Hyperuniformity at the Absorbing State Transition: Perturbative RG for Random Organization

Abstract

Hyperuniformity, where the static structure factor obeys S(q) q with > 0, emerges at criticality in systems having multiple, symmetry-unrelated, absorbing states. Important examples arise in periodically sheared suspensions and amorphous solids; these lie in the random organisation (RO) universality class, for which analytic results for are lacking. Here, using Doi-Peliti field theory and perturbative RG about a Gaussian model, we find = 0+ and = 2ε/9 + O(ε2) in dimension d>dc=4 and d=4-ε respectively. Our calculations assume that renormalizability is sustained via a certain pattern of cancellation of strongly divergent terms. These cancellations allow the upper critical dimension to remain dc = 4, as is known for RO, while generic perturbations (e.g., those violating particle conservation) would typically flow to a fixed point with dc=6. The assumed cancellation pattern is closely reminiscent of a long-established one near the tricritical Ising fixed point. (This has dc=3, although generic perturbations flow towards the Wilson-Fisher fixed point with dc = 4.) We show how hyperuniformity in RO emerges from anticorrelation of strongly fluctuating active and passive densities. Our calculations also yield the remaining exponents to order ε, surprisingly without recourse to functional RG. These exponents coincide as expected with the Conserved Directed Percolation (C-DP) class which also contains the Manna Model and the quenched Edwards-Wilkinson (q-EW) model. Importantly however, our differs from one found via a mapping to q-EW. That mapping neglects a conserved noise in the RO action, which we argue to be dangerously irrelevant. Thus, although other exponents are common to both, the RO and C-DP universality classes have different exponents for hyperuniformity.