Universal scaling dimensions for highly irrelevant operators in the Local Potential Approximation

Abstract

We study d-dimensional scalar field theory in the Local Potential Approximation of the functional renormalization group. Sturm-Liouville methods allow the eigenoperator equation to be cast as a Schrodinger-type equation. Combining solutions in the large field limit with the Wentzel-Kramers-Brillouin approximation, we solve analytically for the scaling dimension dn of high dimension potential-type operators On() around a non-trivial fixed point. We find that dn = n(d-d) to leading order in n as n ∞, where d=12(d-2+η) is the scaling dimension of the field, , and determine the power-law growth of the subleading correction. For O(N) invariant scalar field theory, the scaling dimension is just double this, for all fixed N≥0 and additionally for N=-2,-4,… \,. These results are universal, independent of the choice of cutoff function which we keep general throughout, subject only to some weak constraints.