RG flows on Sd and Hamiltonian truncation

Abstract

We describe a nonperturbative method to compute the partition function and correlation functions for scalar QFTs set on the d-dimensional sphere Sd. The method relies on a Hamiltonian picture, where the theory is quantized on Sd-1 and states evolve in time by means of a time-dependent Hamiltonian. Crucially, the Hilbert space on Sd-1 is truncated to a finite set of states below a cutoff. Throughout this work we focus on the φ2 and iφ3 flows in three dimensions. In the first part of this paper we analyze the cutoff-dependence of various observables, computing both divergent and RG-improvement counterterms to be added to the action. Next we present nonperturbative results for the massive scalar on S3, finding good agreement in the strong-coupling regime between numerical data and the F-coefficient of the free scalar CFT. We also check that the renormalized i φ3 theory on S3 is nonperturbatively UV-finite. The scheme in question breaks the SO(d+1) spacetime symmetry group of Sd down to SO(d), and in an example we study how the full symmetry is restored in the continuum limit. The relation between our method and earlier work by Al. B. Zamolodchikov involving a specific RG flow on S2 is explained as well.