Critical behavior of QED3--Gross-Neveu-Yukawa Theory in an Arbitrary Gauge

Abstract

The chiral QED3--Gross-Neveu-Yukawa (QED3-GNY) theory is a 2+1-dimensional U(1) gauge theory with Nf flavors of four-component Dirac fermions coupled to a scalar field. For Nf=1, the specific chiral Ising QED3-GNY model has recently been conjectured to be dual to the deconfined quantum critical point that describes Neel--valence-bond-solid transition of frustrated quantum magnets on square lattice. We study the universal critical behaviors of the chiral QED3-GNY model in d=4-ε dimensions for an arbitrary Nf . We calculate the boson anomalous dimensions, inverse correlation length exponent, as well as the scaling dimensions of nonsinglet fermion bilinear in the chiral QED3-GNY model. The Pade estimates for the exponents are obtained in the chiral Ising-, XY- and Heisenberg-QED3-GNY universality class respectively. We also establish the general condition of the supersymmetric criticality for the ungauged QED3-GNY model. For the conjectured duality between chiral QED3-GNY critical point and deconfined quantum critical point, we find the inverse correlation length exponent has a lower boundary -1>0.75, beyond which the Ising-QED3-GNY--CP1 duality may hold.