Hydrodynamics of particle systems with selection via uniqueness for free boundary problems

We study an injection-branching-selection particle system on $\R$ at the hydrodynamic limit under arbitrarily varying injection and removal rates, where the corresponding free boundary problem (FBP) is not in general known to be solvable in the classical sense. We propose a weak formulation that does not involve the notion of a free boundary, but reduces to a FBP when classical solutions exist. It is based on second order parabolic equations with measure-valued right-hand side in conjunction with a complementarity condition. We show that the weak formulation characterizes the limit. We also study a branching-selection model of motionless particles with nonlocal branching in $\R^d$ under a general fitness function. The corresponding integro-differential FBP, shown to characterize the hydrodynamic limit, is an (irreducible) multi-dimensional evolution equation. In both results the treatment is based on FBP uniqueness.