Instanton-Induced Supersymmetry Breaking in Topological Semimetals

TL;DR

This paper demonstrates how instanton-induced supersymmetry breaking explains gap opening in topological semimetals, revealing that even minimal magnetic fields can induce gaps via SUSY mechanisms, offering a new theoretical perspective.

Contribution

It introduces a novel application of supersymmetric quantum mechanics to topological semimetals, linking instanton effects to gap formation and providing a simple criterion for gap opening.

Findings

Instanton effects cause dynamical SUSY breaking leading to gap opening.

A finite energy gap occurs if the SUSY potential has an even number of zeros.

Even infinitesimal magnetic fields can induce gaps in topological semimetals.

Abstract

Supersymmetry (SUSY) proposed as an elementary symmetry for physics beyond the Standard Model has found important applications in various areas outside high-energy physics. Here, we systematically implement supersymmetric quantum mechanics -- exhibiting fundamental SUSY properties in the simple setting of quantum mechanics -- into a wide range of topological semimetals, where the broken translational symmetry, e.g., by a magnetic field, is effectively captured by a SUSY potential. We show that the dynamical SUSY breaking via the instanton effect over the SUSY potential valleys works as the underlying mechanism for the gap opening of the topological semimetallic phases, and the magnitude of the instanton effect is proportional to the energy gap. This instanton mechanism provides a simple criterion for determining whether the energy gap has been opened, without resorting to detailed calculations, i.e., a finite energy gap is opened if and only if the SUSY potential has an even number of zeros. Our theory leads to previously unexpected results: even an infinitesimal magnetic field can open a gap in topologically robust Dirac, Weyl, and nodal-line semimetallic phases due to the dynamical SUSY breaking. Overall, the revealed connection between SUSY quantum mechanics and non-uniform topological semimetals can elucidate previously ambiguous phenomena, provide guidance for future investigations, and open a new avenue for exploring topological semimetals.