Derivation of stochastic Burgers on the line with a Dirichlet boundary condition at the origin

Abstract

We analyze the equilibrium fluctuations of a Hamiltonian chain of oscillators on \(Z\) with an exponential potential, perturbed by a conservative, symmetric noise. Under the canonical diffusive scaling \(t t n2\) and an interaction strength tuned by \(n-1/2\), the fluctuation field is known to converge to the energy solution of the stochastic Burgers equation (SBE) on the torus~ABGS22. We introduce a coupled moving heat bath of strength \(n-δ\) acting on the particle system. We prove that for \(δ ≤ 1\) (the strong-coupling regime), the equilibrium fluctuation field converges to the energy solution of the SBE with a Dirichlet boundary condition at zero. We provide two distinct analytical characterizations of these boundary solutions, corresponding to different spaces of test functions. Conversely, for \(δ > 1\) (the weak-coupling regime), the heat bath becomes irrelevant in the scaling limit: the fluctuations converge to the standard SBE on the full line without any boundary condition, reproducing the full-line result of~GJ14. Our analysis thus reveals a sharp critical scaling in the coupling strength \(δ\), which dictates the emergence -- or absence -- of a macroscopic boundary condition from the microscopic perturbation.

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