Title: Quantum charge transport in two-dimensional narrow channels

Abstract: We consider the transport of spinless fermion charge carriers in a planar narrow rectangular geometry, with the larger dimension being periodic and the narrow one confined to a finite strip width, and ballistic flow in the larger dimension only. Our analysis is based on the formulation of an Effective Field Theory (EFT) for the system, which is appropriate for discussing universal phenomena. The EFT is constructed as a direct product of two known one-dimensional ones obtained both from the thermodynamic limit of the Calogero-Sutherland model. This lower dimensional EFT is known to be capable of describing a quantum hydrodynamical flow. The resulting two-dimensional EFT displays a ground state charge density that is constant along the large dimension and vanishes at the boundaries of the narrow one with the shape of a semi-circumference. This latter feature is a consequence of the specific harmonic confining potential in the narrow dimension considered. The charge transport is obtained by coupling the system to an external electromagnetic field that induces a global translation. The EFT incorporates quantum solitonic excitations along the direction of the flow and the two-dimensional electric current density shows a Poiseuille-like behavior, indicating the presence of non-dissipative quantum viscous effects in the direction transverse to the flow. These two are among the most interesting features while discussing and observing charge flow in nanoscopic structures of several types. We provide explicit expressions for the electric current intensity, DC resistivity and charge mobility in an example.