Growth estimates for Dyson-Schwinger equations

Abstract

Dyson-Schwinger equations are integral equations in quantum field theory that describe the Green functions of a theory and mirror the recursive decomposition of Feynman diagrams into subdiagrams. Taken as recursive equations, the Dyson-Schwinger equations describe perturbative quantum field theory. However, they also contain non-perturbative information. Using the Hopf algebra of Feynman graphs we will follow a sequence of reductions to convert the Dyson-Schwinger equations to the following system of differential equations, \[ γ1r(x) = Pr(x) - (sr)γ1r(x)2 + (Σj ∈ R|sj|γ1j(x)) x ∂x γ1r(x) \] where r ∈ R, R is the set of amplitudes of the theory which need renormalization, γ1r is the anomalous dimension associated to r, Pr(x) is a modified version of the function for the primitive skeletons contributing to r, and x is the coupling constant. Next, we approach the new system of differential equations as a system of recursive equations by expanding γ1r(x) = Σn ≥ 1γr1,n xn. We obtain the radius of convergence of Σ γr1,nxn/n! in terms of that of Σ Pr(n)xn/n!. In particular we show that a Lipatov bound for the growth of the primitives leads to a Lipatov bound for the whole theory. Finally, we make a few observations on the new system considered as differential equations.