An Additive-Noise Approximation to Keller-Segel-Dean-Kawasaki Dynamics: Small-Noise Results
Abstract
We study an additive-noise approximation to Keller-Segel-Dean-Kawasaki dynamics, which is proposed as an approximate model to the fluctuating hydrodynamics of chemotactically interacting particles around their mean-field limit. As such, the interaction potential is given by the Green's function associated to Poisson's equation, which is singular around the origin. Two parameters play a key r\ole in the approximation: the noise intensity which captures the amplitude of fluctuations (tending to zero as the effective system size tends to infinity) and the correlation length δ which represents the effective scale under consideration. Let δ()0 as 0. Under the relative scaling assumption 0(δ()-1)=0 we obtain analogues of law of large numbers and large deviation principles in irregular spaces of distributions using methods of singular stochastic partial differential equations. The same techniques also yield a central limit theorem under the relative scaling 01/2(δ()-1)=0. Assuming the more restrictive relative scaling 01/2δ-γ-2=0 for some γ∈(-1/2,0), we also obtain analogues of law of large numbers and large deviation principles in regular function spaces using a mixture of pathwise and probabilistic tools. We further describe consequences of these results relevant to applications of our approximation in studying continuum fluctuations of particle systems.
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