Trees, parking functions, and standard monomials of skeleton ideals (1806.04289v4)

Abstract: Parking functions are a widely studied class of combinatorial objects, with connections to several branches of mathematics. On the algebraic side, parking functions can be identified with the standard monomials of $M_n$, a certain monomial ideal in the polynomial ring $S = {\mathbb K}[x_1, \dots, x_n]$ where a set of generators are indexed by the nonempty subsets of $[n] = {1,2,\dots,n}$. Motivated by constructions from the theory of chip-firing on graphs we study generalizations of parking functions determined by $M^{(k)}_n$, a subideal of $M_n$ obtained by allowing only generators corresponding to subsets of $[n]$ of size at most $k$. For each $k$ the set of standard monomials of $M^{(k)}_n$, denoted $\text{stan}_n^k$, contains the usual parking functions and has interesting combinatorial properties in its own right. For general $k$ we show that elements of $\text{stan}_n^k$ can be recovered as certain vector-parking functions, which in turn leads to a formula for their count via results of Yan. The symmetric group $S_n$ naturally acts on the set $\text{stan}_n^k$ and we also obtain a formula for the number of orbits under this action. For the case of $k = n-2$ we study combinatorial interpretations of $\text{stan}_n^{n-2}$ and relate them to properties of uprooted trees in terms of root degree and surface inversions. As a corollary we obtain a combinatorial identity for $n^n$ involving Catalan numbers, reminiscent of a result of Benjamin and Juhnke. For the case of $k = 1$ we observe that the number of elements $\text{stan}_n^1$ is given by the determinant of the reduced signless' Laplacian, which provides a weighted count for $|\text{stan}_n^1|$ in terms generalized spanning trees known asspanning TU-subgraphs'. Our constructions naturally generalize to arbitrary graphs and lead to a number of open questions.