Stationary Non-equilibrium Solutions for Coagulation Systems

We study coagulation equations under non-equilibrium conditions which are induced by the addition of a source term for small cluster sizes. We consider both discrete and continuous coagulation equations, and allow for a large class of coagulation rate kernels, with the main restriction being boundedness from above and below by certain weight functions. The weight functions depend on two power law parameters, and the assumptions cover, in particular, the commonly used free molecular and diffusion limited aggregation coagulation kernels. Our main result shows that the two weight function parameters already determine whether there exists a stationary solution under the presence of a source term. In particular, we find that the diffusive kernel allows for the existence of stationary solutions while there cannot be any such solutions for the free molecular kernel. The argument to prove the non-existence of solutions relies on a novel power law lower bound, valid in the appropriate parameter regime, for the decay of stationary solutions with a constant flux. We obtain optimal lower and upper estimates of the solutions for large cluster sizes, and prove that the solutions of the discrete model behave asymptotically as solutions of the continuous model.

Automated summary

The study focuses on coagulation equations under non-equilibrium conditions induced by a source term for small cluster sizes. It is found that the two weight function parameters determine the existence of stationary solutions, with diffusive kernels allowing for their existence while free molecular kernels do not. Lower and upper estimates for solutions for large cluster sizes are obtained, and it is proved that the behavior of discrete model solutions asymptotically resembles that of continuous model solutions.