The nonlocal attraction-repulsion transport equation with power kernels
Abstract
We study a nonlocal continuity equation on Rd in which a probability density is driven by the competition between attraction toward a prescribed background measure ω and self-repulsion among particles, governed respectively by the power-law kernels ψa(x) = |x|1+a and ψr(x) = |x|1+r with exponents a, r ∈ [0,1). We establish global Lagrangian well-posedness via a squared-radius regularization, obtaining uniform L∞ and moment bounds, Wn,∞ regularity, and uniqueness in the Lagrangian class. When the initial data is compactly supported and attraction dominates (a > r, or a = r with ω(Rd) > 1), we prove that the support remains uniformly bounded at all time; a counterexample shows this fails for a = r > 1. For the attractive-dominant nonquadratic range 0 ≤ r ≤ a < 1, we characterize zero-flux stationary states via a free-boundary problem involving a fractional Laplacian operator, reducing the stationarity condition to a fractional exterior Dirichlet problem. This characterization allow us to exhibit explicit examples of stationary measures in dimensions d ∈ \1,2,3\. Numerical particle simulations confirm agreement with the theoretical stationary profiles. Finally, we prove that every global solution with bounded energy and uniform moment bounds converges to a zero-flux stationary state.
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