Generalized Dyson Brownian motion, McKean-Vlasov equation and eigenvalues of random matrices

Abstract

Using It\o's calculus and the mass optimal transportation theory, we study the generalized Dyson Brownian motion (GDBM) and the associated McKean-Vlasov evolution equation with an external potential V. Under suitable condition on V, we prove the existence and uniqueness of strong solution to SDE for GDBM. Standard argument shows that the family of the process of empirical measures LN(t) of GDBM is tight and every accumulative point of LN(t) in the weak convergence topology is a weak solution of the associated McKean-Vlasov evolution equation, which can be realized as the gradient flow of the Voiculescu free entropy on the Wasserstein space over R. Under the condition V''≥ -K for some constant K≥ 0, we prove that the McKean-Vlasov equation has a unique solution μ(t) and LN(t) converges weakly to μ(t) as N→ ∞. For C2 convex potentials, we prove that μ(t) converges to the equilibrium measure μV with respect to the W2-Wasserstein distance on P2(R) as t→ ∞. Under the uniform convexity or a modified uniform convexity condition on V, we prove that μ(t) converges to μV with respect to the W2-Wasserstein distance on P2(R) with an exponential rate as t→ ∞. Finally, we discuss the double-well potentials and raise some conjectures.