Distinguishing between topological Majorana and trivial zero modes via transport and shot noise study in an altermagnet heterostructure

TL;DR

This paper proposes a theoretical method to distinguish topological Majorana zero modes from trivial zero modes in an altermagnet heterostructure using transport and shot noise measurements, providing clear experimental signatures.

Contribution

It introduces a novel heterostructure setup and identifies unique transport and shot noise signatures to differentiate topological and trivial zero modes.

Findings

Zero bias conductance peak quantized for MZMs

Shot noise is negative for MZMs and positive for AZMs at zero temperature

Signatures remain robust with extended hopping and SOC

Abstract

We theoretically investigate the transport and shot noise properties of a one-dimensional semiconducting nanowire with Rashba spin-orbit coupling~(SOC) placed in closed proximity to a bulk $s$-wave superconductor and an altermagnet with $d$-wave symmetry. Such heterostructure with vanishing net magnetization manifests itself as an alternative route to anchor Majorana zero modes~(MZMs) characterized by appropriate topological index~(winding number $W$). Interestingly, this system also hosts accidental zero modes~(AZMs) emerged with vanishing topological index indicating their non-topological nature. Furthermore, by incorporating three terminal setup, we explore the transport and shot noise signatures of these zero modes. At zero temperature, we obtain zero bias peak (ZBP) in differential conductance to be quantized with value $|W|\times 2 e^{2}/h$ for MZMs. On the other hand, AZMs exhibit non-quantized value at zero bias. Moreover, zero temperature shot noise manifests negative~(positive) value for MZMs~(AZMs) within the bulk gap. At finite temperature, shot noise exhibits negative value~(negative to positive transition) concerning MZMs~(AZMs). Thus, the obtained signatures clearly distinguish between the MZMs and non-topological AZMs. We extend our analysis by switching on the next to nearest neighbor hopping amplitude and SOC. Our conclusion remains unaffected for this case as well. Hence, our work paves the way to differentiate between emergent MZMs and AZMs in a semiconductor/ superconductor/ altermagnet heterostructure.