2D Fractons from Gauging Exponential Symmetries

The scope of quantum field theory is extended by introducing a broader class of discrete gauge theories with fracton behavior in 2+1D. We consider translation invariant systems that carry special charge conservation laws, which we refer to as \text{exponential polynomial symmetries}. Upon gauging these symmetries, the resulting $\mathbb{Z}_N$ gauge theories exhibit fractonic physics, including constrained mobility of quasiparticles and UV dependence of the ground state degeneracy. For appropriate values of theory parameters, we find a family of models whose excitations, albeit being deconfined, can only move in the form of bound states rather than isolated monopoles. For concreteness, we study in detail the low-energy physics and topological sectors of a particular model through a universal protocol, developed for determining the holonomies of a given theory. We find that a single excitation, isolated in a region of characteristic size $R$, can only move from its original position through the action of operators with support on $\mathcal{O}(R)$ sites. Furthermore, we propose a Chern-Simons variant of these gauge theories, yielding non-CSS type stabilizer codes, and propose the exploration of exponentially symmetric subsystem SPTs and fracton codes in 3+1D.