A fermionic approach to tunneling through junctions of multiple quantum wires

TL;DR

This paper introduces a fermionic approach using the S-matrix and RG techniques to analyze tunneling in junctions of multiple quantum wires, extending previous methods to infinite leads and aligning with existing results.

Contribution

It reformulates the perturbative RG approach in terms of the S-matrix and extends it to infinite leads, unifying different junction configurations.

Findings

Results agree with bosonization and DMRG for 2- and 3-lead junctions.

Extended method applies to infinite-length interacting leads.

Provides a unified fermionic framework for quantum wire junctions.

Abstract

Junctions of multiple one-dimensional quantum wires of interacting electrons have received considerable theoretical attention as a basic constituent of quantum circuits. While results have been obtained on these models using bosonization and Density Matrix Renormalization Group (DMRG) methods, another powerful technique is based on direct perturbation theory in the bulk interactions, combined with the Renormalization Group (RG) and summed in the Random Phase Approximation (RPA). This technique has so far only been applied to the case where finite length interacting wires are attached to non-interacting Fermi liquid leads. We reformulate it in terms of the single-particle S-matrix, formally unifying treatments of junctions of different numbers of leads, and extend this method to cover the case of infinite length interacting leads obtaining results on 2-lead and 3-lead junctions in good agreement with previous bosonization and DMRG results.