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

**Authors:** Chun-Xiao Liu, Jay D. Sau, Tudor D. Stanescu, and S. Das Sarma

arXiv: 1705.02035 · 2017-09-07

## TL;DR

This paper investigates the complex behavior of Andreev and Majorana bound states in quantum dot-nanowire-superconductor systems, highlighting the difficulty in distinguishing topological Majorana states from trivial bound states using conductance measurements.

## Contribution

It provides a theoretical analysis of ABS and MBS interplay, showing that zero-bias peaks can arise from trivial states and proposing methods to differentiate them from topological Majorana states.

## Key findings

- ABSs tend to coalesce into near-zero-energy states in non-topological regimes.
- Zero-bias conductance peaks can originate from trivial ABSs, mimicking Majorana signatures.
- Distinguishing topological MBSs requires additional criteria beyond conductance peaks.

## Abstract

Motivated by an important recent experiment [Deng et al., Science 354, 1557 (2016)], we theoretically consider the interplay between Andreev bound states(ABSs) and Majorana bound states(MBSs) in quantum dot-nanowire semiconductor systems with proximity-induced superconductivity(SC), spin-orbit coupling and Zeeman splitting. The dot induces ABSs in the SC nanowire which show complex behavior as a function of Zeeman splitting and chemical potential, and the specific question is whether two such ABSs can come together forming a topological MBS. We consider physical situations involving the dot being non-SC, SC, or partially SC. We find that the ABSs indeed tend to coalesce together producing near-zero-energy midgap states as Zeeman splitting and/or chemical potential are increased, but this mostly happens in the non-topological regime although there are situations where the ABSs could come together forming a topological MBS. The two scenarios(two ABSs forming a near-zero-energy non-topological ABS or a zero-energy topological MBS) are difficult to distinguish by tunneling conductance spectroscopy due to essentially the same signatures. Theoretically we distinguish them by knowing the critical Zeeman splitting for the topological quantum phase transition or by calculating the topological visibility. We find that the "sticking together" propensity of ABSs to produce a zero-energy midgap state is generic in class D systems, and by itself says nothing about the topological nature of the underlying SC nanowire. One must use caution in interpreting tunneling conductance measurements where the midgap sticking-together behavior of ABSs cannot be construed as definitive evidence for topological SC with non-Abelian MBSs. We also suggest some experimental techniques for distinguishing between trivial and topological ZBCPs.

## Full text

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## Figures

32 figures with captions in the complete paper: https://tomesphere.com/paper/1705.02035/full.md

## References

57 references — full list in the complete paper: https://tomesphere.com/paper/1705.02035/full.md

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Source: https://tomesphere.com/paper/1705.02035