Refraction Hall Effect

We introduce a new mechanism that produces a Hall-like response in time-reversal-invariant materials, driven entirely by geometric effects. Specifically, we demonstrate that a tilted potential interface causes electron wave packets to undergo a refraction-like deflection upon transmission through the barrier, leading to a finite transverse current and a corresponding Hall conductance. Our analytical framework captures the essential features of this refraction Hall effect, and the resulting Hall conductivity profile is corroborated by numerical simulations across different lattice models and device geometries. We further visualize our predicted effect through real-time wave packet dynamics, which reveals its purely geometric origin and the robustness of the transverse response. These findings establish a fundamentally distinct class of Hall-like transport phenomena in mesoscopic systems that preserve time-reversal symmetry.