Midgap edge states and pairing symmetry of quasi-one-dimensional organic superconductors

Sengupta, K.; Žutić, Igor; Kwon, H. Dharma; Yakovenko, Victor M.; Sarma, S. Das

doi:10.1103/physrevb.63.144531

Cited by 322 publications

(346 citation statements)

References 45 publications

(42 reference statements)

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“…This problem can be solved exactly for certain special cases of the interpolating gap profiles. 50,52 For example, a kink profile with ∆(y) = ∆[cos l(θ − π/2) − i tanh(y) sin l(θ − π/2)] yields the bound-state spectrum…”

Section: A Edge Modes In Chiral Superconductorsmentioning

confidence: 99%

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Paired chiral spin liquid with a Fermi surface inS=1model on the triangular lattice

et al. 2012

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Motivated by recent experiments on Ba3NiSb2O9, we investigate possible quantum spin liquid ground states for spin S = 1 Heisenberg models on the triangular lattice. We use Variational Monte Carlo techniques to calculate the energies of microscopic spin liquid wave functions where spin is represented by three flavors of fermionic spinon operators. These energies are compared with the energies of various competing three-sublattice ordered states. Our approach shows that the antiferromagnetic Heisenberg model with biquadratic term and single-ion anisotropy does not have a low-temperature spin liquid phase. However, for an SU (3)-invariant model with sufficiently strong ring-exchange terms, we find a paired chiral quantum spin liquid with a Fermi surface of deconfined spinons that is stable against all types of ordering patterns we considered. We discuss the physics of this exotic spin liquid state in relation with the recent experiment and suggest new ways to test this scenario.

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Section: A Edge Modes In Chiral Superconductorsmentioning

confidence: 99%

“…49,50 For simplicity, let us choose a bulk potential of the form ∆(k) = ∆e ilθ(k) where l ∈ Z is the winding of the phase of the order parameter around the Fermi surface, and cos θ(k) = k x /|k|. A scattering state with incident angle θ results in an outgoing angle θ ′ = π − θ.…”

Section: A Edge Modes In Chiral Superconductorsmentioning

confidence: 99%

Paired chiral spin liquid with a Fermi surface inS=1model on the triangular lattice

et al. 2012

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“…Since at D = 0 the Josephson junction consists of two semiinfinite uncoupled p x -wave superconductors, ψ L0 and ψ R0 are the wave functions of the surface midgap states [7] belonging to the left and right superconductor. Let us examine the properties of the midgap states.…”

Section: Tunneling Hamiltonian Approachmentioning

confidence: 99%

“…[5] and discovered experimentally as a zero-bias conductance peak in tunneling between normal metals and superconductors (see review [6]). For the Q1D organic superconductors, the midgap states were theoretically predicted to exist at the edges perpendicular to the chains [7,8]. When two unconventional superconductors are joined together in a Josephson junction, their Andreev surface states hybridize to form Andreev bound states in the junction.…”

Section: Introductionmentioning

confidence: 99%

Theoretical prediction of the fractional ac Josephson effect in p- and d-wave superconductors

Kwon¹,

Sengupta²,

Yakovenko³

2003

Braz. J. Phys.

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For certain orientations of Josephson junctions between two p x -wave or two d-wave superconductors, the subgap Andreev states produce a 4π-periodic relation between the Josephson current I and the phase difference φ: I ∝ sin(φ/2). Consequently, the ac Josephson current has the fractional frequency eV / , where V is the dc voltage. In the tunneling limit, the Josephson current is proportional to the first power (not square) of the electron tunneling amplitude. Thus, the Josephson current is carried by single electrons, rather than by Cooper pairs.

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“…The semiconductor Majorana wire -the 1D version [15][16][17] of the semiconductorsuperconductor (SM-SC) heterostructure -represents a direct physical realization of the one-dimensional Kitaev model [5]. The observation of a sharp zero bias conductance peak (ZBP) in charge tunneling measurement has been proposed [15,[18][19][20][21][22] as a possible detection scheme for MFs localized near the ends of Majorana nanowires. The 1D SM-SC heterostructure and the associated ZBP measurements have recently attracted considerable experimental effort [23][24][25][26][27][28][29][30].…”

mentioning

confidence: 99%

Nonlocality of zero-bias anomalies in the topologically trivial phase of Majorana wires

Stãnescu

Tewari

2014

Phys. Rev. B

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We show that the topologically trivial zero bias peak (ZBP) emerging in semiconductor Majorana wires due to soft confinement exhibits correlated splitting oscillations as a function of the applied Zeeman field, similar to the correlated splitting of the Majorana ZBP. Also, we find that the presence of a strong impurity can effectively cut the wire in two and destroy the correlated splitting in both the trivial and the Majorana regimes. We identify a strong nonlocal effect that operates only in the topologically trivial regime and demonstrate that the dependence of the ZBP on the confining gate potential at the opposite end in Majorana wires with two normal metal endcontacts represents a powerful tool for discriminating between topologically trivial and nontrivial ZBPs.First predicted in the context of high energy physics, Majorana fermions (MF) [1] have come under renewed focus in low-temperature condensed matter physics [1-3] as zeroenergy bound states endowed with non-Abelian statistics [4], hence, potential suitable candidates for fault-tolerant quantum computation [5,6]. Proposals for realizing MFs in lowtemperature systems are based on fractional quantum Hall systems [4,7], chiral p-wave superconductors/superfluids [7,8], heterostructures of topological insulators and superconductors [9], and cold fermion systems [10,11]. The recently proposed scheme based on spin-orbit coupled semiconductor thin films [12][13][14][15] and nanowires [15][16][17] with Zeeman splitting and proximity induced s-wave superconductivity involves only conventional ingredients. The semiconductor Majorana wire -the 1D version [15][16][17] of the semiconductorsuperconductor (SM-SC) heterostructure -represents a direct physical realization of the one-dimensional Kitaev model [5]. The observation of a sharp zero bias conductance peak (ZBP) in charge tunneling measurement has been proposed [15,[18][19][20][21][22] as a possible detection scheme for MFs localized near the ends of Majorana nanowires. The 1D SM-SC heterostructure and the associated ZBP measurements have recently attracted considerable experimental effort [23][24][25][26][27][28][29][30].Despite significant progress, the actual observation of MFs in SM nanowires is still under debate, as signatures similar to the Majorana-induced ZBPs are predicted to occur even in the topologically trivial phase in the presence of smooth confining potentials [31], or strong disorder [32]. On the other hand, due to the overlap of the wave functions localized near the opposite ends, the Majorana ZBP is characterized by splitting oscillations as a function of the Zeeman field or the chemical potential. The ZBPs measured at the opposite ends of a clean wire should be characterized by the same splitting oscillations (correlated splitting), since they involve the same wave function overlap. The direct observation of correlated splitting has been recently proposed [33] as a tool for identifying Majorana-induced ZBPs.In this Rapid Communication we show that topologically trivial ZBPs emerging in SM...

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Midgap edge states and pairing symmetry of quasi-one-dimensional organic superconductors

Cited by 322 publications

References 45 publications

Paired chiral spin liquid with a Fermi surface inS=1model on the triangular lattice

Paired chiral spin liquid with a Fermi surface inS=1model on the triangular lattice

Theoretical prediction of the fractional ac Josephson effect in p- and d-wave superconductors

Nonlocality of zero-bias anomalies in the topologically trivial phase of Majorana wires

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