Saved in:
Bibliographic Details
Main Authors: Lyu, Shulin, Lyu, Yuanfei
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.00391
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910035907444736
author Lyu, Shulin
Lyu, Yuanfei
author_facet Lyu, Shulin
Lyu, Yuanfei
contents We study the Hankel determinant for the weight $x^α{\rm exp}(-x-t_1/x-t_2/x^2), x\in[0,+\infty)$, with $α>-1,~t_1\in\mathbb{R}\setminus\{0\}, ~t_2>0.$ Compared with the weight $x^α{\rm e}^{-x-t_1/x}$ studied in prior work (where $α,t_1>0$), the range of $α$ in our work is extended and the parameter $t_2$ introduces a ``stronger" zero at the origin. This leads to more varied behavior of the Hankel determinant, and the interplay between $t_1$ and $t_2$ introduces uncertainty and complexity into the analysis. By using a pair of ladder operators satisfied by the associated monic orthogonal polynomials and three compatibility conditions, we show that the recurrence coefficients are expressed in terms of four auxiliary quantities which satisfy a system of difference equations that can be iterated. We also establish two coupled second order partial differential equations (PDEs) satisfied by two of the auxiliary quantities, which are reduced to a Painlevé III$^\prime$ equation when $t_2\rightarrow0^+$. Moreover, the logarithmic derivative of the Hankel determinant is shown to satisfy a second order six degree PDE which is reduced to the $σ$-form of the Painlevé III$^{\prime}$ equation when $t_2\rightarrow0^+$. Under suitable double scaling, we obtain the limiting forms of the above PDEs and deduce the equilibrium density of the eigenvalues for the unitary ensemble. We extend our analysis to the Hankel determinant for $x^α\exp(-x-\sum_{k=1}^m t_k/x^k)$ with $m=3$. For general $m$, we outline a derivation that leads, at least in principle, to the PDE satisfied by the logarithmic derivative of the Hankel determinant.
format Preprint
id arxiv_https___arxiv_org_abs_2603_00391
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Hankel Determinant for a Perturbed Laguerre Weight with Pole Singularities and Generalized Painlevé III' Equation
Lyu, Shulin
Lyu, Yuanfei
Mathematical Physics
15B52, 33E17, 42C05
We study the Hankel determinant for the weight $x^α{\rm exp}(-x-t_1/x-t_2/x^2), x\in[0,+\infty)$, with $α>-1,~t_1\in\mathbb{R}\setminus\{0\}, ~t_2>0.$ Compared with the weight $x^α{\rm e}^{-x-t_1/x}$ studied in prior work (where $α,t_1>0$), the range of $α$ in our work is extended and the parameter $t_2$ introduces a ``stronger" zero at the origin. This leads to more varied behavior of the Hankel determinant, and the interplay between $t_1$ and $t_2$ introduces uncertainty and complexity into the analysis. By using a pair of ladder operators satisfied by the associated monic orthogonal polynomials and three compatibility conditions, we show that the recurrence coefficients are expressed in terms of four auxiliary quantities which satisfy a system of difference equations that can be iterated. We also establish two coupled second order partial differential equations (PDEs) satisfied by two of the auxiliary quantities, which are reduced to a Painlevé III$^\prime$ equation when $t_2\rightarrow0^+$. Moreover, the logarithmic derivative of the Hankel determinant is shown to satisfy a second order six degree PDE which is reduced to the $σ$-form of the Painlevé III$^{\prime}$ equation when $t_2\rightarrow0^+$. Under suitable double scaling, we obtain the limiting forms of the above PDEs and deduce the equilibrium density of the eigenvalues for the unitary ensemble. We extend our analysis to the Hankel determinant for $x^α\exp(-x-\sum_{k=1}^m t_k/x^k)$ with $m=3$. For general $m$, we outline a derivation that leads, at least in principle, to the PDE satisfied by the logarithmic derivative of the Hankel determinant.
title Hankel Determinant for a Perturbed Laguerre Weight with Pole Singularities and Generalized Painlevé III' Equation
topic Mathematical Physics
15B52, 33E17, 42C05
url https://arxiv.org/abs/2603.00391