Non-invertible Symmetries in Weyl Fermions, and Applications to Fermion-Boundary Scattering Problem

Abstract

We construct a family of non-invertible topological defects in two-dimensional theories of n Weyl fermions. The construction relies on the existence of G-symmetric conformal boundary conditions for n Dirac fermions. Upon unfolding, these boundary conditions become topological defects D of n Weyl fermions that intertwine the two G-representations, and they are generically non-invertible. For G=U(1)n, we show that D is a duality defect associated with gauging a finite Abelian group Γ, and we give an explicit algorithm for determining Γ and its action on the fermions. We also show that the same finite-Abelian gauging description applies in certain restricted examples with non-Abelian G. By contrast, for certain non-Abelian symmetry structures, including the G=SU(2) symmetry appearing in the 1-5-7-8-9 problem, we prove that D cannot be realized as a duality defect for gauging any finite Abelian group. Finally, we explain how the duality-defect perspective gives a streamlined derivation of fermion scattering from a conformal boundary.