Macdonald-Hurwitz Number
Abstract
Inspired by J. Novak's works on the asymptotic behavior of the BGW and the HCIZ matrix integrals \cite{[N0]} and by the algebraic and geometric properties of the Hurwitz numbers \cite{[IP]}, \cite{[LZZ]}, \cite{[LR]}, \cite{[OP]}, \cite{[Z1]}, and by the symplectic surgery theory of the relative GW-invariants \cite{[IP]}, \cite{[LR]}, using the elements of the transform matrix from the integral Macdonald function with two parameters to the homogeneous symmetric power sum functions \cite{[M]}, we have constructed the Macdonald-Hurwitz numbers. As an application, we have constructed a series of new genus-expanded cut-and-join differential operators, which can be thought of as the generalization of the Laplace-Beltrami operators and have the genus-expanded integral Macdonald functions as their common eigenfunctions. We have also obtained some generating wave functions of the same degree, which are generated by the Macdonald-Hurwitz numbers and can be expressed in terms of the new cut-and-join differential operators and the initial values. Another application is that we have constructed a new commutative associative algebra (referring to the last section (6)). By taking the limit along a special path (referring to the formulas (140), (141)), we specialize to be a commutative associative algebra , which will be proven to be isomorphic to the middle-dimensional -equivalent cohomological rings via the Jack functions over the Hilbert scheme points of constructed by W. Li, Z. Qin, and W. Wang in \cite{[LQW2]}.}
Cite
@article{arxiv.2211.11375,
title = {Macdonald-Hurwitz Number},
author = {Quan Zheng},
journal= {arXiv preprint arXiv:2211.11375},
year = {2023}
}
Comments
Any comments are welcomed and thanks!