Abstract
We study three instances of log-correlated processes on the interval: the logarithm of the Gaussian unitary ensemble (GUE) characteristic polynomial, the Gaussian log-correlated potential in presence of edge charges, and the Fractional Brownian motion with Hurst index $H \to 0$ (fBM0). In previous collaborations we obtained the probability distribution function (PDF) of the value of the global minimum (equivalently maximum) for the first two processes, using the {\it freezing-duality conjecture} (FDC). Here we study the PDF of the position of the maximum $x_m$ through its moments. Using replica, this requires calculating moments of the density of eigenvalues in the $\beta$-Jacobi ensemble. Using Jack polynomials we obtain an exact and explicit expression for both positive and negative integer moments for arbitrary $\beta >0$ and positive integer $n$ in terms of sums over partitions. For positive moments, this expression agrees with a very recent independent derivation by Mezzadri and Reynolds. We check our results against a contour integral formula derived recently by Borodin and Gorin (presented in the Appendix A from these authors). The duality necessary for the FDC to work is proved, and on our expressions, found to correspond to exchange of partitions with their dual. Performing the limit $n \to 0$ and to negative Dyson index $\beta \to -2$, we obtain the moments of $x_m$ and give explicit expressions for the lowest ones. Numerical checks for the GUE polynomials, performed independently by N. Simm, indicate encouraging agreement. Some results are also obtained for moments in Laguerre, Hermite-Gaussian, as well as circular and related ensembles. The correlations of the position and the value of the field at the minimum are also analyzed.
Highlights
Correlated Gaussian (LCG) random processes and fields attract growing attention in mathematical physics and probability and play an important role in problems of statistical mechanics, quantum gravity, turbulence, financial mathematics and random matrix theory, see e.g. recent papers [1,2,3,4,5] for introduction and some background references and [6] for earlier review including condensed matter applications
Our first prediction is for the lowest moments of the position of the global maximum for the the modulus of the characteristic polynomial pN (x) = det(x I − H ) of the Hermitian N × N matrix H sampled with the probability weight
In this paper we developed a systematic approach to investigating statistical properties of the position xm of the global extremum for appropriately regularized logarithmically-correlated gaussian (LCG) processes in an interval
Summary
Correlated Gaussian (LCG) random processes and fields attract growing attention in mathematical physics and probability and play an important role in problems of statistical mechanics, quantum gravity, turbulence, financial mathematics and random matrix theory, see e.g. recent papers [1,2,3,4,5] for introduction and some background references and [6] for earlier review including condensed matter applications. A general lattice version of logarithmically correlated Gaussian field is a collection of Gaussian variables VN,x : x ∈ DN attached to the sites of d−dimensional box DN of side length N (assuming lattice spacing one) and characterized by the mean zero and the covariance structure
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