Full proximity treatment of topological superconductors in Josephson-junction architectures

Setiawan, F.; Wu, Chien‐Te; Levin, K.

doi:10.1103/physrevb.99.174511

Cited by 29 publications

(13 citation statements)

References 87 publications

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“…Previous investigations 37,39,42 have shown the im- portance of properly tuning the chemical potential, magnetic field strength, and superconducting phase difference for driving the JJ into the TS state. However, the strong dependence of the TS state and the ground-state phase on the spin-orbit angle (θ so ), the magnetic field orientation (ϕ B ), and the supercurrent direction (θ c ), shown in Fig.…”

Section: B Effects Of Crystalline Anisotropymentioning

confidence: 99%

“…In a more general scenario, there are situations in which the topological transition occurs without the current having a local minimum. 39,100 Figure 2(a) reveals that the topological gap is sizable only on a reduced part of the topological region. The topological gap is crucial for ensuring the practical protection of the MBS.…”

Section: Topological Superconductivity In Phase-unbiased Josephson Ju...mentioning

confidence: 99%

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Anisotropic topological superconductivity in Josephson junctions

Pekerten,

Pakizer,

Hawn

et al. 2021

Preprint

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We investigate the effects of magnetic and crystalline anisotropies on the topological superconducting state of planar Josephson junctions (JJs). In junctions where only Rashba spin-orbit coupling (SOC) is present, the topological phase diagram is insensitive to the supercurrent direction, but exhibits a strong dependence on the magnetic field orientation. However, when both Rashba and Dresselhaus SOCs coexist, the topological phase diagram strongly depends on both the magnetic field and junction crystallographic orientations. We examine the impact of the magnetic and crystalline anisotropy on the current-phase relation (CPR), energy spectrum, and topological gap of phase-biased JJs, where the junction is connected in a loop and the superconducting phase difference is fixed by a loop-threading magnetic flux. The anisotropic CPR can be used to extract the ground-sate phase (i.e. the superconducting phase difference that minimizes the system free energy) behavior in phase-unbiased JJs with no magnetic flux. Under appropriate conditions, phase-unbiased JJs can self-tune into or out of the topological superconducting state by rotating the in-plane magnetic field. The magnetic field orientations at which topological transitions occur strongly depends on both the junction crystallographic orientation and the relative strength between Rashba and Dresselhaus SOCs. We find that for an optimal practical application, in which the junction exhibits topological superconductivity with a sizeable topological gap, a careful balancing of the magnetic field direction, the junction crystallographic orientation, and the relative strengths of the Rashba and Dresselhaus SOCs is required. We discuss the considerations that must be undertaken to achieve this balancing for various junction types and parameters.

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Section: B Effects Of Crystalline Anisotropymentioning

confidence: 99%

Section: Topological Superconductivity In Phase-unbiased Josephson Ju...mentioning

confidence: 99%

Anisotropic topological superconductivity in Josephson junctions

Pekerten,

Pakizer,

Hawn

et al. 2021

Preprint

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“…Current strategies explore the manipulation of Majorana zero modes (MZMs) in devices which rely on 1-D topological superconductivity [16][17][18][19] induced by the proximity effect in topological insulators or semiconductors with strong spin-orbit coupling, or via planar Josephson Junctions 20,21 . However, MZMs may be corrupted by non-topological low energy Andreev bound states (ABS) 22 , which can be present as a result of details of interfaces and materials properties in such systems 23 . Here we report the fragility of surface ABS in superfluid 3 He at an ideal non-transparent interface, exploiting the ability to tune in situ the scattering of quasiparticles by the surface through adjustment of the isotopic composition of the helium surface boundary layer.…”

mentioning

confidence: 99%

Fragility of surface states in topological superfluid 3He

et al. 2021

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Superfluid 3He, with unconventional spin-triplet p-wave pairing, provides a model system for topological superconductors, which have attracted significant interest through potential applications in topologically protected quantum computing. In topological insulators and quantum Hall systems, the surface/edge states, arising from bulk-surface correspondence and the momentum space topology of the band structure, are robust. Here we demonstrate that in topological superfluids and superconductors the surface Andreev bound states, which depend on the momentum space topology of the emergent order parameter, are fragile with respect to the details of surface scattering. We confine superfluid 3He within a cavity of height D comparable to the Cooper pair diameter ξ0. We precisely determine the superfluid transition temperature Tc and the suppression of the superfluid energy gap, for different scattering conditions tuned in situ, and compare to the predictions of quasiclassical theory. We discover that surface magnetic scattering leads to unexpectedly large suppression of Tc, corresponding to an increased density of low energy bound states.

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“…Furthermore, it has also been shown that the presence of critical current minima may not necessarily be associated to transitions between the trivial and TS states [45] and a further analysis of magnetic and crystalline anisotropies of the TS state [46,47] may be needed to better understand the physical origin of the critical current minima [36]. In spite of the challenges, planar JJs continue to attract attention due to their experimental feasibility, versatility, and enhanced region of system parameters supporting the TS state [41,[46][47][48][49][50][51][52][53][54][55][56][57][58][59][60].…”

mentioning

confidence: 99%

“…Therefore, although in some cases the ground-state phase jumps appear to occur at the same Zeeman energy at which the critical current minima occur, this is, in general, not necessarily true. Further, the existence of ground-state jumps may not even be accompanied by critical current minima (nor vice versa), especially for junctions with narrow S regions [49]. In such cases, the existence of current minima does not necessarily represent a signature of topological phase transition.…”

mentioning

confidence: 99%

Signatures of Topological Transitions in the Spin Susceptibility of Josephson Junctions

Pakizer,

Matos-Abiague

2021

Preprint

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We theoretically investigate how the spin susceptibility of a planar Josephson junction is affected when the system transits into the topological superconducting state. We show that the magnetic flux and magnetic field dependence of the spin susceptibility closely maps the phase diagram of the system. In the absence of an external magnetic flux the system can self-tune into the topological superconducting state by minimizing its free energy. Self-tuned topological transitions are accompanied by sharp peaks in the spin susceptibility, which can therefore be use as measurable fingerprints for detecting the topological superconducting state. Away from the peaks, the amplitude of the spin susceptibility can provide qualitative information about the relative size of the topological gap. The signatures in the spin susceptibility are robust, even in junctions with narrow superconducting leads, where critical current minima may no longer serve as an indication of topological phase transitions. Numerical simulations are complemented with simplified analytical models capable of capturing the main features predicted for the spin susceptibility behavior. The predicted results could be particularly relevant for future experiments on realization and detection of the topological superconducting state in planar Josephson junctions.

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Full proximity treatment of topological superconductors in Josephson-junction architectures

Cited by 29 publications

References 87 publications

Anisotropic topological superconductivity in Josephson junctions

Anisotropic topological superconductivity in Josephson junctions

Fragility of surface states in topological superfluid 3He

Signatures of Topological Transitions in the Spin Susceptibility of Josephson Junctions

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