Uncovering novel phase structures in k scalar theories with the renormalization group

Abstract

We present a detailed version of our recent work on the renormalization group approach to multicritical scalar theories with higher derivative kinetic term of the form φ(-)kφ and upper critical dimension dc = 2nk/(n-1). Depending on whether the numbers k and n have a common divisor two classes of theories have been distinguished which show qualitatively different features. For coprime k and n-1 the theory admits a Wilson-Fisher type fixed point with a marginal interaction φ2n. We derive in this case the renormalization group equations of the potential at the functional level and compute the scaling dimensions and some OPE coefficients, mostly at leading order in ε. While giving new results, the critical data we provide are compared, when possible, and accord with a recent alternative approach using the analytic structure of conformal blocks. Instead when k and n-1 have a common divisor we unveil a novel interacting structure at criticality. In this case the phase diagram is more involved as other operators come into play at the scale invariant point. 2 theories with odd n, which fall in this class, are analyzed in detail. Using the RG flows that are derived at quadratic level in the couplings it is shown that a derivative interaction is unavoidable at the critical point. In particular there is an infrared fixed point with a pure derivative interaction at which we compute the scaling dimensions. For the particular example of 2 theory in dc=6 we include some cubic corrections to the flow of the potential which enable us to compute some OPE coefficients as well.