Supercritical Mass and Condensation in Fokker--Planck Equations for Consensus Formation
It provides theoretical insights into condensation phenomena in consensus models, relevant for mathematical physics and multi-agent systems.
The paper studies a consensus formation model with condensation effects, showing that supercritical mass leads to finite-time concentration for a broader class of diffusion functions and providing estimates of the critical mass.
Inspired by recently developed Fokker--Planck models for Bose--Einstein statistics, we study a consensus formation model with condensation effects driven by a polynomial diffusion coefficient vanishing at the domain boundaries. For the underlying kinetic model, given by a nonlinear Fokker--Planck equation with superlinear drift, it was shown that if the initial mass exceeds a critical threshold, the solution may exhibit finite-time concentration in certain parameter regimes. Here, we show that this supercritical mass phenomenon persists for a broader class of diffusion functions and provide estimates of the critical mass required to induce finite-time loss of regularity.