Localization beyond Dirac and Weyl fermions

Adesh Singh, Gargee Sharma

Published 2024-07-01Version 1

In condensed matter, limited symmetry constraints allow free fermionic excitations to exist beyond the conventional Weyl and Dirac electrons of high-energy physics. These excitations carry a higher pseudospin, providing a natural generalization to the Weyl fermion. How do electrons beyond the conventional Dirac and Weyl fermions localize under disorder? In this Letter, we solve the problem of localization of free fermionic excitations carrying an arbitrary pseudospin-s. We derive exact analytical expressions for fermionic wavefunctions, scattering time, renormalized velocity, Cooperon, and the magnetoconductivity. We discover that the gapless Cooperon mode solely depends on the pseudospin even when Fermi surface is composed of multiple pockets, leading to weak localization (antilocalization) behavior for even (odd) s. Remarkably, we find the localization correction to scale exponentially with s, i.e., faster moving electrons are strongly susceptible to disorder effects. This opens up intriguing possibility for Anderson localization and many-body localization in these materials.