Eigenvalues of Brownian Motions on GL(N,C)
Abstract
We prove that the empirical law of eigenvalues of Brownian motion on the Lie Group GL(N,C) converges almost surely to a deterministic probability measure, characterized by a free stochastic differential equation. This fully resolves a conjecture made by Philippe Biane in 1997. Our analysis includes a family \B=Bρ,ζ |ζ|<ρ\ of nondegenerate diffusion processes on GL(N,C) whose laws are invariant under unitary conjugation, with initial distributions assumed to be uniformly bounded and invertible. The crux of our analysis is a strong quantitative approximation of Brownian motion B(t) on GL(N,C) for small t by a single increment I+W(t), where W=Wρ,ζ is an elliptic Brownian motion in the Lie algebra gl(N,C) = MN(C). Specifically, for any t∈[0,1] and δ>0, \[ P(\|B(t)-I-W(t)\|≥ δ)≤ (C t/δ)N2/3 \] for a constant C=Cρ. Leveraging independence of multiplicative increments of the Brownian motion then allows us to use powerful (anti-)concentration tools for Gaussian matrices to complete the Hermitization procedure for convergence of eigenvalues.
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