Fractional Gaussian forms and gauge theory: an overview

Abstract

Fractional Gaussian fields are scalar-valued random functions or generalized functions on an n-dimensional manifold M, indexed by a parameter s. They include white noise (s = 0), Brownian motion (s=1, n=1), the 2D Gaussian free field (s = 1, n=2) and the membrane model (s = 2). These simple objects are ubiquitous in math and science, and can be used as a starting point for constructing non-Gaussian theories. The differential form analogs of these objects are equally natural: for example, instead of considering an instance h(x) of the GFF on R2, one might write h1(x)dx1 + h2(x) dx2 where h1 and h2 are independent GFF instances. In general, given k ∈ \0,1,…,n\, an instance of the fractional Gaussian k-form with parameter s ∈ R (abbreviated FGFsk(M)) is given by (-)-s2 Wk, where Wk is a k-form-valued white noise. We write FGFsk(M)d=0 and FGFsk(M)d*=0 for the L2 orthogonal projections of FGFsk(M) onto the space of k-forms on which d (resp.\ d*) vanishes. We explain how FGFsk(M) and its projections transform under d and d*, as well as wedge/Hodge-star operators, subspace restrictions, and axial projections. We discuss how the 1-form FGF11(M) and its gauge-fixed projection FGF11(M)d*=0 are related to gauge theories, and we formulate several conjectures and open problems about scaling limits, including possible off-critical/non-Gaussian limits, whose construction in the Yang-Mills setting is a famous open problem.