Magnetoresistance in the Extreme Quantum Limit: Field-Induced Crossover to the Unitarity Limit

TL;DR

This paper theoretically explores magnetoresistance in the extreme quantum limit, revealing a field-induced crossover in scattering behavior that leads to distinct linear and negative MR regimes, and proposes a universal relation for impurity density measurement.

Contribution

It uncovers a magnetic-field-induced crossover in scattering rates and MR behaviors in the EQL, providing new insights into quantum-classical correspondence and impurity density determination.

Findings

Linear transverse MR ($ ho_{xx} \\propto B$) in the EQL

Negative longitudinal MR ($ ho_{zz} \\propto B^{-2}$) in the EQL

Universal relation for impurity density in the unitarity limit

Abstract

We theoretically investigate magnetoresistance (MR) in the extreme quantum limit (EQL), where the kinetic energy becomes significantly smaller than the cyclotron energy, using the Kubo formula with Green's functions and the $T$-matrix approximation. We uncover a magnetic-field-induced crossover in the scattering rate: $1/\tau \propto B^2$ in the Born regime and $1/\tau \propto B^{-2}$ in the unitarity limit. This crossover gives rise to distinct MR behaviors in the EQL, characterized by linear transverse MR ($\rho_{xx} \propto B$) and negative longitudinal MR ($\rho_{zz} \propto B^{-2}$). This dichotomy implies insulating behavior when the magnetic field is perpendicular to the current, and metallic behavior when it is parallel. In the unitarity limit, we further derive a universal relation that enables direct experimental determination of the impurity density from $\rho_{xx}$ and $\rho_{xy}$. Our results establish a quantum--classical correspondence that remains valid even in the EQL, provided that the field dependences of the scattering rate and quantum corrections are properly incorporated.