Layer-Contrasted Hall Effect in Twisted Bilayers with Time Reversal Symmetry

We discover a layer-contrasted charge Hall effect in chiral bilayers with time reversal symmetry. The restriction by Onsager relation on having linear Hall response in individual layers is lifted by layer hybridization of electronic states in the chiral structures, allowing opposite Hall voltages to develop in opposite layers. This effect also amounts to a layer Hall effect, namely the Hall transport of layer pseudospin that carries charge dipole, and the underlying band geometric quantity is the momentum-space vorticity of the layer current. We demonstrate the effect in twisted bilayer graphene and twisted homobilayer transition metal dichalcogenides with a wide rage of twist angles, which exhibits giant Hall ratios under experimentally practical conditions, with gate voltage controlled on-off switch. This work reveals novel Hall physics in chiral structures, and opens up a new direction of layertronics that exploits the quantum nature of layer degree of freedom to uncover exciting effects.