Perturbation of singular equilibria of hyperbolic two-component systems: a universal hydrodynamic limit
Abstract
We consider one-dimensional, locally finite interacting particle systems with two conservation laws which under Eulerian hydrodynamic limit lead to two-by-two systems of conservation laws: + (, u)=0 u+ (,u)=0, with (,u)∈ D⊂2, where D is a convex compact polygon in 2. The system is typically strictly hyperbolic in the interior of D with possible non-hyperbolic degeneracies on the boundary ∂ D. We consider the case of isolated singular (i.e. non hyperbolic) point on the interior of one of the edges of D, call it (0,u0)=(0,0) and assume D⊂\0\. This can be achieved by a linear transformation of the conserved quantities. We investigate the propagation of small nonequilibrium perturbations of the steady state of the microscopic interacting particle system, corresponding to the densities (0,u0) of the conserved quantities. We prove that for a very rich class of systems, under proper hydrodynamic limit the propagation of these small perturbations are universally driven by the two-by-two system + ( u)=0 u + ( + γ u2) =0 where the parameter γ:=12 uu(0,u0) (with a proper choice of space and time scale) is the only trace of the microscopic structure. The proof is valid for the cases with γ>1. [truncated]
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