Renormalization-Group Evolution and Nonperturbative Behavior of Chiral Gauge Theories with Fermions in Higher-Dimensional Representations

Abstract

We study the ultraviolet to infrared evolution and nonperturbative behavior of a simple set of asymptotically free chiral gauge theories with an SU(N) gauge group and an anomaly-free set of nSk copies of chiral fermions transforming as the symmetric rank-k tensor representation, Sk, and n A copies of fermions transforming according to the conjugate antisymmetric rank- tensor representation, A, of this group with k, \ 2. As part of our study, we prove a general theorem guaranteeing that a low-energy effective theory resulting from the dynamical breaking of an anomaly-free chiral gauge theory is also anomaly-free. We analyze the theories with k==2 in detail and show that there are only a finite number of these. Depending on the specific theory, the ultraviolet to infrared evolution may lead to a non-Abelian Coulomb phase, or may involve confinement with massless composite fermions, or fermion condensation with dynamical gauge and global symmetry breaking. We show that Sk Ak chiral gauge theories with k 3 are not asymptotically free. We also analyze theories with fermions in Sk and A representations of SU(N) with k and k, \ 2.