Dynamical Universality for Random Matrices

We establish an invariance principle corresponding to the universality of random matrices. More precisely, we prove the dynamical universality of random matrices in the sense that, if the random point fields μ of Nparticle systems describing the eigenvalues of random matrices or log-gases with general self-interaction potentials V converge to some random point field μ, then the associated natural μ -reversible diffusions represented by solutions of stochastic differential equations (SDEs) converge to some μ-reversible diffusion given by the solution of an infinite-dimensional SDE (ISDE). Our results are general theorems that can be applied to various random point fields related to random matrices such as sine, Airy, Bessel, and Ginibre random point fields. In general, the representations of finitedimensional SDEs describing N-particle systems are very complicated. Nevertheless, the limit ISDE has a simple and universal representation that depends on a class of random matrices appearing in the bulk, and at the softand at hard-edge positions. Thus, we prove that ISDEs such as the infinite-dimensional Dyson model and the Airy, Bessel, and Ginibre interacting Brownian motions are universal dynamical objects.

[1]  Y. Kawamoto,et al.  Finite-particle approximations for interacting Brownian particles with logarithmic potentials , 2016, Journal of the Mathematical Society of Japan.

[2]  H. Osada Non-collision and collision properties of Dyson's model in infinite dimension and other stochastic dynamics whose equilibrium states are determinantal random point fields , 2015, 1502.06072.

[3]  Osada,et al.  Infinite-dimensional stochastic differential equations and tail σ-fields II: the IFC condition , 2021 .

[4]  O. Kallenberg Random Measures, Theory and Applications , 2017 .

[5]  Kazuhiro Kuwae,et al.  Convergence of spectral structures: a functional analytic theory and its applications to spectral geometry , 2003 .

[6]  C. Tracy,et al.  Introduction to Random Matrices , 1992, hep-th/9210073.

[7]  H. Osada Dirichlet form approach to infinite-dimensional Wiener processes with singular interactions , 1996 .

[8]  D. Lubinsky,et al.  Universality in measure in the bulk for varying weights , 2016 .

[9]  H. Osada Infinite-dimensional stochastic differential equations related to random matrices , 2010, Probability Theory and Related Fields.

[10]  H. Osada Interacting Brownian motions in infinite dimensions with logarithmic interaction potentials , 2009, 0902.3561.

[11]  Hirofumi Osada,et al.  Tagged particle processes and their non-explosion criteria , 2009, 0905.3973.

[12]  Terence Tao,et al.  Random matrices: Universality of local spectral statistics of non-Hermitian matrices , 2012, 1206.1893.

[13]  H. Yau,et al.  Universality of general β -ensembles , 2011 .

[14]  M. Shcherbina Orthogonal and Symplectic Matrix Models: Universality and Other Properties , 2010, 1004.2765.

[15]  Y. Kawamoto,et al.  Dynamical Bulk Scaling Limit of Gaussian Unitary Ensembles and Stochastic Differential Equation Gaps , 2016, 1610.05969.

[16]  Li-Cheng Tsai Infinite dimensional stochastic differential equations for Dyson’s model , 2014, Probability Theory and Related Fields.

[17]  Stephanos Venakides,et al.  UNIFORM ASYMPTOTICS FOR POLYNOMIALS ORTHOGONAL WITH RESPECT TO VARYING EXPONENTIAL WEIGHTS AND APPLICATIONS TO UNIVERSALITY QUESTIONS IN RANDOM MATRIX THEORY , 1999 .

[18]  G. Akemann,et al.  Universality at Weak and Strong Non-Hermiticity Beyond the Elliptic Ginibre Ensemble , 2016, Communications in Mathematical Physics.

[19]  Y. Kawamoto,et al.  Uniqueness of Dirichlet Forms Related to Infinite Systems of Interacting Brownian Motions , 2017, Potential Analysis.

[20]  Stephanos Venakides,et al.  Strong asymptotics of orthogonal polynomials with respect to exponential weights , 1999 .

[21]  Doron S Lubinsky A New Approach to Universality Limits Involving Orthogonal Polynomials , 2007 .

[22]  A. Kolesnikov Mosco convergence of Dirichlet forms in infinite dimensions with changing reference measures , 2006 .

[23]  H. Yau,et al.  Fixed energy universality of Dyson Brownian motion , 2016, Advances in Mathematics.

[24]  Universality at the edge of the spectrum for unitary, orthogonal, and symplectic ensembles of random matrices , 2005, math-ph/0507023.

[25]  H. Spohn Interacting Brownian Particles: A Study of Dyson’s Model , 1987 .

[26]  Universality in Random Matrix Theory for orthogonal and symplectic ensembles , 2004, math-ph/0411075.

[27]  A. Hammond,et al.  Brownian Gibbs property for Airy line ensembles , 2011, 1108.2291.

[28]  H. Osada,et al.  Cores of dirichlet forms related to random matrix theory , 2014, 1405.4304.

[29]  H. Osada,et al.  Strong Markov property of determinantal processes with extended kernels , 2014, 1412.8678.

[30]  Zhi-Ming Ma,et al.  Introduction to the theory of (non-symmetric) Dirichlet forms , 1992 .

[31]  M. Katori,et al.  Noncolliding Brownian Motion and Determinantal Processes , 2007, 0705.2460.

[32]  K. Johansson Universality of the Local Spacing Distribution¶in Certain Ensembles of Hermitian Wigner Matrices , 2000, math-ph/0006020.