Symmetric Sextic Freud Weight
Abstract
This paper investigates the properties of the sequence of coefficients $(\b_n)_{n\geq0}$ in the recurrence relation satisfied by the sequence of monic symmetric polynomials, orthogonal with respect to the symmetric sextic Freud weight $$\omega(x; \tau, t) = \exp(-x^6 + \tau x^4 + t x^2), \qquad x \in \mathbb{R}, $$ with real parameters $\tau$ and $t$. We derive a fourth-order nonlinear discrete equation satisfied by $\beta_n$, which is shown to be a special case of {the second} member of the discrete Painlev\'{e} I hierarchy. Further, we analyse differential and differential-difference equations satisfied by the recurrence coefficients. The emphasis is to offer a comprehensive study of the intricate evolution in the behaviour of these recurrence coefficients as the pair of parameters $(\tau,t)$ change. A comprehensive numerical and computational analysis is carried out for critical parameter ranges, and graphical plots are presented to illustrate the behaviour of the recurrence coefficients as well as the complexity of the associated Volterra lattice hierarchy. The corresponding symmetric sextic Freud polynomials are shown to satisfy a second-order differential equation with rational coefficients. The moments of the weight are examined in detail, including their integral representations, differential equations, and recursive structure. Closed-form expressions for moments are obtained in several special cases, and asymptotic expansions for the recurrence coefficients are provided. The results highlight rich algebraic and analytic structures underlying the symmetric sextic Freud weight and its connections to integrable systems.