Second-order convergence of monotone schemes for conservation laws
Provides the first theoretical guarantee of second-order accuracy for numerical methods solving nonlinear conservation laws with discontinuities, a long-standing open problem in numerical analysis.
Proved that monotone W1-contractive schemes for scalar conservation laws achieve second-order convergence (Δx²) in Wasserstein distance for decreasing piecewise constant initial data, marking the first proof of second-order convergence for discontinuous solutions of nonlinear conservation laws.
We prove that a class of monotone, \emph{$W_1$-contractive} schemes for scalar conservation laws converge at a rate of $Δx^2$ in the Wasserstein distance ($W_1$-distance), whenever the initial data is decreasing and consists of a finite number of piecewise constants. It is shown that the Lax--Friedrichs, Enquist--Osher and Godunov schemes are $W_1$-contractive. Numerical experiments are presented to illustrate the main result. To the best of our knowledge, this is the first proof of second-order convergence of any numerical method for discontinuous solutions of nonlinear conservation laws.