Exponential decay of mass for inertial coalescing particles with Hamiltonian noise

Abstract

We study a system of N inertial particles on a two-dimensional torus 2, evolving under a second-order stochastic dynamics with position-dependent friction λ and noise amplitude σ, and undergoing coalescence at rate R0 when their distance falls below a threshold δ. In the joint small-mass / small-correlation limit μ() 0, μ()/∈(0,∞), the empirical measure of the surviving particles converges to a stochastic continuity equation with inertial drift~g. Assuming that σ is tangent to the level sets of a Hamiltonian H=h1(x1)\,h2(x2) satisfying mild non-degeneracy and convexity-type conditions, and that λ and the amplitude ρ of σ along ξ=∇ H are aligned with H, we prove that the expected total mass decays exponentially in time, with an explicit rate depending on and on the values of λ and ρ on the separatrix \H=0\. The proof rests on a cell-by-cell analysis of the sign of ÷\,g on the level sets of H, showing that the inertial drift pushes trajectories toward the separatrix at a quantitative rate.