems based on unconventional superconductors [18][19][20][21][22] [32,33]. Recently, the connection between ϕ 0 JJs based on nanowires and TSs has also been discussed [34]. Most relevant for the present work, the emergence of a ϕ 0 JJ was theoretically predicted [35][36][37] in a system of a quantum dot (QD) with SOI subject to a Zeeman field when coupled to s-wave superconducting leads and observed in recent experiments [1]. Interestingly, the ingredients for observing a ϕ 0 JJ in this type of system largely overlap with those required to generate MBSs. In this work, we focus on two models for ϕ 0 JJs based on QDs which, compared to previous studies [35][36][37], are in the singlet-triplet anticrossing regime. In the...

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“…The CPR in such ϕ junction J = J 0 sin(θ − ϕ) suggests that the current flows even at the zero phase difference [10][11][12]. Breaking time-reversal symmetry in X is a necessary condition to realize the ϕ junction.…”

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confidence: 99%

Tunable- φ Josephson junction with a quantum anomalous Hall insulator

2017

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We theoretically study the Josephson current in a superconductor/quantum anomalous Hall insulator/superconductor junction by using the lattice Green function technique. When an in-plane external Zeeman field is applied to the quantum anomalous Hall insulator, the Josephson current J flows without a phase difference across the junction θ . The phase shift ϕ appearing in the current-phase relationship J ∝ sin(θ − ϕ) is proportional to the amplitude of Zeeman fields and depends on the direction of Zeeman fields. A phenomenological analysis of the Andreev reflection processes explains the physical origin of ϕ. In a quantum anomalous Hall insulator, time-reversal symmetry and mirror-reflection symmetry are broken simultaneously. However, magnetic mirror-reflection symmetry is preserved. Such characteristic symmetry properties enable us to have a tunable ϕ junction with a quantum Hall insulator.

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Effects of spin-orbit coupling and spatial symmetries on the Josephson current in SNS junctions

Cited by 53 publications

References 30 publications

Gate controlled anomalous phase shift in Al/InAs Josephson junctions

Gate controlled anomalous phase shift in Al/InAs Josephson junctions

Detecting topological superconductivity with φ0 Josephson junctions

Tunable- φ Josephson junction with a quantum anomalous Hall insulator

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