Critical Phenomena on the Bethe Lattice

Abstract

We investigate the critical behavior of a family of Z2-symmetric scalar field theories on the Bethe lattice (the tree limit of regular hyperbolic tessellations) using both the non-perturbative Functional Renormalization Group and lattice perturbation theory. The family is indexed by the parameter ζ ∈ (0,1], which determines the range of the theory via the kinetic term constructed from the graph Laplacian raised to the power ζ. Specifically, ζ=1 is the short-range theory, while 0<ζ<1 defines the long-range model. Due to the hyperbolic nature of Bethe lattices, the Laplacian lacks a zero mode and exhibits a spectral gap. We find that upon closing this spectral gap by a modification of the Laplacian, the scalar field theories exhibit novel critical behavior in the form of non-trivial fixed points with critical exponents governed by ζ and the spectral dimension ds=3. In particular, our analysis indicates the presence of a Wilson-Fisher fixed point for the short range ζ =1 theory. In contrast, the nearest-neighbor Ising model on the Bethe lattice is known to exhibit mean-field critical exponents. To the best of our knowledge, this work provides the first evidence that a scalar φ4 theory and the discrete Ising model on the same underlying lattice may lie in distinct universality classes.