Giant number fluctuations in dry active polar fluids: A shocking analogy with lightning rods

Abstract

The hydrodynamic equations of dry active polar fluids (i.e., moving flocks without momentum conservation) are shown to imply giant number fluctuations. Specifically, the rms fluctuations <(δ N)2> of the number N of active particles in a region containing a mean number of active particles <N> scales according to the law <(δ N)2> = K'<N>φ(d) with φ(d)=710+15d in d4 spatial dimensions. This is much larger the "law of large numbers" scaling <(δ N)2> = K<N> found in most equilibrium and non-equilibrium systems. In further contrast to most other systems, the coefficient K' also depends singularly on the shape of the box in which one counts the particles, vanishing in the limit of very thin boxes. These fluctuations arise not from large density fluctuations - indeed, the density fluctuations in s are not in general particularly large - but from long ranged spatial correlations between those fluctuations. These are shown to be closely related in two spatial dimensions to the electrostatic potential near a sharp upward pointing conducting wedge of opening angle 3π8=67.5, and in three dimensions to the electrostatic potential near a sharp upward pointing charged cone of opening angle 37.16. This very precise prediction can be stringently tested by alternative box counting experiments that directly measure this density-density correlation function.