Quantum critical magneto-transport at a continuous metal-insulator transition

Abstract

In contrast to the seminal weak localization prediction of a non-critical Hall constant (RH) at the Anderson metal-insulator transition (MIT), RH in quite a few real disordered systems exhibits both, a strong T-dependence and critical scaling near their MIT. Here, we investigate these issues in detail within a non-perturbative "strong localization" regime using cluster-dynamical mean field theory (CDMFT). We uncover (i) clear and unconventional quantum-critical scaling of the γ-function, finding that γ(gxy) log(gxy) over a wide range spanning the continuous MIT, very similar to that seen for the longitudinal conductivity, (ii) strongly T-dependent and clear quantum critical scaling in both transverse conductivity and RH at the MIT. We find that these surprising results are in comprehensive and very good accord with signatures of a novel kind of localization in disordered NbN near the MIT, providing substantial support for our "strong" localization view.