Random Riemannian Geometry in 4 Dimensions

Abstract

We construct and analyze conformally invariant random fields on 4-dimensional Riemannian manifolds (M,g). These centered Gaussian fields h, called co-biharmonic Gaussian fields, are characterized by their covariance kernels k defined as the integral kernel for the inverse of the Paneitz operator equation* p=18π2[2+ div(2Ric-23scal)∇ ]. equation* The kernel k is invariant (modulo additive corrections) under conformal transformations, and it exhibits a precise logarithmic divergence |k(x,y)-1d(x,y)| C. In terms of the co-biharmonic Gaussian field h, we define the quantum Liouville measure, a random measure on M, heuristically given as equation* dμ(x):= eγ h(x)-γ22k(x,x)\,d volg(x)\,, equation* and rigorously obtained a.s.~for |γ|<8 as weak limit of the RHS with h replaced by suitable regular approximations (h)∈ N. For the flat torus M= T4, we provide discrete approximations of the Gaussian field and of the Liouville measures in terms of semi-discrete random objects, based on Gaussian random variables on the discrete torus and piecewise constant functions in the isotropic Haar system.