Dynamical renormalization group for mode-coupling field theories with solenoidal constraint

TL;DR

This paper develops a renormalization group analysis for a mode-coupling field theory with a solenoidal constraint, relevant for biological systems like bird flocks, revealing new static and unchanged dynamical universality classes.

Contribution

It introduces a solenoidal Model G, addressing the complex coupling of density, velocity, and spin fields with a solenoidal constraint, and demonstrates its impact on static and dynamical universality classes.

Findings

The solenoidal constraint produces a new vertex mixing static and dynamical couplings.

The static universality class is modified by the constraint.

The dynamical universality class remains unchanged despite the constraint.

Abstract

The recent inflow of empirical data about the collective behaviour of strongly correlated biological systems has brought field theory and the renormalization group into the biophysical arena. Experiments on bird flocks and insect swarms show that social forces act on the particles' velocity through the generator of its rotations, namely the spin, indicating that mode-coupling field theories are necessary to reproduce the correct dynamical behaviour. Unfortunately, a theory for three coupled fields - density, velocity and spin - has a prohibitive degree of intricacy. A simplifying path consists in getting rid of density fluctuations by studying incompressible systems. This requires imposing a solenoidal constraint on the primary field, an unsolved problem even for equilibrium mode-coupling theories. Here, we perform an equilibrium dynamic renormalization group analysis of a mode-coupling field theory subject to a solenoidal constraint; using the classification of Halperin and Hohenberg, we can dub this case as a solenoidal Model G. We demonstrate that the constraint produces a new vertex that mixes static and dynamical coupling constants, and that this vertex is essential to grant the closure of the renormalization group structure and the consistency of dynamics with statics. Interestingly, although the solenoidal constraint leads to a modification of the static universality class, we find that it does not change the dynamical universality class, a result that seems to represent an exception to the general rule that dynamical universality classes are narrower than static ones. Our results constitute a solid stepping stone in the admittedly large chasm towards developing an off-equilibrium mode-coupling theory of biological groups.