In section 11 of [this paper][1] I show  that a discrete Morse function on a simplicial  complex  leads to a dynamical description of Forman's theory.  More precisely  there is a canonical flow  associated to the function  such that the (open) faces of the barycentric subdivision are invariant sets. The  stationary points of this flow  are the barycenters of the original simplicial complex.  

The discrete  Morse function defines a a continuous function  which is  affine on the faces of the barycentric subdivision and is a Lyapunov function for the above flow, i.e., it decreases along the trajectories of the flow.    

The key property  of the flow as far as its connection with Forman's theory is concerned is the following:  a barycenter of a face  $F$ (which is a stationary point of the flow) has nontrivial Conley index if and only if the corresponding face is critical in Forman's sense.   The unstable manifold of this point is the interior of the face $F$ and  the   (homotopic)  Conley index is the homotopy type of the pair $[F,\partial F]$. We see that this is the same as the homotopy  type of a pointed sphere of the same dimension as $F$.

Using  the finite volume flow technology of Harvey-Lawson  one can then obtain a  chain homotopy from the simplicial chain complex  to the Forman complex.


  [1]: http://www3.nd.edu/~lnicolae/tameflow.pdf