On the universality of potential well dynamics

Abstract

Given a smooth potential function V : Rm R, one can consider the ODE ∂t2 u = -(∇ V)(u) describing the trajectory of a particle t u(t) in the potential well V. We consider the question of whether the dynamics of this family of ODE are universal in the sense that they contain (as embedded copies) any first-order ODE ∂t u = X(u) arising from a smooth vector field X on a manifold M. Assuming that X is nonsingular and M is compact, we show (using the Nash embedding theorem) that this is possible precisely when the flow (M,X) supports a geometric structure which we call a strongly adapted 1-form; many smooth flows do have such a 1-form, but we give an example (due to Bryant) of a flow which does not, and hence cannot be modeled by the dynamics of a potential well. As one consequence of this embeddability criterion, we construct an example of a (coercive) potential well system which is Turing complete in the sense that the halting of any Turing machine with a given input is equivalent to a certain bounded trajectory in this system entering a certain open set. In particular, this system contains trajectories for which it is undecidable whether that trajectory enters such a set. Remarkably, the above results also hold if one works instead with the nonlinear wave equation ∂t2 u - u = -(∇ V)(u) on a torus instead of a particle in a potential well, or if one replaces the target domain Rm by a more general Riemannian manifold.