Coupled-wire constructions use bosonization to analytically tackle the strong interactions
underlying fractional topological states of matter. We give an introduction to this technique …

We consider a system of weakly coupled Rashba nanowires in the strong spin-orbit
interaction (SOI) regime. The nanowires are arranged into two tunnel-coupled layers …

Fractionalized quasiparticles—anyons—bear a special role in present-day physics. At the
same time, they display properties of interest both foundational, with quantum numbers that …

We consider a setup consisting of two coupled sheets of bilayer graphene in the regime of
strong spin-orbit interaction, where electrostatic confinement is used to create an array of …

We consider a system consisting of two tunnel-coupled two-dimensional topological
insulators proximitized by a top and bottom superconductor with a phase difference of π …

Topological nonsymmorphic crystalline superconductivity (TNCS) is an intriguing phase of
matter, offering a platform to study the interplay between topology, superconductivity, and …

We construct a dual-bosonized description of a massless Majorana fermion in (2+ 1) d. In
contrast to Dirac fermions, for which a bosonized description can be constructed using a flux …

We introduce a model of interacting Majorana fermions that describes a superconducting
phase with a topological order characterized by the Fibonacci topological field theory. Our …

The construction of fractional quantum Hall (FQH) states from the two-dimensional array of
quantum wires provides a useful way to control strong interactions in microscopic models …

The coupled-wire construction provides a useful way to obtain microscopic Hamiltonians for
various two-dimensional topological phases, among which fractional quantum Hall states …