Probability and (Braiding) Statistics in Majorana nanowires

TL;DR

This paper analyzes the expected experimental signals of Majorana braiding in nanowires, emphasizing the importance of distinguishing topological from trivial signatures to confirm non-Abelian anyonic statistics.

Contribution

It provides a detailed comparison of braiding and fusion experiment signals in topological and non-topological systems, highlighting the most reliable methods for identifying Majorana modes.

Findings

Full braiding experiments better distinguish topological from trivial signals.

Certain trivial signatures can mimic anyonic braiding, requiring careful interpretation.

Fusion experiments are less effective than full braids in confirming Majorana non-Abelian statistics.

Abstract

Given recent progress in the realization of Majorana zero modes in semiconducting nanowires with proximity-induced superconductivity, a crucial next step is to attempt an experimental demonstration of the predicted braiding statistics associated with the Majorana mode. Such a demonstration should, in principle, confirm that observed zero-bias anomalies are indeed indicative of the presence of anyonic Majorana zero modes. Moreover, such a demonstration would be a breakthrough at the level of fundamental physics: the first clear demonstration of a non-Abelian excitation. It is therefore important to clarify the expected signals of Majorana physics in the braiding context, and to differentiate these signals from those that might also arise in non-topological variants of the same system. A definitive and critical distinction between signals expected in topological (i.e. anyonic) and non-topological (i.e. trivial) situations is therefore essential for future progress in the field. In this manuscript, we carefully examine the expected signals of braiding and fusion experiments in topological and non-topological variants of the experimental nanowire systems in which Majoranas are predicted to occur. We point out situations where `trivial' and `anyonic' signatures may be similar experimentally, necessitating a certain level of caution in the interpretation of various proposed fusion and braiding experiments. We find in particular that braiding experiments consisting of full braids (two Majorana exchanges) are better at distinguishing between topological and non-topological systems than fusion experiments or experiments with an odd number of Majorana exchanges.