Distinguishing topological Majorana bound states from trivial Andreev bound states: Proposed tests through differential tunneling conductance spectroscopy

Abstract Majorana bound states (MBS) and Andreev bound states (ABS) in realistic Majorana nanowires setups have similar experimental signatures which make them hard to distinguishing one from the other. Here, we characterize the continuous Majorana/Andreev crossover interpolating between fully-separated, partially-separated, and fully-overlapping Majorana modes, in terms of global and local topological invariants, fermion parity, quasiparticle densities, Majorana pseudospin and spin polarizations, density overlaps and transition probabilities between opposite Majorana components. We found that in inhomogeneous wires, the transition between fully-overlapping trivial ABS and nontrivial MBS does not necessarily mandate the closing of the bulk gap of quasiparticle excitations, but a simple parity crossing of partially-separated Majorana modes (ps-MM) from trivial to nontrivial regimes. We demonstrate that fully-separated and fully-overlapping Majorana modes correspond to the two limiting cases at the opposite sides of a continuous crossover: the only distinction between the two can be obtained by estimating the degree of separations of the Majorana components. This result does not contradict the bulk-edge correspondence: Indeed, the field inhomogeneities driving the Majorana/Andreev crossover have a length scale comparable with the nanowire length, and therefore correspond to a nonlocal perturbation which breaks the topological protection of the MBS.

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Spatial Rabi oscillations between Majorana bound states and quantum dots

Beilstein Journal of Nanotechnology ◽

10.3762/bjnano.9.143 ◽

2018 ◽

Vol 9 ◽

pp. 1527-1535

Author(s):

Jun-Hui Zheng ◽

Dao-Xin Yao ◽

Zhi Wang

Keyword(s):

Quantum Dot ◽

Bound States ◽

Bound State ◽

Double Quantum ◽

Energy Splitting ◽

Rabi Oscillations ◽

Andreev Bound States ◽

Majorana Bound States ◽

Nonlocal Quantum ◽

Equal Amplitude

Background: A Majorana bound state is a superconducting quasiparticle that is the superposition of particle and hole with equal amplitude. We propose a verification of this amplitude equality by analyzing the spatial Rabi oscillations of the quantum states of a quantum dot that is tunneling-coupled to the Majorana bound states. Results: We find two resonant Rabi driving energies that correspond to the energy splitting due to the coupling of two spatially separated Majorana bound states. The resulting Rabi oscillating frequencies from these two different resonant driving energies are identical for the Majorana bound states, while different for ordinary Andreev bound states. We further study a double-quantum-dot setup and find a nonlocal quantum correlation between them that is mediated by two Majorana bound states. This nonlocal correlation has the signature of additional resonant driving energies. Conclusion: Our method can be used to distinguish between Majorana bound states and Andreev bound states. It also gives a precise measurement of the energy splitting between two Majorana bound states.

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Andreev bound states versus Majorana bound states in quantum dot-nanowire-superconductor hybrid structures: Trivial versus topological zero-bias conductance peaks

Physical Review B ◽

10.1103/physrevb.96.075161 ◽

2017 ◽

Vol 96 (7) ◽

Cited By ~ 144

Author(s):

Chun-Xiao Liu ◽

Jay D. Sau ◽

Tudor D. Stanescu ◽

S. Das Sarma

Keyword(s):

Quantum Dot ◽

Bound States ◽

Hybrid Structures ◽

Zero Bias ◽

Andreev Bound States ◽

Majorana Bound States ◽

Zero Bias Conductance

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Suppressed Andreev reflection and helical Andreev bound states in triplet superconductor three-dimensional topological insulator

International Journal of Modern Physics B ◽

10.1142/s0217979215500186 ◽

2015 ◽

Vol 29 (04) ◽

pp. 1550018 ◽

Cited By ~ 1

Author(s):

M. Khezerlou ◽

H. Goudarzi

Keyword(s):

Topological Insulator ◽

Bound States ◽

Andreev Reflection ◽

Chemical Potential ◽

Three Dimensional ◽

P Wave ◽

Superconducting Gap ◽

Tunneling Conductance ◽

Andreev Bound States ◽

Josephson Supercurrent

Effect of proximity-induced unconventional p-wave superconductivity in a three-dimensional topological insulator-based S/F/S structure on the Andreev bound states (ABSs) and Josephson supercurrent is studied. We investigate, in detail, the suppression of Andreev reflection and helical ABSs in the presence of three types of triplet superconducting gap. The magnetization of ferromagnetic section is perpendicular to the surface of junction. The influence of such features on the supercurrent flow on the surface of the topological insulator is studied. We carry out our goal by introducing a relevant form of Dirac spinors for gapless renormalized by chemical potential μ excitation states. Therefore, it enables us to consider the virtual Andreev process, simultaneously, and we propose to investigate it in a tunneling conductance junction. It is shown that the results obtained in this case are completely different from those in conventional superconductivity, as s- or d-waves, for example, the magnetization is found to decrease the gap for px and px+ipy case, whereas increase it for py order. Strongly suppressed Andreev reflection is demonstrated.

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Conductance asymmetries in mesoscopic superconducting devices due to finite bias

SciPost Physics ◽

10.21468/scipostphys.10.2.037 ◽

2021 ◽

Vol 10 (2) ◽

Author(s):

André Melo ◽

Chun-Xiao Liu ◽

Piotr Rożek ◽

Tómas Örn Rosdahl ◽

Michael Wimmer

Keyword(s):

Bound States ◽

Voltage Dependence ◽

Superconducting Devices ◽

Scattering Matrix ◽

Tunnel Barrier ◽

Tunneling Conductance ◽

Physical Origin ◽

Andreev Bound States ◽

Superconducting Device ◽

Symmetry Relations

Tunneling conductance spectroscopy in normal metal-superconductor junctions is an important tool for probing Andreev bound states in mesoscopic superconducting devices, such as Majorana nanowires. In an ideal superconducting device, the subgap conductance obeys specific symmetry relations, due to particle-hole symmetry and unitarity of the scattering matrix. However, experimental data often exhibits deviations from these symmetries or even their explicit breakdown. In this work, we identify a mechanism that leads to conductance asymmetries without quasiparticle poisoning. In particular, we investigate the effects of finite bias and include the voltage dependence in the tunnel barrier transparency, finding significant conductance asymmetries for realistic device parameters. It is important to identify the physical origin of conductance asymmetries: in contrast to other possible mechanisms such as quasiparticle poisoning, finite-bias effects are not detrimental to the performance of a topological qubit. To that end we identify features that can be used to experimentally determine whether finite-bias effects are the source of conductance asymmetries.

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