Reverse approximation of gradient flows as Minimizing Movements: a conjecture by De Giorgi

Abstract

We consider the Cauchy problem for the gradient flow equation eq:81 u'(t)=-∇φ(u(t)), t 0; u(0)=u0, equation generated by a continuously differentiable function φ: H R in a Hilbert space H and study the reverse approximation of solutions to () by the De Giorgi Minimizing Movement approach. We prove that if H has finite dimension and φ is quadratically bounded from below (in particular if φ is Lipschitz) then for every solution u to () (which may have an infinite number of solutions) there exist perturbations φτ: H R \ (τ>0) converging to φ in the Lipschitz norm such that u can be approximated by the Minimizing Movement scheme generated by the recursive minimization of (τ,U,V):= 12τ|V-U|2+ φτ(V): equation eq:abstract Uτn∈ argminV∈ H (τ,Uτn-1,V) n∈ N, Uτ0:=u0. equation We show that the piecewise constant interpolations with time step τ > 0 of all possible selections of solutions (Uτn)n∈ N to () will converge to u as τ 0. This result solves a question raised by Ennio De Giorgi. We also show that even if H has infinite dimension the above approximation holds for the distinguished class of minimal solutions to (), that generate all the other solutions to () by time reparametrization.