Microscopic derivation of Vlasov equations with singular potentials

Abstract

The Vlasov-Poisson equation is a classical example of an effective equation which shall describe the coarse-grained time evolution of a system consisting of a large number of particles which interact by Coulomb or Newton's gravitational force. Although major progress concerning a rigorous justification of such an approach was made recently, there are still substantial steps necessary to obtain a completely convincing result. The main goal of this work is to yield further progress in this regard. \\ To this end, we consider on the one hand N-dependent forces fN (where N shall denote the particle number) which converge pointwise to Coulomb or alternatively Newton`s gravitational force. More precisely, the interaction fulfills fN(q)=q|q|3 for |q|>N-718+ε and has a cut-off at |q|= N-718+ε where ε>0 can be chosen arbitrarily small. We prove that under certain assumptions on the initial density k0 the characteristics of Vlasov equation provide typically a very good approximation of the N-particle trajectories if their initial positions are i.i.d. with respect to density k0. Interestingly, the cut-off diameter is of smaller order than the average distance of a particle to its nearest neighbor. Nevertheless, the cut-off is essential for the success of the applied approach and thus we consider additionally less singular forces scaling like |f(q)|=1|q|α where α∈ (1,43]. In this case we are able to show a corresponding result even without any regularization. Although such forces are distinctly less interesting than for instance Coulomb interaction from a physical perspective, the introduced ideas for dealing with forces where even the related potential is singular might still be helpful for attaining comparable results for the arguably most interesting case α=2.