Differential current noise as an identifier of Andreev bound states that induce nearly quantized conductance plateaus

TL;DR

This paper proposes a differential current noise measurement method to distinguish trivial Andreev bound states from Majorana bound states in conductance experiments, aiding the identification of topological superconductivity.

Contribution

It introduces a novel noise-based protocol to differentiate ABS-induced conductance plateaus from MBS signatures in superconducting systems.

Findings

ABS-induced plateaus show a double-peak in noise at specific bias voltages

MBS-related noise exhibits a broad zero-bias dip below 2e^3/h

The protocol is applicable across various MBS candidate platforms

Abstract

Quantized conductance plateaus, a celebrated hallmark of Majorana bound states (MBSs) predicted a decade ago, have recently been observed with small deviations in iron-based superconductors and hybrid nanowires. Here, we demonstrate that nearly quantized conductance plateaus can also arise from trivial Andreev bound states (ABSs). To avoid ABS interruptions, we propose identifying ABS-induced quantized conductance plateaus by measuring the associated differential current noise $P$ versus bias voltage $V$. Specifically, for a quantized conductance plateau induced by one or multiple low-energy ABSs, the associated $P(V)$ curve exhibits a double-peak around zero bias, with the peak positions at $e|V|\approx 3k_B T$ (where $T$ is the temperature) and peak values larger than $2e^3/h$. These features greatly contrast those of an MBS or quasi-MBS, whose $P(V)$ curve displays a broad zero-bias dip and is consistently below $2e^3/h$. This protocol can be practically implemented in a variety of MBS candidate platforms using an electrode or STM tip as a probe.