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Δ–Springer varieties and Hall–Littlewood polynomials

Published online by Cambridge University Press:  31 January 2024

Sean T. Griffin*
Affiliation:
University of California, Davis, One Shields Ave, Davis, CA, 95616, USA; E-mail: [email protected]

Abstract

The $\Delta $-Springer varieties are a generalization of Springer fibers introduced by Levinson, Woo and the author that have connections to the Delta Conjecture from algebraic combinatorics. We prove a positive Hall–Littlewood expansion formula for the graded Frobenius characteristic of the cohomology ring of a $\Delta $-Springer variety. We do this by interpreting the Frobenius characteristic in terms of counting points over a finite field $\mathbb {F}_q$ and partitioning the $\Delta $-Springer variety into copies of Springer fibers crossed with affine spaces. As a special case, our proof method gives a geometric meaning to a formula of Haglund, Rhoades and Shimozono for the Hall–Littlewood expansion of the symmetric function in the Delta Conjecture at $t=0$.

Type
Discrete Mathematics
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

1. Introduction

In [Reference Griffin, Levinson and Woo10], Levinson, Woo and the author introduced the $\Delta $ -Springer varieties $Y_{n,\lambda ,s}$ as a generalization of Springer fibers that give a compact geometric realization of the Delta Conjecture at $t=0$ . Precisely, they showed that the symmetric function $\Delta ^{\prime }_{e_{k-1}}e_n|_{t=0}$ corresponds under the graded Frobenius characteristic map to the cohomology ring of a certain $\Delta $ -Springer variety, up to a minor twist. In this article, we give a proof of the expansion, originally announced in [Reference Griffin9], of the graded Frobenius characteristic of the cohomology ring of a $\Delta $ -Springer variety as a positive sum of modified Hall–Littlewood symmetric functions. As a special case, our proof gives a geometric explanation of the Hall–Littlewood expansion for $\Delta ^{\prime }_{e_{k-1}}e_n|_{t=0}$ given by Haglund, Rhoades and Shimozono [Reference Haglund, Rhoades and Shimozono12].

1.1. Background and context

Springer fibers $\mathcal {B}_{\lambda }$ are a family of subvarieties of the complete flag variety indexed by partitions $\lambda $ that have remarkable connections to representation theory. Notably, Springer [Reference Springer22, Reference Springer23] constructed an action of the symmetric group $S_n$ on the cohomology ring of a Springer fiber and showed that the top nonzero cohomology group is an irreducible representation of $S_n$ and that all finite-dimensional irreducible representations of $S_n$ appear this way. Furthermore, the graded $S_n$ -module structure of the cohomology ring is well studied. Under the Frobenius characteristic map that sends an $S_n$ -module to a symmetric function, the cohomology ring of a Springer fiber corresponds to the Hall–Littlewood symmetric function [Reference Hotta and Springer15],

$$\begin{align*}\widetilde H_{\lambda}(\mathbf{x};q) = \mathrm{Frob}(H^{*}(\mathcal{B}_{\lambda};\mathbb{Q});q). \end{align*}$$

Alternatively, the modified Hall–Littlewood symmetric functions can be obtained by counting $\mathbb {F}_q$ -points. Letting $\mathrm {Stein}_{\lambda }^{\mu }$ be the Steinberg variety of partial flags of type $\mu $ that are preserved by a fixed nilpotent matrix of Jordan type $\lambda $ , it is well known that for all prime powers q,

(1.1) $$ \begin{align} \widetilde H_{\lambda}(\mathbf{x};q) = \sum_{\mu\vdash n} |\mathrm{Stein}_{\lambda}^{\mu}(\mathbb{F}_q)|m_{\mu}(\mathbf{x}), \end{align} $$

where $m_{\mu }$ is the monomial symmetric function and $\mathrm {Stein}_{\lambda }^{\mu }(\mathbb {F}_q)$ stands for the set of $\mathbb {F}_q$ points of $\mathrm {Stein}_{\lambda }^{\mu }$ .

Similar interpretations have been given for the modified Macdonald polynomials $\widetilde H_{\lambda }(\mathbf {x};q,t)$ , which are a generalization of modified Hall-Littlewood symmetric functions with coefficients in two parameters q and t. Haiman proved that $\widetilde H_{\lambda }(\mathbf {x};q,t)$ is the bi-graded Frobenius characteristic of the fiber of a certain tautological bundle on the Hilbert scheme of points in the plane [Reference Haiman13, Reference Haiman14]. Mellit realized $\widetilde H_{\lambda }(\mathbf {x};q,t)$ as a weighted count of points in an affine Springer fiber [Reference Mellit18].

In a related line of work, the Delta Conjecture of Haglund, Remmel and Wilson [Reference Haglund, Remmel and Wilson11] gives two combinatorial formulas for a symmetric function $\Delta ^{\prime }_{e_{k-1}}e_n$ , where $\Delta ^{\prime }_{e_{k-1}}$ is a certain eigenoperator that diagonalizes the modified Macdonald polynomial basis. There has been recent progress on realizing this symmetric function naturally as the Frobenius characteristic of an $S_n$ -module. Haglund, Rhoades and Shimozono [Reference Haglund, Rhoades and Shimozono12] found a graded ring $R_{n,k}$ whose graded Frobenius characteristic is $\mathrm {rev}_q\circ \omega (\Delta ^{\prime }_{e_{k-1}}e_n|_{t=0})$ , where $\omega $ is the involution that swaps elementary symmetric functions $e_n$ with complete homogeneous symmetric functions $h_n$ , and $\mathrm {rev}_q$ reverses the coefficients as a polynomial in q. Pawlowski and Rhoades subsequently defined the space of spanning line configurations, which is a smooth noncompact variety whose cohomology is $R_{n,k}$ . Additionally, Zabrocki [Reference Zabrocki24] has conjectured that the graded Frobenius characteristic of the superspace coinvariant ring in the $n-k$ fermionic degree is $\Delta ^{\prime }_{e_{k-1}}e_n$ , and Bergeron [Reference Bergeron1] has conjectured that $\Delta ^{\prime }_{e_{k-1}}e_n$ can be obtained via skewing operators. See [Reference Rhoades20] for a survey of these and related results.

In [Reference Griffin9], the author generalized the ring $R_{n,k}$ to a family of quotient rings $R_{n,\lambda ,s}$ that also include Tanisaki’s presentation of the cohomology ring of a Springer fiber as a special case. Each ring $R_{n,\lambda ,s}$ has the structure of a graded $S_n$ -module whose graded Frobenius characteristic has several combinatorial formulas that extend previously known formulas for $\Delta _{e_{k-1}}^{\prime }e_n|_{t=0}$ and $\widetilde H_{\lambda }(\mathbf {x};q)$ . In particular, there are two monomial symmetric function expansions in terms of inversions and diagonal inversions, respectively, of labeled diagrams called partial row-decreasing fillings. We recall the relevant notation and statistics in Section 2.

Theorem 1.1 [Reference Griffin9]

We have

$$\begin{align*}\mathrm{Frob}(R_{n,\lambda,s} ;q) = \sum_{\mu\vdash n}\sum_{\varphi\in \operatorname{\mathrm{PRD}}^{\mu}_{n,\lambda,s}} q^{\operatorname{{\mathrm{inv}}}(\varphi)} m_{\mu}(\mathbf{x}) = \sum_{\mu\vdash n}\sum_{\varphi\in\operatorname{\mathrm{PRD}}^{\mu}_{n,\lambda,s}} q^{\operatorname{{\mathrm{dinv}}}(\varphi)} m_{\mu}(\mathbf{x}). \end{align*}$$

Levinson, Woo and the author [Reference Griffin, Levinson and Woo10] then constructed a compact variety $Y_{n,\lambda ,s}$ , the $\Delta $ -Springer variety, whose cohomology ring is $R_{n,\lambda ,s}$ . In the special case of $\lambda = (1^k)$ and $s=k$ , the variety $Y_{n,(1^k),k}$ gives a compact geometric realization of the Delta Conjecture symmetric function at $t=0$ , since $H^{*}(Y_{n,(1^k),k}) \cong R_{n,k}$ . It was also shown that $Y_{n,\lambda ,s}$ has many of the same geometric and representation-theoretic properties as Springer fibers, including a characterization of the $S_n$ -module structure of the top cohomology group.

Theorem 1.2 [Reference Griffin, Levinson and Woo10]

The variety $Y_{n,\lambda ,s}$ is equidimensional of complex dimension

$$\begin{align*}d = n(\lambda) + (s-1)(n-k), \end{align*}$$

where $n(\lambda ) = \sum _i \binom {\lambda _i^{\prime }}{2}$ . For $s>\ell (\lambda )$ , we have an isomorphism of $S_n$ -modules

$$\begin{align*}H^{2d}(Y_{n,\lambda,s};\mathbb{Q}) \cong \mathrm{Ind}\!\uparrow_{S_k\times S_{n-k}}^{S_n}(S^\lambda), \end{align*}$$

where $S^\lambda $ is considered as a $S_k\times S_{n-k}$ -module in which $S_{n-k}$ acts trivially.

1.2. Results of this paper

Our main theorem is a positive expansion of the graded Frobenius characteristic of $H^{*}(Y_{n,\lambda ,s};\mathbb {Q})$ (equivalently of $R_{n,\lambda ,s}$ ) into modified Hall–Littlewood symmetric functions, a result that was announced in [Reference Griffin9].

Theorem 1.3. We have

(1.2) $$ \begin{align} \mathrm{Frob}(H^{*}(Y_{n,\lambda,s};\mathbb{Q});q) &= \mathrm{rev}_q\left[ \sum_{\substack{\nu\in \mathrm{Par}(n,s),\\ \nu\supseteq \lambda}} q^{n(\nu/\lambda)} \prod_{i\geq 0} \genfrac{[}{]}{0pt}{}{\nu_i^{\prime}-\lambda_{i+1}^{\prime}}{\nu_i^{\prime}-\nu_{i+1}^{\prime}}_q H_\nu(\mathbf{x};q)\right] \end{align} $$
(1.3) $$ \begin{align} & = \sum_{\substack{\nu\in \mathrm{Par}(n,s),\\ \nu\supseteq \lambda}} q^{\sum_i (s-\nu_i^{\prime})(\nu_{i+1}^{\prime}-\lambda_{i+1}^{\prime})}\prod_{i\geq 0} \genfrac{[}{]}{0pt}{}{\nu_i^{\prime}-\lambda_{i+1}^{\prime}}{\nu_i^{\prime}-\nu_{i+1}'}_q \widetilde{H}_\nu(\mathbf{x};q), \end{align} $$

where .

A special case of this formula has been used to verify the construction of higher Specht bases for some infinite subfamilies of the rings $R_{n,\lambda ,s}$ [Reference Gillespie and Rhoades8].

The outline of the proof of Theorem 1.3 is as follows. We start with the fact that the left-hand side of (1.2) is given by the inversion formula in Theorem 1.1. We then show that $Y^{\mu }_{n,\lambda ,s}$ , the projection of $Y_{n,\lambda ,s}$ down to a partial flag variety, has an affine paving such that the dimension of a cell is computed by the inversion statistic $\operatorname {{\mathrm {inv}}}$ . We use this to show that the $m_{\mu }(\mathbf {x})$ coefficient of the inversion formula in Theorem 1.1 can be computed by counting $\mathbb {F}_q$ points of $Y_{n,\lambda ,s}^{\mu }$ . We then show that the $\mathbb {F}_q$ points of $Y_{n,\lambda ,s}^{\mu }$ can alternatively be computed by partitioning $Y_{n,\lambda ,s}^{\mu }$ into a disjoint union of copies of affine spaces crossed with Steinberg varieties.

When $\lambda = (1^k)$ and $s=k$ , the right-hand side of (1.2) is the right-hand side of [Reference Haglund, Rhoades and Shimozono12, Theorem 6.14], the formula for $\mathrm {Frob}(R_{n,k};q)$ proven by Haglund, Rhoades and Shimozono. Since $R_{n,k} \cong H^{*}(Y_{n,(1^k),k};\mathbb {Q})$ (up to doubling the degree), this can be seen as a solution to Problem 9.9 in [Reference Pawlowski and Rhoades19], but with the space of spanning line configurations $X_{n,k}$ replaced by the $\Delta $ -Springer variety $Y_{n,(1^k),k}$ .

2. Background

2.1. Compositions and partitions

Let us recall basic notions about symmetric functions and their connections to $S_n$ -modules. A composition $\alpha $ of n of length s is a tuple $\alpha =(\alpha _1,\alpha _2,\dots , \alpha _s)$ of nonnegative integers such that $\alpha _1+\cdots +\alpha _s = n$ . We write $|\alpha |=n$ for the size of $\alpha $ . Let $\mathrm {Comp}(n,s)$ be the set of compositions of n with length s. We say $\alpha $ is a strong composition if $\alpha _i>0$ for all $i\leq s$ . Given $\alpha $ a strong composition of n, let

be the i th block of $\alpha $ .

A partition is a composition $\lambda $ such that $\lambda _1\geq \lambda _2\geq \cdots \geq \lambda _s\geq 0$ . The length of $\lambda $ , written $\ell (\lambda )$ , is the number of positive parts of $\lambda $ . We sometimes write $\lambda \vdash n$ to mean that $\lambda $ is a partition of n. The conjugate partition $\lambda '$ is the partition of n whose ith entry $\lambda _i^{\prime }$ is the number of indices j such that $\lambda _j\geq i$ . Occasionally, we write $(a^b)$ to mean the partition $(a,a,\dots ,a)$ with b many a’s. We write $(\lambda ,a)$ to mean the partition obtained by appending a to the end of $\lambda $ . Let $\mathrm {Par}(n,s)$ be the set of partitions $\lambda $ of n such that $\ell (\lambda )\leq s$ , where we identify partitions up to adding trailing $0$ s.

Given $\alpha \in \mathrm {Comp}(n,s)$ and $\lambda \in \mathrm {Par}(k,s)$ for some $k\leq n$ , we write $\lambda \subseteq \alpha $ if $\lambda _i\leq \alpha _i$ for all $i\leq s$ . A coinversion of $\alpha $ is a pair $(i,j)$ such that $1\leq i<j\leq s$ and $\alpha _i<\alpha _j$ . Let $\operatorname {\mathrm {coinv}}(\alpha )$ be the number of coinversions of $\alpha $ . For example, for $n=10$ , $k=4$ and $s=5$ , we have $\lambda = (2,1,1,0,0)\in \mathrm {Par}(4,5)$ , and $\alpha = (2,3,1,0,4) \in \mathrm {Comp}(10,5)$ such that $\lambda \subseteq \alpha $ . It can be checked that $\operatorname {\mathrm {coinv}}(\alpha ) = 5$ .

2.2. Symmetric functions and q-analogues

A symmetric function f is a formal power series in the variables that is invariant under any permutation of the variables. Let $m_{\lambda }(\mathbf {x})$ , $h_{\lambda }(\mathbf {x})$ and $s_{\lambda }(\mathbf {x})$ be the usual monomial, complete homogeneous and Schur symmetric functions, each of which forms a basis of the ring of symmetric functions as $\lambda $ ranges over all partitions of n. See [Reference Macdonald17] for their definitions.

To each finite-dimensional representation of $S_n$ over $\mathbb {Q}$ , we associate a symmetric function via the Frobenius characteristic map as follows. For $\lambda \vdash n$ , let $S^\lambda $ be the Specht module, which is the irreducible representation of $S_n$ indexed by $\lambda $ . Given a finite-dimensional vector space V over $\mathbb {Q}$ that has the structure of an $S_n$ -module, it decomposes as a direct sum of Specht modules, $V \cong \bigoplus _{\lambda \vdash n} (S^\lambda )^{\oplus a_{\lambda }}$ , where $a_{\lambda }$ is the multiplicity of $S^\lambda $ in V. The Frobenius characteristic of V is then defined to be

Given a graded vector space $V = \bigoplus _{i\geq 0} V^{(i)}$ where $V^{(i)}$ is finite dimensional, its Hilbert series is the generating function

If each $V^{(i)}$ also has the structure of a finite-dimensional $S_n$ -module, its graded Frobenius characteristic is

The ring $\Lambda _{\mathbb {Q}(q)}$ has a basis given by the Hall–Littlewood symmetric functions $P_{\mu }(\mathbf {x};q)$ , which have the property that

$$\begin{align*}s_{\lambda}(\mathbf{x}) = \sum_{\mu\vdash n} K_{\lambda,\mu}(q) P_{\mu}(\mathbf{x};q), \end{align*}$$

where $K_{\lambda ,\mu }(q)$ is the Kostka–Foulkes polynomial; see [Reference Macdonald17] for more details. The dual Hall–Littlewood symmetric functions are defined by

$$\begin{align*}H_{\mu}(\mathbf{x};q) = \sum_{\lambda\vdash n} K_{\lambda,\mu}(q) s_{\lambda}(\mathbf{x}). \end{align*}$$

These symmetric functions are sometimes alternatively denoted by $Q^{\prime }_{\mu }(\mathbf {x};q) = H_{\mu }(\mathbf {x};q)$ . Given a polynomial $f(q) = a_0 + a_1q + \cdots +a_mq^m$ with symmetric function coefficients such that $a_m\neq 0$ , the q -reversal of f is $\mathrm {rev}_q(f) = a_m + a_{m-1}q + \cdots + a_1 q^{m-1} + a_0q^m$ . In the case of Hall-Littlewood symmetric functions, the degree of $H_{\mu }(\mathbf {x};q)$ as a polynomial in q is . The reversal of $H_{\mu }(\mathbf {x};q)$ is the modified (dual) Hall–Littlewood symmetric function, written

$$\begin{align*}\widetilde H_{\mu}(\mathbf{x};q) = \mathrm{rev}_q\left(H_{\mu}(\mathbf{x};q)\right) = q^{n(\mu)}H_{\mu}(\mathbf{x};q^{-1}). \end{align*}$$

We use the following standard q-analogues of integers, factorials and binomial coefficients.

(2.1)
(2.2)
(2.3)

2.3. Flag varieties and Schubert cells

Given a field $\mathbb {F}$ , a partial flag in $\mathbb {F}^K$ is a nested sequence of vector subspaces of $\mathbb {F}^K$ ,

(2.4) $$ \begin{align} V_{\bullet} = (V_1\subset V_2\subset\dots\subset V_m). \end{align} $$

Given a strong composition $\mu = (\mu _1,\dots , \mu _m)$ such that $|\mu |=\mu _1+\cdots +\mu _m \leq K$ , define the partial flag variety to be the set of partial flags of $\mathbb {F}^K$ such that the dimensions of the successive quotients $V_i/V_{i-1}$ are recorded by the parts of $\mu $ ,

(2.5)

Here, by convention, we define . (Note that we have switched to using $\mu $ as a strong composition here, since the symbol $\alpha $ will be reserved later to denote a different composition.) We occasionally write when $|\mu | = K$ and the field $\mathbb {F}$ is clear from context.

The partial flag variety is realized as a projective algebraic variety as $G/P^{\mu }$ , where $G=GL_K$ and $P^{\mu }$ is the parabolic subgroup of block upper triangular matrices with blocks of sizes $\mu _1,\mu _2,\dots , \mu _m,K-|\mu |$ . We remark that although $\mathcal {B}^{\mu }(\mathbb {F}^K)$ is isomorphic to $\mathcal {B}^{\mu ,K-|\mu |}$ , it will be notationally convenient for us to distinguish the two spaces. In the case when $K=n$ and $\mu = (1^n)$ , $\mathcal {B}^{(1^n)}$ is the complete flag variety.

Returning to the general case when $|\mu |\leq K$ , let and let . Given an injective map $w : [n]\rightarrow [K]$ , we say that w is $\mu $ -increasing if for each $i\leq \ell (\mu )$ , w is increasing on the ith block of $\mu $ ; that is, $w_j<w_k$ for all elements $j<k$ of $\mu [i]$ . Given any w, let $\mathrm {sort}_{\mu }(w)$ be the unique injective $\mu $ -increasing function such that the images of the set $\mu [i]$ under w and $\mathrm {sort}_{\mu }(w)$ are the same for each i.

Define $f_1,f_2,\dots ,f_K$ to be the standard ordered basis of $\mathbb {F}^K$ . Given a $\mu $ -increasing injective map $w:[n]\rightarrow [K]$ , let the coordinate flag $F_{\bullet }^{(w)}\in \mathcal {B}^{\mu }(\mathbb {F}^K)$ be defined by setting $F^{(w)}_p=\mathrm {span}\{f_{w(1)},\ldots , f_{w(\mu _1+\cdots +\mu _p)}\}$ for all p such that $1\leq p\leq \ell (\mu )$ . Now define the Schubert cell $C_w$ to be the $P^{\mu }$ orbit of $F^{(w)}_{\bullet }$ . When $\mathbb {F} = \mathbb {C}$ , the Schubert cells are the cells of an affine paving (in fact, a CW-complex) of the partial flag variety.

There is another description of the Schubert cells that will be useful for us. Given a vector $v = \sum _i a_if_i\in \mathbb {F}^K$ , we say its leading term is the term $a_if_i$ with i maximal such that $a_i\neq 0$ . Given any $V_{\bullet }\in C_w\subseteq \mathcal {B}^{\mu }(\mathbb {F}^K)$ , for each i such that $1\leq i\leq \ell (\mu )$ , there exist unique vectors $v_1,\dots ,v_n\in \mathbb {F}^K$ such that for $p\in \mu [i]$ , we have $v_p\in V_i\setminus V_{i-1}$ , $v_p$ has leading term $f_{w(p)}$ , and

(2.6) $$ \begin{align} v_{p} =f_{w(p)}+\sum_{h=1}^{w(p)-1} \beta_{w(p),h}\, f_h, \end{align} $$

for some $\beta _{w(p),h}$ such that $\beta _{w(p),h}=0$ if $h\in \{w(1),\ldots ,w(p-1)\}$ . Note $V_i=\mathrm {span}\{v_1,\ldots ,v_{\mu _1+\cdots +\mu _i}\}$ . The $\beta _{w(p),h}$ that are not required to be 0 can be taken as algebraically independent coordinates on $C_w$ . We will say that (2.6) is the standard coordinate representation of $V_{\bullet }$ and that the $\beta _{w(p),h}$ are the standard coordinates of the Schubert cell. Equivalently, if $V_{\bullet }$ is represented as a matrix whose first $\mu _1+\cdots +\mu _i$ many columns span $V_i$ , then the $\beta _{w(p),h}$ are the matrix entries after column reducing.

Note that we have a projection map

$$\begin{align*}\pi^{\mu} : \mathcal{B}^{(1^n)}(\mathbb{F}^K) \to \mathcal{B}^{\mu}(\mathbb{F}^K)\end{align*}$$

defined by sending $V_{\bullet }$ to $(V_{\mu _1},V_{\mu _1+\mu _2},\dots ,V_n)$ . Given w a $\mu $ -increasing injective function, it is evident from the coordinate description of the Schubert cell $C_w\subseteq \mathcal {B}^{(1^n)}(\mathbb {F}^K)$ that $C_w$ is mapped isomorphically under $\pi ^{\mu }$ onto the corresponding Schubert cell $C_w\subseteq \mathcal {B}^{\mu }(\mathbb {F}^K)$ (which justifies our abuse of notation by not decorating $C_w$ with $\mu $ ).

2.4. Springer fibers and Steinberg varieties

Springer fibers are subvarieties of the complete flag variety studied by Springer [Reference Springer22, Reference Springer23]. Given a nilpotent $n\times n$ matrix N over $\mathbb {F}$ , the Springer fiber associated to it is

with the reduced induced scheme structure. Given two nilpotent matrices whose Jordan block sizes are recorded by the partition $\lambda \vdash n$ , their associated Springer fibers are isomorphic, so we simply denote the Springer fiber by , where $\lambda $ is the Jordan type of N. Springer showed that although the symmetric group $S_n$ does not act directly on $\mathcal {B}_{\lambda }$ , it does act on the cohomology ring $H^{*}(\mathcal {B}_{\lambda }(\mathbb {C});\mathbb {Q})$ , and used this action to geometrically construct the irreducible representations of $S_n$ . The connection between Springer fibers and symmetric functions is summed up in the following elegant formula [Reference Garsia and Procesi6, Reference Hotta and Springer15]:

(2.7) $$ \begin{align} \widetilde H_{\lambda}(\mathbf{x};q) = \mathrm{Frob}(H^{*}(\mathcal{B}_{\lambda}(\mathbb{C});\mathbb{Q}) ;q). \end{align} $$

Here, and throughout the paper, we define the grading on cohomology so that $H^{2k}$ is in degree k. This is possible since the odd degree cohomology groups of all of the varieties mentioned in this paper are $0$ .

It can be shown by induction that the Springer fiber has an alternative definition as a variety where the conditions $NV_i\subseteq V_i$ are replaced with the conditions $NV_i\subseteq V_{i-1}$ for all i, since N is nilpotent and we are considering complete flags. For partial flags of type $\mu $ a composition of K, these conditions give rise to two different varieties, which we refer to as the Steinberg and the Spaltenstein varieties, defined respectively as

We note that $\mathrm {Spalt}_{\lambda }^{\mu }$ is denoted by $\mathcal {B}^\lambda _{\mu }$ in [Reference Griffin, Levinson and Woo10]. By the construction of the Springer action, there is an isomorphism of graded vector spaces [Reference Borho and MacPherson2, Reference Brundan and Ostrik4]

(2.8) $$ \begin{align} H^{*}(\mathrm{Stein}_{\lambda}^{\mu}(\mathbb{C});\mathbb{Q}) \cong H^{*}(\mathcal{B}_{\lambda}(\mathbb{C});\mathbb{Q})^{S_{\mu}}, \end{align} $$

where the superscript $S_{\mu }$ denotes taking the fixed subspace under the action of the Young subgroup permuting the elements in the sets $\mu [1],\dots ,\mu [\ell (\mu )]$ independently. Similarly, there is an identification of the cohomology of $\mathrm {Spalt}_{\lambda }^{\mu }(\mathbb {C})$ with the $S_{\mu }$ -anti-invariants of the cohomology of the Springer fiber, up to a grading shift.

For X a complex variety, an affine paving of X is a filtration of X by closed subvarieties

$$\begin{align*}\emptyset=X_0\subseteq X_1\subseteq X_2\subseteq\cdots \subseteq X_m = X \end{align*}$$

such that for all i, $X_i\setminus X_{i-1}\cong \bigsqcup _{j} C_{i,j}$ , a disjoint union where $C_{i,j}\cong \mathbb {C}^{a_{i,j}}$ for some $a_{i,j}$ . If a compact complex variety X has an affine paving, then the dimensions of the even degree cohomology groups can be computed by counting dimensions of cells,

$$\begin{align*}\dim_{\mathbb{Q}} H^{2d}(X;\mathbb{Q}) = \#\{(i,j) \,|\, \dim_{\mathbb{C}}(C_{i,j}) = d\}, \end{align*}$$

and the odd degree cohomology groups are $0$ .

It is well known [Reference Brundan and Ostrik4, Reference Fresse5, Reference Spaltenstein21] that both $\mathrm {Stein}_{\lambda }^{\mu }(\mathbb {C})$ and $\mathrm {Spalt}_{\lambda }^{\mu }(\mathbb {C})$ have affine pavings. Hence, their odd degree cohomology groups are $0$ .

2.5. $\Delta $ -Springer varieties and affine pavings

We now recall the definition of the $\Delta $ -Springer variety $Y_{n,\lambda ,s}$ and the affine pavings of $Y_{n,\lambda ,s}$ constructed in [Reference Griffin, Levinson and Woo10].

Fix an integer $n\geq 0$ , a partition $\lambda $ of size $|\lambda |=k\leq n$ and an integer $s\geq \ell (\lambda )$ . Define , where for $i>\ell (\lambda )$ , and define . Given $\mathbb {F}$ a field and a nilpotent matrix $N_\Lambda $ over $\mathbb {F}$ of Jordan type $\Lambda $ , the $\Delta $ -Springer variety over $\mathbb {F}$ is defined to be

When $n=|\lambda | = k$ and s is arbitrary, the $\Delta $ -Springer variety specializes to $\mathcal {B}_{\lambda }$ , the usual Springer fiber.

The $\Delta $ -Springer variety can equivalently be defined as the projection of a certain Spaltenstein variety. Letting $(1^n,(s-1)^{n-k}) = (1^n,s-1,s-1,\dots ,s-1)$ , where $s-1$ is repeated $n-k$ many times, and $\pi : \mathcal {B}^{(1^n,(s-1)^{n-k})}\to \mathcal {B}^{(1^n)}(\mathbb {F}^K)$ be the projection map that forgets all but the first n parts of the flag, we have [Reference Griffin, Levinson and Woo10, Lemma 5.8]

(2.9) $$ \begin{align} Y_{n,\lambda,s} = \pi\left(\mathrm{Spalt}^{(1^n,(s-1)^{n-k})}_{\Lambda}\right). \end{align} $$

To briefly illustrate why (2.9) holds, given $V_{\bullet } \in \mathrm {Spalt}^{(1^n,(s-1)^{n-k})}_\Lambda $ , then by definition $N_\Lambda V_i\subseteq V_{i-1}$ for all i and $V_{2n-k} = \mathbb {C}^K$ . Combining these conditions for the $n-k$ many indices $i=n+1,\dots , 2n-k$ gives $N_\Lambda ^{n-k} \mathbb {C}^K = N_\Lambda ^{n-k} V_{2n-k} \subseteq V_n$ , which is the same condition as in $Y_{n,\lambda ,s}$ . Additionally, the conditions $N_\Lambda V_i \subseteq V_{i-1}$ for $i=1,\dots , n$ are equivalent to the conditions $N_\Lambda V_i\subseteq V_i$ for $i=1,\dots , n$ since $N_\Lambda $ is nilpotent so the action of $N_\Lambda $ on the $1$ -dimensional space $V_i/V_{i-1}$ must be $0$ .

We denote by $[\Lambda ]$ the Young diagram of $\Lambda $ according to English convention, which formally is the set

$$\begin{align*}[\Lambda] = \{(i,j) \,|\, 1\leq i \leq \ell(\Lambda), 1\leq j\leq \Lambda_i\}, \end{align*}$$

where $(i,j)$ is the cell in the ith row from the top and the jth column from the left. There are two copies of $[\lambda ]$ inside of $[\Lambda ]$ that we will consider, which are respectively left justified and right justified inside of $[\Lambda ]$ ,

Figure 1. An example of $[\Lambda ]$ for $n=7$ , $\lambda =(2,1)$ , $s=3$ , with the two copies of the Young diagram of $\lambda $ shaded.

The affine pavings of $Y_{n,\lambda ,s} = Y_{n,\lambda ,s}(\mathbb {C})$ are defined in terms of specific choices of the nilpotent matrix $N_\Lambda $ . Recall $f_1,\dots , f_K\in \mathbb {C}^K$ is the standard basis, and let . Given a bijection $T : [\Lambda ] \to [K]$ , define two nilpotent matrices $N_T$ and $N_T^t$ by

(2.10)
(2.11)

For example, for T as in Figure 2, we have $N_T f_5 = f_3$ and $N_T f_1 = 0$ , whereas $N_{T}^t f_3 = f_5$ and $N_T^t f_{16} = 0$ . Observe that both $N_T$ and $N_T^t$ have Jordan type $\Lambda $ by construction and that $N_T^t$ is simply the transpose of the matrix $N_T$ . We define $Y_{N_T}$ and $Y_{N_T^t}$ to be the $\Delta $ -Springer varieties for $N_T$ and $N_T^t$ , respectively, where we are abusing notation by suppressing the data of n, $\lambda $ and s.

Figure 2. The reading order filling T of $[\Lambda (7,(2,2),4)]$ , and the associated labelings $T^{(i)}$ .

Definition 2.1. We say that T is $(n,\lambda ,s)$ -Schubert compatible if

  • T restricts to a bijection between $[\lambda ]^r$ and $[k]$ .

  • T is decreasing along each row from left to right.

  • For all $(i,j)\in [\lambda ]^r$ , the label $T(i,j)$ is greater than all labels in column $j+1$ .

  • For $i'<i$ , we have $T(i',\Lambda _{i'}) < T(i,\Lambda _{i})$ .

  • Whenever $T(a,b)> T(c,d)$ for $b,d>1$ , then $T(a,b-1)> T(c,d-1)$ .

When n, $\lambda $ and s are clear from context, we simply say T is Schubert compatible.

Definition 2.2. The reading order of $[\Lambda ]$ is the sequence of cells obtained by reading down each column of $[\Lambda ]$ , ordering the columns from right to left. The reading order filling of $[\Lambda ]$ is the unique bijection $T:[\Lambda ]\to [K]$ such that $T(i,j) = \ell $ if and only if $(i,j)$ is the $\ell $ th cell in reading order.

It is noted in [Reference Griffin, Levinson and Woo10] that the reading order filling is Schubert compatible. See the filling T in Figure 2 for an example of the reading order filling.

When T is Schubert compatible, the intersection of a Schubert cell with $Y_{N_T}$ is either empty or a copy of affine space, and the nonempty intersections are the cells of an affine paving of $Y_{N_T}$ . In fact, these cells have a recursive structure which we state next.

Let T be Schubert compatible. For $1\leq i \leq s$ , define the flattening function $\mathrm {f\hspace {0.25pt}l}_T^{(i)}$ and filling $T^{(i)}$ as follows. If $i\leq \ell (\lambda )$ , then $\mathrm {f\hspace {0.25pt}l}_T^{(i)}$ is the unique order-preserving function with the following domain and codomain:

$$\begin{align*}\mathrm{f\hspace{0.25pt}l}_T^{(i)} : [K] \setminus \{T(i,\Lambda_i)\} \to [K-1]. \end{align*}$$

Let $T^{(i)}$ be the filling obtained by deleting the cell $(i,\Lambda _i)$ , applying $\mathrm {f\hspace {0.25pt}l}_T^{(i)}$ to the label in each remaining cell and reordering the rows so that the labels in the right-most cells increase from top to bottom. If $i> \ell (\lambda )$ , then $\mathrm {f\hspace {0.25pt}l}_T^{(i)}$ is the unique order-preserving function

$$\begin{align*}\mathrm{f\hspace{0.25pt}l}_T^{(i)} : [K]\setminus (\{T(i,\Lambda_i)\}\cup \{T(i',1) \,|\, i'\neq i\})\to [K-s]. \end{align*}$$

We define $T^{(i)}$ in the same way as the previous case, except we also delete the cells $(i',1)$ for $i'\neq i$ and shift those rows to the left by one unit before applying $\mathrm {f\hspace {0.25pt}l}_T^{(i)}$ and reordering the rows. See Figure 2 for examples.

Given an injective map $w: [n]\to [K]$ , we say w is admissible with respect to T if the image of w contains $[k]$ , and whenever $T(a,b) = w(i)$ for some i, then either $b=\Lambda _a$ or $T(a,b+1) = w(i')$ for some $i'<i$ . It is proven in [Reference Griffin, Levinson and Woo10].

We have the following recursion for the cells $C_w\cap Y_{N_T}$ .

Lemma 2.3 [Reference Griffin, Levinson and Woo10]

Let T be Schubert compatible. The intersection $C_w\cap Y_{N_T}$ is nonempty if and only if w is admissible with respect to T. If $C_w\cap Y_{N_T}$ is nonempty, then there is an isomorphism

(2.12) $$ \begin{align} C_w\cap Y_{N_T}\cong \mathbb{C}^{i-1} \times (C_{\mathrm{f\hspace{0.25pt}l}_T^{(i)}(w)} \cap Y_{N_{T^{(i)}}}), \end{align} $$

where i is such that $w(1) = T(i,\Lambda _i)$ .

Remark 2.4. The proof of Lemma 2.3 given in [Reference Griffin, Levinson and Woo10] can be used without change to show that for any field $\mathbb {F}$ , there is a bijection

(2.13) $$ \begin{align} C_w\cap Y_{N_T}(\mathbb{F})\cong \mathbb{F}^{i-1} \times (C_{\mathrm{f\hspace{0.25pt}l}_T^{(i)}(w)} \cap Y_{N_{T^{(i)}}}(\mathbb{F})). \end{align} $$

We use the symbol $\cong $ throughout the paper to mean a bijection between sets, but all bijections below are easily seen to be isomorphisms of complex algebraic varieties in the case when $\mathbb {F}=\mathbb {C}$ . Furthermore, the term ‘isomorphism’ should be translated as ‘bijection’ in the general setting and as ‘isomorphism of complex algebraic varieties’ in the case $\mathbb {F}=\mathbb {C}$ .

A partial row-decreasing filling (PRD) of $[\Lambda ]$ is a filling of a subset of size n of the cells of $[\Lambda ] = [\Lambda (n,\lambda ,s)]$ with positive integers such that the filled cells are right justified in each row, the labeling weakly decreases along each row, and each cell of $[\lambda ]^r$ is filled. A PRD is standard if the filling uses the labels $1,2,\dots , n$ without repeats.

Given w admissible with respect to T, let $\operatorname {\mathrm {PRD}}_T(w)$ be the standard partial row-decreasing filling of $[\Lambda ]$ such that, for $1\leq i\leq n$ , if $w(i) = T(a,b)$ , then the cell $(a,b)$ of $[\Lambda ]$ is labeled by i. It can be checked that the map $\operatorname {\mathrm {PRD}}_T$ gives a bijection between admissible w and standard partial row-decreasing fillings. Hence, standard partial row-decreasing fillings of $[\Lambda ]$ also index the cells of $Y_{N_T}$ . See Figure 3 for an example of $\operatorname {\mathrm {PRD}}_T(w)$ for T the reading order filling of $[\Lambda (7,(2,2),4)]$ and $w = 2713594$ (where we have listed out the images of $1,2,\dots ,7$ in order).

Figure 3. For T as in Figure 2, the partial row-decreasing filling $\operatorname {\mathrm {PRD}}_T(w)$ associated to the admissible function $w=2713594$ .

2.6. Monomial symmetric function formulas

In [Reference Griffin, Levinson and Woo10], it is shown that the map on cohomology induced by inclusion of varieties

$$\begin{align*}H^{*}(\mathcal{B}^{(1^n)}(\mathbb{C}^K);\mathbb{Q}) \twoheadrightarrow H^{*}(Y_{n,\lambda,s}(\mathbb{C});\mathbb{Q}) \end{align*}$$

is surjective. There is a well-defined $S_n$ action on $H^{*}(Y_{n,\lambda ,s}(\mathbb {C});\mathbb {Q})$ which is the unique one that makes the above map $S_n$ -equivariant. Thus, $H^{*}(Y_{n,\lambda ,s}(\mathbb {C});\mathbb {Q})$ has the structure of a graded $S_n$ -module. In [Reference Griffin9], several formulas for the graded Frobenius characteristic of $H^{*}(Y_{n,\lambda ,s}(\mathbb {C});\mathbb {Q})$ are given, which we recall next.

For $\mu \vdash n$ , let $\operatorname {\mathrm {PRD}}_{n,\lambda ,s}^{\mu }$ be the set of partial row-decreasing fillings of $\Lambda = \Lambda (n,\lambda ,s)$ with $\mu _i$ many i’s. Given such a labeling $\varphi \in \operatorname {\mathrm {PRD}}_{n,\lambda ,s}^{\mu }$ , let $\varphi _{i,j}$ be the label in cell $(i,j)$ . Given a pair of cells $((i,j)$ , $(p,q))$ of $[\Lambda ]$ , we say they are an attacking pair if either $j=q$ and $i<p$ , or if $j = q+1$ and $i> p$ .

Definition 2.5. Given $\varphi \in \operatorname {\mathrm {PRD}}_{n,\lambda ,s}^{\mu }$ , a diagonal inversion of $\varphi $ is an attacking pair $((i,j),(p,q))$ of cells of $[\Lambda ]$ such that one of the following hold:

  1. (D1) $(i,j)$ and $(p,q)$ are filled such that $\varphi _{i,j}> \varphi _{p,q}$ ,

  2. (D2) $(i,j)$ is not filled and $(p,q)$ is filled.

Let $\operatorname {{\mathrm {dinv}}}(\varphi )$ be the number of diagonal inversions of $\varphi $ .

For $\varphi = \operatorname {\mathrm {PRD}}_T(2713594)$ as in Figure 3, $\varphi $ has three diagonal inversions of type (D1); $((1,5),(2,5))$ , $((2,4),(1,3))$ , and $((1,3),(3,3))$ ; and three of type (D2); $((2,3),(3,3))$ , $((4,3),(1,2))$ , and $((2,3),(1,2))$ , so $\operatorname {{\mathrm {dinv}}}(\varphi ) = 6$ .

We have the following restatement of Theorem 1.1.

Theorem 2.6 [Reference Griffin, Levinson and Woo10]

We have

$$\begin{align*}\mathrm{Frob}(H^{*}(Y_{n,\lambda,s}(\mathbb{C});\mathbb{Q}) ;q) = \sum_{\mu\vdash n} \sum_{\varphi\in \operatorname{\mathrm{PRD}}_{n,\lambda,s}^{\mu}} q^{\operatorname{{\mathrm{dinv}}}(\varphi)} m_{\mu}(\mathbf{x}). \end{align*}$$

Remark 2.7. In Corollary 3.7, we show that the statistic $\operatorname {{\mathrm {dinv}}}$ counts the dimensions of the cells of $Y_{N_T}$ when T is the reading order of $[\Lambda ]$ . There is another inversion statistic $\operatorname {{\mathrm {inv}}}$ defined in [Reference Griffin9, Reference Griffin, Levinson and Woo10] that also gives a monomial expansion of the graded Frobenius characteristic of $H^{*}(Y_{n,\lambda ,s}(\mathbb {C});\mathbb {Q})$ . We do not define it here because it does not immediately come from a Schubert compatible filling of the cells of $[\Lambda ]$ . However, it may still be possible to show it counts dimensions of cells of $Y_{N_T}$ for some choice of filling T.

3. Counting $\mathbb {F}_q$ -points of projected $\Delta $ -Springer varieties

In this section, we analyze the projections of the $\Delta $ -Springer variety to other partial flag varieties. We then show that the graded Frobenius characteristic of $H^{*}(Y_{n,\lambda ,s}(\mathbb {C});\mathbb {Q})$ can be written in terms of counting $\mathbb {F}_q$ points of these projected varieties.

Fix $n,\lambda ,s,$ and $k=|\lambda |$ as in Subsection 2.5, let and let .

Definition 3.1. Let $\mu $ be a strong composition of n and let $N_\Lambda $ is a nilpotent matrix of type $\Lambda $ . Define the projected $\Delta $ -Springer variety to be

(3.1)

Lemma 3.2. We have

$$\begin{align*}Y_{n,\lambda,s}^{\mu} = \pi^{\mu}\left(\mathrm{Spalt}_{\Lambda}^{(1^n,(s-1)^{n-k})}\right), \end{align*}$$

where $\pi ^{\mu } : \mathcal {B}^{(1^n,(s-1)^{n-k})}\to \mathcal {B}^{\mu }(\mathbb {F}^K)$ is the usual projection map of partial flag varieties.

Proof. Let $\rho ^{\mu } : \mathcal {B}^{(1^n)}(\mathbb {F}^K)\to \mathcal {B}^{\mu }(\mathbb {F}^K)$ be the usual projection map, which factors through $\pi ^{\mu }$ (i.e., $\pi ^{\mu } = \rho ^{\mu }\circ \pi $ ), where $\pi $ is the projection in (2.9). By (2.9), it is immediate that $\pi ^{\mu }(\mathrm {Spalt}_\Lambda ^{(1^n,(s-1)^{n-k})}) = \rho ^{\mu }(Y_{n,\lambda ,s})$ , which is contained in the right-hand side of (3.1). For the other containment, it is necessary to show that any $V_{\bullet }\in \mathcal {B}^{\mu }(\mathbb {F}^K)$ on the right-hand side can be extended to an element of $Y_{n,\lambda ,s}$ . This follows from the fact that

$$\begin{align*}(\rho^{\mu})^{-1}(V_{\bullet})\cap Y_{n,\lambda,s} \cong \mathcal{B}_{N_1}\times \cdots \times\mathcal{B}_{N_\ell}, \end{align*}$$

where $N_i$ is the nilpotent operator induced by $N_\Lambda $ on $V_i/V_{i-1}$ . Indeed, since each of the Springer fibers in the product is nonempty, then $V_{\bullet }$ can be extended to an element $W_{\bullet }\in Y_{n,\lambda ,s}$ so that $\rho ^{\mu } (W_{\bullet }) = V_{\bullet }$ . Thus, we have equality of the two sets.

For $T:[\Lambda ]\to [K]$ a bijection, we denote by $Y_{N_T}^{\mu }$ the projected $\Delta $ -Springer variety $Y_{n,\lambda ,s}^{\mu }$ for the specific choice of nilpotent $N_T$ , and similarly for $N_T^t$ .

Lemma 3.3. Let T be Schubert compatible and w admissible with respect to T. The projection $\rho ^{\mu } : Y_{N_T} \to Y_{N_T}^{\mu }$ maps $C_w\cap Y_{N_T}$ to $C_{\mathrm {sort}_{\mu }(w)}\cap Y_{N_T}^{\mu }$ . When w is $\mu $ -increasing, $C_w\cap Y_{N_T}$ maps isomorphically onto $C_w\cap Y_{N_T}^{\mu }$ . Thus, when $\mathbb {F}=\mathbb {C}$ , the subspaces $C_w \cap Y_{n,\lambda ,s}^{\mu }(\mathbb {C})$ for w admissible and $\mu $ -increasing are the cells of an affine paving of $Y_{n,\lambda ,s}^{\mu }(\mathbb {C})$ .

Proof. The first part of the lemma is immediate from the fact that $\rho ^{\mu }$ maps $C_w$ to $C_{\mathrm {sort}_{\mu }(w)}$ and the definition of $Y_{N_T}^{\mu }$ . Let w be $\mu $ -increasing. Since $\rho ^{\mu }:\mathcal {B}^{(1^n)}(\mathbb {F}^K)\to \mathcal {B}^{\mu }(\mathbb {F}^K)$ maps $C_w$ isomorphically onto $C_w\subseteq \mathcal {B}^{\mu }(\mathbb {F}^K)$ , then the restriction of $\rho ^{\mu }$ to $C_w\cap Y_{N_T}$ maps $C_w\cap Y_{N_T}$ isomorphically onto its image, so it suffices to show that $C_w\cap Y_{N_T}$ maps surjectively onto $C_w\cap Y_{N_T}^{\mu }$ .

Let $V_{\bullet }\in C_w\cap Y_{N_T}^{\mu }$ . For each i, let $v_1,\dots ,v_n$ be the vectors such that for $p\in \mu [i]$ , we have $v_p\in V_i\setminus V_{i-1}$ , $v_p$ has leading term $f_{w(p)}$ , and

(3.2) $$ \begin{align} v_{p} =f_{w(p)}+\sum_{h=1}^{w(p)-1} \beta_{w(p),h}\, f_h \end{align} $$

for some $\beta _{w(p),h}$ such that $\beta _{w(p),h}=0$ if $h\in \{w(1),\ldots ,w(p-1)\}$ . We claim that the partial flag $W_{\bullet }\in \mathcal {B}^{(1^n)}(\mathbb {F}^K)$ defined by $W_i = \mathrm {span}\{v_1,\dots , v_i\}$ for $i\leq n$ is in $Y_{N_T}$ . Indeed, since $N_T V_i\subseteq V_i$ , then $N_TW_{\mu _i}\subseteq W_{\mu _i}$ for all i. For $\mu _1+\cdots +\mu _{i-1}+1 \leq p\leq \mu _1+\cdots +\mu _i$ , then $N_Tv_p\in W_{\mu _i}$ . Let $(a,b)$ be the coordinates of the label $w(p)$ in T, so $w(p) = T(a,b)$ . Since T is Schubert compatible, either $N_Tv_p=0$ or the leading term of $N_Tv_p$ is $N_Tf_{w(p)}=f_{T(a,b+1)}$ . In the latter case, since w is admissible with respect to T, then $T(a,b+1)=w(p')$ for some $p'<p$ . Since w is $\mu $ -increasing, we have $w(p')\notin \{p+1,\dots , \mu _i\}$ , so the expansion of $N_Tv_p$ into the $v_i$ vectors cannot have any terms with nonzero coefficient on $v_{p+1},\dots , v_{\mu _i}$ (otherwise the leading term would not be $f_{w(p')}$ ); hence, $N_Tv_p\in W_p$ . Therefore, we have the containment $N_TW_p\subseteq W_p$ for all p.

Since $N_T^{n-k}\mathbb {F}^{|\Lambda |} \subseteq V_{\ell (\mu )} = W_n$ , then we have $W_{\bullet }\in Y_{n,\lambda ,s}$ and by construction, $\rho ^{\mu }(W_{\bullet }) = V_{\bullet }$ , so $\rho ^{\mu }$ maps $C_w\cap Y_{n,\lambda ,s}$ surjectively, hence isomorphically, onto $C_w\cap Y_{n,\lambda ,s}^{\mu }$ .

When $\mathbb {F}=\mathbb {C}$ , since $C_w\cap Y_{n,\lambda ,s}$ is isomorphic to an affine space, then $C_w\cap Y_{n,\lambda ,s}^{\mu }$ is as well. Since the $C_w$ are cells of an affine paving of $\mathcal {B}^{\mu }(\mathbb {C}^K)$ , then the intersections $C_w\cap Y_{n,\lambda ,s}^{\mu }(\mathbb {C})$ for $\mu $ -increasing w are the cells of an affine paving of $Y_{n,\lambda ,s}^{\mu }(\mathbb {C})$ .

Recall that for T Schubert compatible and w admissible with respect to T, $\operatorname {\mathrm {PRD}}_T(w)$ is defined to be the row-decreasing filling of $[\Lambda ]$ such that if $w(i) = T(p,q)$ , then the cell $(p,q)$ is labeled by i. Equivalently, if we let $\operatorname {\mathrm {PRD}}_T(w)^{-1}(a)$ be the position of the label a in $\operatorname {\mathrm {PRD}}_T(w)$ , we have

(3.3) $$ \begin{align} w(a) = T(\operatorname{\mathrm{PRD}}_T(w)^{-1}(a)). \end{align} $$

Definition 3.4. For T Schubert compatible and w admissible with respect to T, an inversion of w with respect to T is a pair $(c,i)$ with $1\leq c\leq n$ , $1\leq i\leq s$ such that one of the following conditions holds:

  1. (IT1) There exists a label $\ell>c$ of $\operatorname {\mathrm {PRD}}_T(w)$ in row i such that $w(\ell ) < w(c)$ ,

  2. (IT2) The condition (IT1) does not hold, and there exists an empty cell $(i,j)$ of $\operatorname {\mathrm {PRD}}_T(w)$ in row i such that $T(i,j) < w(c)$ .

Define $\operatorname {{\mathrm {inv}}}_T(w)$ to be the number of such pairs.

For example, letting T be as in Figure 2 (reading order for $\Lambda (7,(2,2),4)$ ) and $w=2713594$ as in Figure 3, then the inversions of w with respect to T of type (IT1) are $(c,i) = (1,1), (2,1)$ and $(5,2)$ , and those of type (IT2) are $(c,i) = (2,2), (6,2)$ and $(6,4)$ . Thus, $\operatorname {{\mathrm {inv}}}_T(w) = 6$ .

Lemma 3.5. Let T be a Schubert-compatible filling of $[\Lambda ]$ . If w is admissible with respect to T and $\mu $ -increasing, then

$$\begin{align*}C_w \cap Y_{N_T}^{\mu} \cong \mathbb{F}^{\operatorname{{\mathrm{inv}}}_T(w)}. \end{align*}$$

Proof. By Lemma 3.3, it suffices to prove the result for the case $\mu = (1^n)$ . We proceed by induction on n. In the base case when $n=0$ (and s is arbitrary), then $\lambda = \emptyset $ , and the unique admissible w is the empty function $w=\emptyset $ . Furthermore, $C_\emptyset \cap Y_{N_T} = Y_{N_T}$ is a single point and $\operatorname {{\mathrm {inv}}}_T(w) = 0$ . Thus, the base case holds.

Let $n\geq 1$ and T and w be arbitrary with $w(1) = T(i,\Lambda _i)$ . To complete the induction, by Lemma 2.3, it suffices to show

(3.4) $$ \begin{align} \operatorname{{\mathrm{inv}}}_T(w) - \operatorname{{\mathrm{inv}}}_{T^{(i)}}\left(\mathrm{f\hspace{0.25pt}l}_T^{(i)}(w)\right) = i-1. \end{align} $$

First, we claim that the left-hand side of (3.4) is the number of inversions of w with respect to T that are of the form $(1,i')$ . Indeed, there is an injective map from the inversions of $\mathrm {f\hspace {0.25pt}l}_T^{(i)}(w)$ with respect to $T^{(i)}$ to the inversions of w with respect to T by sending $(c,r)$ to $(c+1,r')$ , where $r'$ is the row of T corresponding to row r of $T^{(i)}$ in the row-sorting step of forming $T^{(i)}$ . The inversions of w that are not in the image of this map are those of the form $(1,i')$ , together with inversions of w of the form $(c,r)$ with $c>1$ of type (IT2) that involve an empty cell $(p,1)$ that was deleted from T to form $T^{(i)}$ in the case when $i>\ell (\lambda )$ . However, observe that $[\Lambda ]/[\lambda ]^r$ has $n-k$ cells in each row, and the number of labels in $[\Lambda ]/[\lambda ]^r$ is $n-k$ . Therefore, since both $1$ and c are not in row p, both entries $(p,1)$ and $(p,2)$ are empty, and $T(p,2) < T(p,1) < w(c)$ , so $(c,p)$ is in the image of the injective map described above. Thus, the left-hand side of (3.4) only counts inversions of w of the form $(1,i')$ .

Second, we claim that $(1,i')$ is an inversion if and only if $i'<i$ . Indeed, if $i'<i$ , then $T(i',\Lambda _{i'}) < T(i,\Lambda _i)=w(1)$ since T is Schubert compatible. If $(i',\Lambda _{i'})$ is filled in $\operatorname {\mathrm {PRD}}_T(w)$ , let its label be $\ell $ . Since w is injective, then $\ell>1$ . Furthermore, $w(\ell ) = T(\operatorname {\mathrm {PRD}}_T(w)^{-1}(\ell )) = T(i',\Lambda _{i'}) < w(1)$ ; thus, $(1,i')$ is an inversion of type (IT1). Otherwise, $(i',\Lambda _{i'})$ is not filled in $\operatorname {\mathrm {PRD}}_T(w)$ , so since $T(i',\Lambda _{i'}) < w(1)$ , then $(1,i')$ is an inversion of type (IT2).

Suppose $(1,i')$ is an inversion for some $i'\geq i$ . Then in either of the cases (IT1) or (IT2), there exists a cell $(i',j')$ in row $i'$ such that $T(i',j') < w(1) = T(i,\Lambda _i)$ (where $T(i',j') = w(\ell )$ in the (IT1) case). By Schubert compatibility, we have $T(i,\Lambda _i) \leq T(i',\Lambda _{i'}) \leq T(i',j')$ , a contradiction. Therefore, $(1,i')$ is an inversion if and only if $i'<i$ , so the number of inversions counted by the left-hand side of (3.4) is $i-1$ . The inductive step is thus complete.

Lemma 3.6. Let T be the reading order filling of $[\Lambda ]$ . For all w admissible with respect to T, we have $\operatorname {{\mathrm {inv}}}_T(w) = \operatorname {{\mathrm {dinv}}}(\operatorname {\mathrm {PRD}}_T(w))$ .

Proof. Let $\varphi = \operatorname {\mathrm {PRD}}_T(w)$ . We define a map from diagonal inversions of $\varphi $ to inversions of w with respect to T as follows. For each diagonal inversion $((i,j),(p,q))$ , let its corresponding inversion of w be $(\varphi _{p,q},i)$ . The pair $(\varphi _{p,q},i)$ is indeed an inversion. If $((i,j),(p,q))$ is a type (D1) inversion, then $(\varphi _{p,q},i)$ is a type (IT1) inversion, where $\ell =\varphi _{i,j}$ . If $((i,j),(p,q))$ is type (D2), then $(\varphi _{p,q},i)$ is type (IT1) or type (IT2) depending on whether there exists a label $\ell>\varphi _{p,q}$ in row i of $\varphi $ or not, respectively. We claim that the map defined above is a bijection between diagonal inversions of $\varphi $ and inversions of w with respect to T.

To show bijectivity, we give the inverse bijection, as follows. Given $(c,i)$ an inversion of w, let $(p,q)$ be the coordinates of the label c in $\varphi $ . If $(c,i)$ is of type (IT1), then there exists a label $\ell>c$ in row i of $\varphi $ such that $w(\ell ) < w(c)$ . Since $w(\ell ) < w(c)$ , then either $i<p$ and $\ell $ is in a cell above and weakly to the right of c, or $i>p$ and $\ell $ is in a cell below and strictly to the right of c. In the first case, $(c,i)$ corresponds to the diagonal inversion $((i,q),(p,q))$ . Indeed, the cell $(i,q)$ is either empty in $\varphi $ , so $((i,q),(p,q))$ is a type (D2) diagonal inversion, or the cell $(i,q)$ is labeled and $\varphi _{i,q} \geq \ell> c$ by the row-decreasing property of $\varphi $ so $((i,q),(p,q))$ is a type (D1) diagonal inversion. In the second case when $i>p$ , then $(c,i)$ corresponds to the diagonal inversion $((i,q+1),(p,q))$ . Indeed, the cell $(i,q+1)$ is either empty in $\varphi $ , so $((i,q+1),(p,q))$ is a type (D2) diagonal inversion, or the cell $(i,q+1)$ is labeled and $\varphi _{i,q+1}\geq \ell> c$ so $((i,q+1),(p,q))$ is a type (D1) diagonal inversion.

Finally, if $(c,i)$ is of type (IT2), then there exists an empty cell $(i,j)$ in $\varphi $ such that $T(i,j) < w(c)$ . Then either $i<p$ and $((i,q),(p,q))$ is a diagonal inversion of type (D2), or $i>p$ and $((i,q+1),(p,q))$ is a diagonal inversion of type (D2). It can then be checked that this is the inverse map, and hence, the number of inversions of w with respect to T is equal to the number of diagonal inversions of $\varphi $ .

Combining Lemma 3.6 with Lemma 3.5, we see that $\operatorname {{\mathrm {dinv}}}$ has geometric meaning: it counts the dimensions of cells in $Y_{N_T}$ .

Corollary 3.7. For T the reading order filling of $[\Lambda ]$ and w that is $\mu $ -increasing and admissible with respect to T, we have

(3.5) $$ \begin{align} C_w\cap Y_{N_T}^{\mu} &\cong \mathbb{F}^{\operatorname{{\mathrm{dinv}}}(\operatorname{\mathrm{PRD}}_T(w))}. \end{align} $$

We are now able to prove the main theorem of this section.

Theorem 3.8. For all prime powers q, we have

$$\begin{align*}\mathrm{Frob}(H^{*}(Y_{n,\lambda,s}(\mathbb{C});\mathbb{Q});q) = \sum_{\mu\vdash n}|Y_{n,\lambda,s}^{\mu}(\mathbb{F}_q)|\, m_{\mu}(\mathbf{x}).\end{align*}$$

Proof. Let T be the reading order filling of $[\Lambda ]$ and let $\mu \vdash n$ . We claim that

(3.6) $$ \begin{align} \sum_{\varphi \in \operatorname{\mathrm{PRD}}_{n,\lambda,s}^{\mu}} q^{\operatorname{{\mathrm{dinv}}}(\varphi)} = \sum_{\substack{w \text{ admissible wrt }T,\\ \mu\text{-increasing}}} q^{\operatorname{{\mathrm{dinv}}}(\operatorname{\mathrm{PRD}}_T(w))}. \end{align} $$

Indeed, given w admissible with respect to T that is $\mu $ -increasing, define $\varphi \in \operatorname {\mathrm {PRD}}_{n,\lambda ,s}^{\mu }$ by replacing the labels $\mu _1+\cdots +\mu _{i-1}+1, \mu _1+\cdots +\mu _{i-1}+2,\dots , \mu _1+\cdots +\mu _{i}$ in $\operatorname {\mathrm {PRD}}_T(w)$ with i for each $i\leq \ell (\mu )$ . Since w is $\mu $ -increasing, then the labels $\mu _1+\cdots +\mu _{i-1}+1, \mu _1+\cdots +\mu _{i-1}+2,\dots , \mu _1+\cdots +\mu _{i}$ in $\operatorname {\mathrm {PRD}}_T(w)$ are increasing in reading order, so there are no diagonal inversions among these labels. Therefore, it follows from the definition of $\operatorname {{\mathrm {dinv}}}$ that $\operatorname {{\mathrm {dinv}}}(\varphi ) = \operatorname {{\mathrm {dinv}}}(\operatorname {\mathrm {PRD}}_T(w))$ .

Using (3.6), we have

(3.7) $$ \begin{align} \mathrm{Frob}(H^{*}(Y_{n,\lambda,s}(\mathbb{C});\mathbb{Q});q) &= \sum_{\mu\vdash n} \sum_{\varphi \in \operatorname{\mathrm{PRD}}_{n,\lambda,s}^{\mu}} q^{\operatorname{{\mathrm{dinv}}}(\varphi)} m_{\mu}(\mathbf{x}) \end{align} $$
(3.8) $$ \begin{align} &= \sum_{\mu\vdash n} \,\,\sum_{\substack{w \text{ admissible wrt }T,\\ \mu\text{-increasing}}} |C_w \cap Y_{N_T}^{\mu}(\mathbb{F}_q)| m_{\mu}(\mathbf{x}) \end{align} $$
(3.9) $$ \begin{align} & = \sum_{\mu \vdash n} |Y_{N_T}^{\mu}(\mathbb{F}_q)| m_{\mu}(\mathbf{x}). \end{align} $$

The first equality is Theorem 2.6, the second follows from Corollary 3.7 and the fact that $\operatorname {\mathrm {PRD}}_T$ restricts to a bijection between the set of w that are admissible and $\mu $ -increasing and $\operatorname {\mathrm {PRD}}_{n,\lambda ,s}^{\mu }$ , and the third equality follows from the fact that the intersections $C_w\cap Y_{N_T}^{\mu }$ for w that are admissible with respect to T and $\mu $ -increasing partition the space $Y_{N_T}^{\mu }$ by Lemma 3.3.

As a corollary, we obtain the following generalization of Borho and Macpherson’s result (2.8).

Corollary 3.9. For all $\mu \vdash n$ , we have an isomorphism of graded vector spaces

(3.10) $$ \begin{align} H^{*}(Y_{n,\lambda,s}^{\mu}(\mathbb{C});\mathbb{Q}) \cong H^{*}(Y_{n,\lambda,s}(\mathbb{C});\mathbb{Q})^{S_{\mu}}. \end{align} $$

Proof. By Frobenius reciprocity (see, for example, [Reference Brosnan and Chow3]), the $m_{\mu }(\mathbf {x})$ coefficient of the graded Frobenius characteristic of a graded $S_n$ -module is the Hilbert series of the $S_{\mu }$ -invariant subspace. By Theorem 3.8, applying this fact to the cohomology of $Y_{n,\lambda ,s}(\mathbb {C})$ yields

(3.11) $$ \begin{align} |Y_{n,\lambda,s}^{\mu}(\mathbb{F}_q)| = \mathrm{Hilb}(H^{*}(Y_{n,\lambda,s}(\mathbb{C});\mathbb{Q})^{S_{\mu}};q) \end{align} $$

for all prime powers q. By the last part of Lemma 3.3,

$$\begin{align*}\mathrm{Hilb}(H^{*}(Y_{n,\lambda,s}^{\mu}(\mathbb{C});\mathbb{Q});q) = \sum_{\substack{w \text{ admissible wrt }T,\\ \mu\text{-increasing}}} q^{\dim_{\mathbb{C}}(C_w \cap Y_{N_T}^{\mu}(\mathbb{C}))}. \end{align*}$$

By (2.13), it can be checked by induction that $|C_w\cap Y_{N_T}^{\mu }(\mathbb {F}_q)| = q^{\dim _{\mathbb {C}}(C_w \cap Y_{N_T}^{\mu }(\mathbb {C}))}$ for each w admissible and $\mu $ -increasing. Since the $C_w\cap Y_{N_T}^{\mu }(\mathbb {F}_q)$ partition $\mathbb {F}_q$ , we have

(3.12) $$ \begin{align} |Y_{n,\lambda,s}^{\mu}(\mathbb{F}_q)| = \mathrm{Hilb}(H^{*}(Y_{n,\lambda,s}^{\mu}(\mathbb{C});\mathbb{Q});q). \end{align} $$

Combining (3.11) and (3.12), the two spaces have the same Hilbert series and are hence isomorphic as graded vector spaces.

Remark 3.10. We note that a second proof of Corollary 3.9 has been given by Gillespie and the author [Reference Gillespie and Griffin7] by realizing $Y_{n,\lambda ,s}$ as a special case of a variety studied by Borho and MacPherson in their study of partial resolutions of nilpotent orbit closures [Reference Borho and MacPherson2].

4. A Springer fiber decomposition of $Y_{n,\lambda ,s}$

In this section, we decompose the $\Delta $ -Springer variety $Y_{n,\lambda ,s}^{\mu }$ into subspaces that are isomorphic to Steinberg varieties crossed with affine spaces, so, in particular, $Y_{n,\lambda ,s}$ decomposes into copies of Springer fibers crossed with affine spaces. We then use this to prove our expansion of the graded Frobenius characteristic of the cohomology ring in terms of Hall-Littlewood polynomials in Section 5.

Definition 4.1. The reverse reading order of $[\Lambda ]$ is the sequence of cells obtained by reading down each column of $[\Lambda ]$ , ordering the columns from left to right. The reverse reading order filling of $[\Lambda ]$ is the unique bijection $T:[\Lambda ]\to [K]$ such that $T(i,j) = \ell $ if and only if $(i,j)$ is the $\ell $ th cell in reverse reading order.

Note that in reverse reading order, only the order of the columns are reversed (not the order of the rows). See Figure 4 for the reverse reading order filling of $[\Lambda (7,(2,2),4]$ .

Figure 4. The reverse reading order filling T for $[\Lambda (7,(2,2),4)]$ , with $[\lambda ] = [(2,2)]$ shaded in orange. The diagram of $\alpha = (2,4,0,1)\in \mathrm {Comp}(7,4)$ is the union of the orange and blue cells.

Throughout this section, we let T be the reverse reading order filling of $[\Lambda ]$ . For notational convenience, we use the simplified notation and .

Given $\alpha \in \mathrm {Comp}(n,s)$ such that $\lambda \subseteq \alpha $ , let $[\alpha ]$ be the subdiagram of $[\Lambda ]$ defined by

Note that the inequality $\alpha _i\leq \Lambda _i = (n-k)+\lambda _i$ is guaranteed for all i by the fact that $\alpha $ has size n and contains $\lambda $ (which has size k), so $[\alpha ]$ is indeed a subdiagram of $[\Lambda ]$ .

Let $\mathbb {F}^\alpha \subseteq \mathbb {F}^K$ , which is the subspace spanned by $f_{i}$ for i a label of T contained in $[\alpha ]$ . Similarly, let be the subspace spanned by $f_i$ for i a label of T contained in $[\lambda ]$ .

Let $w: [n]\to [K]$ be the unique $(n)$ -increasing injective function whose image is the set of labels of T in $[\alpha ]$ , and let $C_{w}$ be the corresponding Schubert cell in the Grassmannian $\mathcal {B}^{(n,K-n)} = \mathrm {Gr}(n,\mathbb {F}^K)$ . Define

(4.1)
(4.2)

Note that since $N^t$ restricts to a nilpotent matrix on the subspace $\mathbb {F}^\alpha $ with Jordan type $\mathrm {sort}(\alpha )$ , then $Z_\alpha ^{\mu }\cong \mathrm {Stein}_{\mathrm {sort}(\alpha )}^{\mu }$ .

The following is the main theorem of this section. In the case $\mu = (1^n)$ , it says that the subspaces $\widehat {Z}_{\alpha }$ , which partition $Y_{n,\lambda ,s}$ , are isomorphic to a Springer fiber crossed with an affine space.

Theorem 4.2. We have

$$\begin{align*}\widehat{Z}^{\mu}_\alpha \cong \mathbb{F}^\ell\times Z_\alpha^{\mu}, \end{align*}$$

where $\ell = \sum _i (s-\alpha _i^{\prime })(\alpha _{i+1}^{\prime }-\lambda _{i+1}^{\prime }) + \operatorname {\mathrm {coinv}}(\alpha )$ (where $\operatorname {\mathrm {coinv}}$ was defined at the end of Subsection 2.1) and $\alpha _i^{\prime }$ is the number of cells of $[\alpha ]$ in the ith column where .

In order to prove Theorem 4.2, we need several definitions and lemmata.

Definition 4.3. A pair $(i,j)$ with $i>j$ is a free pair for $\alpha $ if the cell with label i of T is in $[\alpha ]/[\lambda ]$ and the cell with label j of T is the leftmost cell of $[\Lambda ]\setminus [\alpha ]$ in j’s own row.

Remark 4.4. Let w be the unique admissible $(n)$ -increasing injective function whose image is the set of labels of T in $[\alpha ]$ , as above. Free pairs $(i,j)$ are defined to correspond to a subset of standard coordinates $\beta _{i,j}$ of $C_w$ . Note that $\beta _{i,j}$ is undefined unless i is in the image of w, and that if i is in the image of w, then $\beta _{i,j}=0$ if j is a label in $[\alpha ]$ .

Example 4.5. For $n=7$ , $\lambda = (2,2)$ , $s=4$ and $\alpha = (2,4,0,1)$ as depicted in Figure 4, the free pairs are $(14,9)$ , $(14,8)$ , $(14,3)$ , $(10,9)$ , $(10,8)$ , $(10,3)$ and $(4,3)$ .

Lemma 4.6. The number of free pairs of $\alpha $ is

(4.3) $$ \begin{align} \sum_i (s-\alpha_i^{\prime})(\alpha_{i+1}^{\prime} -\lambda_{i+1}^{\prime}) + \operatorname{\mathrm{coinv}}(\alpha). \end{align} $$

Proof. Let $(i,j)$ be a free pair for $\alpha $ . If i and j are not in the same column, in which case j must be in a column to the left of i, then associate $(i,j)$ to the pair $(i,j')$ , where $j'$ is the label in the same row as j and in the column immediately to the left of the column of i. This correspondence sets up a bijection between free pairs in which i and j are not in the same column and pairs $(i,j')$ where i is a label in $[\alpha ]\setminus [\lambda ]$ and $j'$ is a label in $[\Lambda ]\setminus [\alpha ]$ in the column immediately to the left of i. Counting these latter pairs by the column containing i, we have the sum

(4.4) $$ \begin{align} \sum_p (s-\alpha_p^{\prime}) (\alpha_{p+1}^{\prime} - \lambda_{p+1}^{\prime}). \end{align} $$

If i and j are in the same column, then associate the free pair $(i,j)$ to the coinversion $(r,r')$ of $\alpha $ , where r is the row of j and $r'$ is the row of i. Indeed, $(r,r')$ is a coinversion since $r<r'$ by the fact that $i>j$ and the definition of reverse reading order, and $\alpha _r<\alpha _{r'}$ since i is in $[\alpha ]$ and j is not. This correspondence is a bijection between free pairs with i and j in the same column and coinversions of $\alpha $ . Thus, the total number of free pairs is given by (4.3).

Example 4.7. For $\alpha $ as in Example 4.5, the free pairs $(10,9)$ and $(4,3)$ contribute to $\operatorname {\mathrm {coinv}}(\alpha )$ in (4.3). The terms of (4.4) are: $1\cdot 0$ for $p=1$ , $2\cdot 1$ for $p=2$ corresponding to pairs $(10,3)$ and $(10,8)$ , $3\cdot 1$ for $p=3$ corresponding to pairs $(14,9)$ , $(14, 3)$ and $(14,8)$ , and $1\cdot 0$ for $p=4$ .

Definition 4.8. For $(i,j)$ a free pair with $i>j$ , let $U_{i,j}(t)$ be the $K\times K$ matrix such that

(4.5) $$ \begin{align} U_{i,j}(t) (N^mf_i) &= N^m(f_i+tf_j) &\text{for } m\geq 0 \text{ such that } N^m f_i \neq 0, \end{align} $$
(4.6) $$ \begin{align} U_{i,j}(t) ((N^t)^mf_i) &= (N^t)^m(f_i+tf_j) &\text{for } m\geq 0, \end{align} $$

and $U_{i,j}(t)f_\ell =f_\ell $ for all labels $\ell $ of T that are not in the same row as i.

Similarly, let $\widehat {U}_{i,j}(t)$ be the matrix such that

(4.7) $$ \begin{align} \widehat{U}_{i,j}(t) (N^mf_i) &= N^m (f_i + tf_j) &\text{for } m\geq 0 \text{ such that } N^m f_i \neq 0 \end{align} $$

and $\widehat {U}_{i,j}(t) f_\ell =f_\ell $ for all labels $\ell $ of T that are either not in the same row as i or not weakly to the right of i.

Example 4.9. Continuing our running Example 4.5, the operator $U_{14,9}(t)$ is defined by

  • $U_{14,9}(t)f_{14} = f_{14} + tf_9$ ,

  • $U_{14,9}(t)f_{16} = f_{16} + tf_{13}$ ,

  • $U_{14,9}(t)f_{10} = f_{10} + tf_5$ ,

  • $U_{14,9}(t)f_{6} = f_{6} + tf_1$ ,

  • $U_{14,9}(t)f_{2} = f_{2} + 0$ ,

and $U_{14,9}(t)f_{\ell } = f_{\ell }$ for all $\ell \notin \{2,6,10,14,16\}$ . However,

  • $\widehat {U}_{14,9}(t) f_{14} = f_{14} + tf_9$ ,

  • $\widehat {U}_{14,9}(t) f_{16} = f_{16} + tf_{13}$ ,

and $\widehat {U}_{14,9}(t)f_\ell = f_\ell $ for all $\ell \notin \{14,16\}$ .

Lemma 4.10. The matrices $U_{i,j}(t)$ and $\widehat {U}_{i,j}(t)$ are unipotent upper triangular.

Proof. By construction, $U_{i,j}(t)$ has $1$ s along the diagonal, so it suffices to check it is upper triangular. Thus, it suffices to check that for all m, the vector $N^mf_i$ has index greater than the vector $N^m f_j$ (if both are nonzero), and the vector $(N^t)^mf_i$ has index greater than the vector $(N^t)^mf_j$ (if both are nonzero). Both of these claims follow immediately from the definition of free pairs and reverse reading order. The same reasoning applies to $\widehat {U}_{i,j}(t)$ .

Lemma 4.11. Let $(i_1,j_1),(i_2,j_2),\dots ,(i_\ell ,j_\ell )$ be the free pairs for $\alpha $ listed so that $i_1\geq i_2\geq \cdots \geq i_\ell $ . Then for all $p\leq \ell $ ,

(4.8) $$ \begin{align} U_{i_{p},j_{p}}(t_{p})\,U_{i_{p-1},j_{p-1}}(t_{p-1})\cdots U_{i_1,j_1}(t_1)\,\mathbb{F}^\alpha = \widehat{U}_{i_{p},j_{p}}(t_{p})\,\widehat{U}_{i_{p-1},j_{p-1}}(t_{p-1})\cdots \widehat{U}_{i_1,j_1}(t_1)\,\mathbb{F}^\alpha. \end{align} $$

Proof. We proceed by induction on p. The base case $p=0$ is trivial, so suppose that for some $p\geq 0$ , (4.8) holds. It suffices to show that

(4.9) $$ \begin{align} U_{i_{p+1},j_{p+1}}(t_{p+1})\widehat{U}_{i_{p},j_{p}}(t_{p})\cdots \widehat{U}_{i_1,j_1}(t_1)\mathbb{F}^\alpha = \widehat{U}_{i_{p+1},j_{p+1}}(t_{p+1})\widehat{U}_{i_{p},j_{p}}(t_{p})\cdots \widehat{U}_{i_1,j_1}(t_1)\mathbb{F}^\alpha. \end{align} $$

Let $v\in \widehat {U}_{i_{p},j_{p}}(t_{p})\cdots \widehat {U}_{i_1,j_1}(t_1)\mathbb {F}^\alpha $ . Since the image of the operator $U_{i_{p+1},j_{p+1}}(t_{p+1})-\widehat {U}_{i_{p+1},j_{p+1}}(t_{p+1})$ is contained in the span of the vectors $(N^t)^m f_{j_{p+1}}$ for $m>0$ (in fact, they are equal when $t_{p+1}\neq 0$ ), then

(4.10) $$ \begin{align} U_{i_{p+1},j_{p+1}}(t_{p+1})v - \widehat{U}_{i_{p+1},j_{p+1}}(t_{p+1})v \end{align} $$

is a linear combination of the vectors $(N^t)^mf_{j_{p+1}}$ for $m>0$ . For a fixed $m>0$ , let $f_{j'} = (N^t)^mf_{j_{p+1}}$ . Then $j'$ is in a column strictly to the left of $i_q$ for all $q\leq p+1$ . Since the operators $\widehat {U}_{i_q,j_q}(t_q)$ for $q\leq p+1$ fix $f_{j'}$ , and since $f_{j'}\in \mathbb {F}^\alpha $ , then

$$ \begin{align*}f_{j'} \in \widehat{U}_{i_{p},j_{p}}(t_{p})\cdots \widehat{U}_{i_1,j_1}(t_1)\mathbb{F}^\alpha.\end{align*} $$

Furthermore, since $j'$ is not in the same row as $i_{p+1}$ , then $U_{i_{p+1},j_{p+1}}(t_{p+1})$ and $\widehat {U}_{i_{p+1},j_{p+1}}(t_{p+1})$ fix $f_{j'}$ , so $f_{j'}$ is in both sides of (4.9). Therefore, (4.10) is in the intersection of the left-hand side and right-hand side of (4.9). Since $U_{i_{p+1},j_{p+1}}(t_{p+1})v$ and $\widehat {U}_{i_{p+1},j_{p+1}}(t_{p+1})v$ are arbitrary elements of the left- and right-hand sides of (4.9), respectively, then the two sets are equal. The induction is thus complete.

Example 4.12. For our running example and $(i_1,j_1) = (14,9)$ , then $U_{14,9}(t) - \widehat {U}_{14,9}(t)$ sends $f_{10}$ to $tf_5$ and $f_6$ to $tf_1$ (and everything else to $0$ ) but both $tf_5$ and $tf_1$ are in $\mathbb {F}^\alpha $ and fixed by both $U_{14,9}(t)$ and $\widehat {U}_{14,9}(t)$ , so $U_{14,9}(t)\mathbb {F}^\alpha = \widehat {U}_{14,9}(t)\mathbb {F}^\alpha = \mathrm {span}\{f_{14} + tf_9, f_{10},f_6,f_5,f_4,f_2,f_1\}$ .

Lemma 4.13. Let $(i_1,j_1),(i_2,j_2),\dots , (i_\ell ,j_\ell )$ be the free pairs for $\alpha $ , listed so that $i_1\geq i_2\geq \cdots \geq i_\ell $ . Then we have a well-defined map

$$\begin{align*}\mathbb{F}^\ell \times Z^{\mu}_\alpha \to \widehat{Z}^{\mu}_\alpha \end{align*}$$

defined by sending $(\vec {t},V_{\bullet })$ to ${U}_{i_\ell ,j_\ell }(t_\ell )\cdots {U}_{i_2,j_2}(t_2) {U}_{i_1,j_1}(t_1)V_{\bullet }$ .

Proof. Letting $V_{\bullet }\in Z^{\mu }_\alpha $ , it suffices to show that ${U}_{i_\ell ,j_\ell }(t_\ell )\cdots {U}_{i_2,j_2}(t_2) {U}_{i_1,j_1}(t_1)V_{\bullet } \in \widehat {Z}^{\mu }_\alpha $ . Since each ${U}_{i_p,j_p}(t_p)$ is unipotent upper triangular by Lemma 4.10 and $V_n=\mathbb {F}^\alpha \in C_{w}$ , then

$$\begin{align*}U_{i_\ell,j_\ell}(t_\ell)\cdots U_{i_2,j_2}(t_2) U_{i_1,j_1}(t_1)V_n \in C_{w}. \end{align*}$$

By construction, we have $U_{i_p,j_p}(t_p) N^t = N^t U_{i_p,j_p}(t_p)$ for all $p\leq \ell $ , so $N^t$ preserves each part of the partial flag $U_{i_\ell ,j_\ell }(t_\ell )\cdots U_{i_2,j_2}(t_2) U_{i_1,j_1}(t_1)V_{\bullet }$ .

Finally, we must check that ${U}_{i_\ell ,j_\ell }(t_\ell )\cdots {U}_{i_2,j_2}(t_2) {U}_{i_1,j_1}(t_1)V_n \supseteq \mathbb {F}^\lambda $ . Indeed, this follows from the fact that $V_n = \mathbb {F}^\alpha \supseteq \mathbb {F}^\lambda $ , Lemma 4.11, and the fact that each $\widehat {U}_{i_p,j_p}(t_p)$ fixes $\mathbb {F}^\lambda $ . Thus, the map is well defined.

Example 4.14. For our running example with $n=7$ , $\lambda = (2,2)$ , $s=4$ and $\alpha = (2,4,0,1)$ , one (of many) partial flags in $Z_\alpha ^{(1^7)}$ is the one represented by the $K\times n$ matrix A below (we do not need the full $K\times K$ matrix because the span of the first n columns completely determines the type $(1^n,K-n)$ partial flag). The reader can check that the matrix representative of the partial flag

$$\begin{align*}U_{4,3}(t_7)U_{10,3}(t_6)U_{10,8}(t_5)U_{10,9}(t_4)U_{14,3}(t_3)U_{14,8}(t_2)U_{14,9}(t_1)\end{align*}$$

is the matrix B below.

$$\begin{align*}A = \begin{bmatrix} 0 & 0 & 3 & 0 & 1 & 0 & 0\\ 1 & 0 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & 0 & 0 & 6 & 1\\ 0 & 0 & 0 & 3 & 0 & 1 & 0\\ 0 & 1 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & 1 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & 1 & 0 & 0 & 0\\ 0 & 0 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & 0 & 0 & 0 & 0 \end{bmatrix} \qquad B = \begin{bmatrix} t_4 & t_1 & 3 & 0 & 1 & 0 & 0\\ 1 & 0 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & t_6 & t_3 & 0 & 0 & t_7\\ 0 & t_5 & t_2 & 0 & 0 & 6 & 1\\ 0 & t_4 & t_1 & 3 & 0 & 1 & 0\\ 0 & 1 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & t_6 & 0 & 0 & 0\\ 0 & 0 & t_5 & t_2 & 0 & 0 & 0\\ 0 & 0 & t_4 & t_1 & 0 & 0 & 0\\ 0 & 0 & 1 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & t_5 & 0 & 0 & 0\\ 0 & 0 & 0 & t_4 & 0 & 0 & 0\\ 0 & 0 & 0 & 1 & 0 & 0 & 0\\ 0 & 0 & 0 & 0 & 0 & 0 & 0\\ 0 & 0 & 0 & 0 & 0 & 0 & 0 \end{bmatrix} \end{align*}$$

We leave it to the reader to check that B represents a partial flag $\widehat {Z}_\alpha ^{(1^7)}$ .

Lemma 4.15. Let $V_{\bullet }\in Z^{\mu }_\alpha $ and let $(i_1,j_1),(i_2,j_2),\dots ,(i_\ell ,j_\ell )$ be the free pairs for $\alpha $ listed so that $i_1\geq i_2\geq \cdots \geq i_\ell $ . For all $p\leq \ell $ , the standard coordinate $\beta _{i_p,j_p}$ of ${U}_{i_\ell ,j_\ell }(t_\ell )\cdots {U}_{i_1,j_1}(t_1)V_n\in C_w$ is $t_p$ .

Proof. By construction of $\widehat {U}_{i,j}(t)$ , the standard coordinates of $\widehat {U}_{i,j}(t)V$ are obtained by applying $\widehat {U}_{i,j}(t)$ directly to each $v_p$ and collecting terms (in terms of matrix representatives, $\widehat {U}_{i,j}(t)$ sends column-reduced matrices to column-reduced matrices); hence, the standard coordinates of ${U}_{i_\ell ,j_\ell }(t_\ell )\cdots {U}_{i_1,j_1}(t_1)V_n = \widehat {U}_{i_\ell ,j_\ell }(t_\ell )\cdots \widehat {U}_{i_1,j_1}(t_1)V_n$ are obtained by applying these operators to the standard coordinates of $V_n$ . Observe the following:

  1. 1. The $\beta _{i_p,j_p}$ coordinate of $V_n$ is $0$ since $V_n = \mathbb {F}^\alpha $ .

  2. 2. The operator $\widehat {U}_{i_p,j_p}(t_p)$ is the only $\widehat {U}_{i_q,j_q}(t_q)$ operator that changes the $\beta _{i_p,j_p}$ coordinate. Otherwise, there must exist some q and $m>0$ such that $N^m f_{i_q} = f_{i_p}$ and $N^m f_{j_q} = f_{j_p}$ . But this would imply that the label $j_p$ is strictly to the right of the label $j_q$ in T, contradicting the fact that $j_p$ is the leftmost label in $[\Lambda ]/[\lambda ]$ in $j_p$ ’s row.

  3. 3. $\widehat {U}_{i_p,j_p}(t_p) f_{i_p} = f_{i_p} + t_pf_{j_p}$ .

Combining 1–3 above, the $\beta _{i_p,j_p}$ coordinate after applying all of these operators is $t_p$ .

Lemma 4.16. Let $V\in C_{w}$ such that $N^tV\subseteq V$ and let $(i,j)$ be a pair of labels of T such that $i>j$ , i is in $[\alpha ]$ , and j is in $[\Lambda ]/[\alpha ]$ (for example, $(i,j)$ is a free pair of $\alpha $ ). Suppose that for all labels $r<i$ of T in $[\alpha ]$ , we have $f_{r}\in V$ . Then for any $m>0$ , if $N^mf_i = f_{i'}$ and $N^mf_j = f_{j'}$ , then the $\beta _{i,j}$ and $\beta _{i',j'}$ coordinates of V are equal.

Proof. Letting $v_q$ be the vectors for the standard coordinate representation of V and letting $a_\ell = \beta _{i,\ell }$ and $b_{\ell '} = \beta _{i',\ell '}$ for notational convenience, we have

$$ \begin{align*} v_{w^{-1}(i)} &= f_i + a_j f_{j} + \sum_{j\neq \ell<i} a_\ell f_\ell,\\ v_{w^{-1}(i')} &= f_{i'} + b_{j'} f_{j'} + \sum_{j'\neq \ell'<i'} b_{\ell'} f_{\ell'},\\ (N^t)^m v_{w^{-1}(i')} &= f_i + b_{j'} f_j + \sum_{j'\neq \ell' < i'} b_{\ell'} ((N^t)^m f_{\ell'}). \end{align*} $$

Since all of the above vectors are in V, then

(4.11) $$ \begin{align} v_{w^{-1}(i)} - (N^t)^m v_{w^{-1}(i')} = (a_j-b_{j'}) f_j + \sum_{j\neq \ell<i} a_\ell f_\ell - \sum_{j'\neq \ell' < i'} b_{\ell'} ((N^t)^m f_{\ell'})\in V. \end{align} $$

Observe that the $f_j$ coefficient of this vector is exactly $a_j-b_{j'}$ , since the two sums contain no $f_j$ terms.

Suppose by way of contradiction that $a_j\neq b_{j'}$ . Then the vector (4.11) is nonzero, and since it is in V, its leading term must be a scalar multiple of $f_p$ for some p a label in $[\alpha ]$ . Since $a_\ell = \beta _{i,\ell } = 0$ for all $\ell \in \{w(1),w(2),\dots , i\}$ , then no nonzero terms in the first sum correspond to $\ell $ a label in $[\alpha ]$ . Therefore, the leading term must be $b_{\ell '}((N^t)^mf_{\ell '})$ for some $\ell '$ in the second sum. Let $\ell $ be such that $(N^t)^mf_{\ell '} = f_\ell $ , and note that $\ell>j$ since it is the leading term. However, since $\ell '<i'$ by assumption, then $\ell <i$ (a property of reverse reading order). Since we necessarily have that $\ell $ is a label in $[\alpha ]$ , then by the hypothesis in the statement of the lemma, we have $f_\ell \in V$ . Therefore, we can eliminate the $b_{\ell '}f_\ell = b_{\ell '}((N^t)^mf_{\ell '})$ term from (4.11). After repeating this process of eliminating terms from (4.11), we get a nonzero vector in V whose leading term does not correspond to a label in $[\alpha ]$ , a contradiction. Therefore, we must have $a_j=b_{j'}$ , which completes the proof.

Lemma 4.17. Let $(i_1,j_1),(i_2,j_2),\dots , (i_\ell ,j_\ell )$ be the free pairs for $\alpha $ , listed so that $i_1\geq i_2\geq \cdots \geq i_\ell $ . Then the map

$$\begin{align*}\mathbb{F}^\ell \times Z^{\mu}_\alpha \to \widehat{Z}^{\mu}_\alpha \end{align*}$$

defined by sending $(\vec {t},V_{\bullet })$ to $U_{i_\ell ,j_\ell }(t_\ell )\cdots U_{i_2,j_2}(t_2) U_{i_1,j_1}(t_1)V_{\bullet }$ is an isomorphism.

Proof. First, observe that the map is well defined by Lemma 4.13. Second, by Lemma 4.15, the $\beta _{i_m,j_m}$ coordinate of $U_{i_\ell ,j_\ell }(t_\ell )\cdots U_{i_2,j_2}(t_2) U_{i_1,j_1}(t_1)V_{\bullet }$ is $t_m$ for each m. Therefore, any two pairs that map to the same partial flag must have the same $\vec {t}$ vector, and since the operators $U_{i,j}(t)$ are invertible, the map is injective.

Finally, we show that the map is surjective. Let $V_{\bullet }\in \widehat {Z}^{\mu }_\alpha $ and let $t_m = \beta _{i_m,j_m}$ be the standard coordinate of $V_n$ . We claim that $U_{i_1,j_1}^{-1}(t_1) U_{i_2,j_2}^{-1}(t_2)\cdots U_{i_\ell ,j_\ell }^{-1}(t_\ell )V_{\bullet } \in Z^{\mu }_\alpha $ . Observe that $U_{i,j}^{-1}(t) = U_{i,j}(-t)$ . Thus, it is clear that this flag is in $\widehat {Z}^{\mu }_\alpha $ , so it suffices to prove that

$$\begin{align*}U_{i_1,j_1}(-t_\ell)U_{i_2,j_2}(-t_2)\cdots U_{i_\ell,j_\ell}(-t_\ell)V_n = \mathbb{F}^\alpha. \end{align*}$$

This follows from the next claim.

Claim: Letting $\beta _{*,*}$ be the standard coordinates of $U_{i_p,j_p}(-t_p)\cdots U_{i_\ell ,j_\ell }(-t_\ell )V_n$ , for all $1\leq p\leq q\leq \ell $ , we have $\beta _{i_q,j_q}=0$ , and for all pairs $(i_q,j)$ with $j<i_q$ that are not free pairs, we have $\beta _{i_q,j}=0$ .

We prove the claim by reverse induction on p. In the base case when $p=q=\ell $ , then for all $r<i_\ell $ such that r is a label of T in $[\alpha ]$ , then $f_r\in V_n$ , so we have $U_{i_\ell ,j_\ell }(-t_\ell ) V_n = \widehat {U}_{i_\ell ,j_\ell }(-t_\ell )V_n$ . Since the standard coordinates of $\widehat {U}_{i_\ell ,j_\ell }(-t_\ell )V_n$ are obtained by applying $\widehat {U}_{i_\ell ,j_\ell }(-t_\ell )$ to the standard coordinate representation of $V_n$ , then $\widehat {U}_{i_\ell ,j_\ell }(-t_\ell )$ eliminates the $\beta _{i_\ell ,j_\ell }$ coordinate by construction, so the first part of the claim holds in the base case.

Let $(i_\ell ,j)$ be a pair with $j < i_\ell $ that is not a free pair. If j is a label in $[\alpha ]$ , then $\beta _{i_\ell ,j} = 0$ by definition, so assume j is a label of T in $[\Lambda ]/[\alpha ]$ . Let $i'$ be the label in the cell immediately to the left of $i_\ell $ and let $j'$ be the label of the cell immediately to the left of j (both of which must exist since $(i_\ell ,j)$ is not a free pair. Notice that if $i_\ell $ were in the first column, then j would also have to be in the first column). Since, as we mentioned above, $f_r \in V_n$ for all $r < i_\ell $ such that r is in $[\alpha ]$ , then $f_r\in \widehat {U}_{i_\ell ,j_\ell }(-t_\ell )V_n = U_{i_\ell ,j_\ell }(-t_\ell )V_n$ for $r< i'$ . By Lemma 4.16, we have $\beta _{i_\ell ,j} = \beta _{i',j'}$ . Furthermore, by the minimality of $i_\ell $ , we have that $i'$ is in $[\lambda ]$ (otherwise, $(i',j')$ would be a free pair, contradicting the minimality of $i_\ell $ ). Thus, $\beta _{i',j'}=0$ and so also $\beta _{i_\ell ,j} = 0$ , which completes the base case.

In the inductive step, suppose the statement of the claim holds for p. Then by the inductive hypothesis, for all $r<i_{p-1}$ such that r is a label of T in $[\alpha ]$ (note, this may exclude $i_p$ if $i_p=i_{p-1}$ ), then all $\beta _{r,j}$ coordinates of $U_{i_p,j_p}(-t_p)\cdots U_{i_\ell ,j_\ell }(-t_\ell )V_n$ are $0$ , so $f_r \in U_{i_p,j_p}(-t_p)\cdots U_{i_\ell ,j_\ell }(-t_\ell )V_n$ . Therefore,

$$ \begin{align*} U_{i_{p-1},j_{p-1}}(-t_{p-1})U_{i_p,j_p}(-t_p) \cdots U_{i_\ell,j_\ell}(-t_\ell) &V_n \\ &= \widehat{U}_{i_{p-1},j_{p-1}}(-t_{p-1})U_{i_p,j_p}(-t_p) \cdots U_{i_\ell,j_\ell}(-t_\ell)V_n. \end{align*} $$

By construction, $\widehat {U}_{i_{p-1},j_{p-1}}(-t_{p-1})$ eliminates the $\beta _{i_{p-1},j_{p-1}}$ coordinate and does not change the coordinates guaranteed to be $0$ in the inductive hypothesis. Given a pair $(i_{p-1},j)$ such that j is a label of T not in $[\alpha ]$ , then there exist m and $q>p-1$ such that $(N^t)^mf_{i_{p-1}} = f_{i_q}$ and $(N^t)^m f_{j_{p-1}} = f_{j_q}$ . Note this implies $N^m f_{i_q} = f_{i_{p-1}}$ and $N^m f_{j_q} = f_{j_{p-1}}$ . Since

$$\begin{align*}f_r \in U_{i_{p-1},j_{p-1}}(-t_{p-1})U_{i_p,j_p}(-t_p)\cdots U_{i_\ell,j_\ell}(-t_\ell)V_n \end{align*}$$

for all $r\leq i_q$ such that r is a label in $[\alpha ]$ , then by Lemma 4.16, the $\beta _{i_q,j_q}$ and $\beta _{i_{p-1},j}$ coordinates of this subspace are equal and thus are both $0$ . This completes the induction and the proof of the claim.

By the claim, we have for $p=1$ that $U_{i_1,j_1}(-t_1)U_{i_2,j_2}(-t_2)\cdots U_{i_\ell ,j_\ell }(-t_\ell )V_{\bullet }\in Z^{\mu }_\alpha $ , so the map in the statement of the lemma is surjective. In the case when $\mathbb {F} = \mathbb {C}$ , since the inverse is a regular map, it is an isomorphism of varieties.

Proof of Theorem 4.2

The isomorphism $\widehat {Z}^{\mu }_\alpha \cong \mathbb {F}^\ell \times Z^{\mu }_\alpha $ follows by combining Lemma 4.6 and Lemma 4.17.

5. Proof of Theorem 1.3

In this section, we use the results from Sections 3 and 4 to prove the main theorem, Theorem 1.3. Throughout this section, we utilize the notation for $\nu \in \mathrm {Par}(n,s)$ . Recall our convention that we consider $H^{2k}(Y_{n,\lambda ,s};\mathbb {Q})$ to be the degree k component of the cohomology ring.

Lemma 5.1. Let $\nu \in \mathrm {Par}(n,s)$ such that $\lambda \subseteq \nu $ . Then

(5.1) $$ \begin{align} \sum_{\substack{\alpha\in \mathrm{Comp}(n,s),\\ \mathrm{sort}(\alpha)=\nu, \\ \alpha\supseteq \lambda}} q^{\operatorname{\mathrm{coinv}}(\alpha)} = \prod_{i\geq 0} \genfrac{[}{]}{0pt}{}{\nu_i^{\prime} - \lambda_{i+1}^{\prime}}{\nu_i^{\prime} - \nu_{i+1}^{\prime}}_q. \end{align} $$

Proof. We proceed by induction on $m=\nu _1$ . In the base case $m=\nu _1=1$ , then $\lambda = (1^k)$ and $\nu = (1^n)$ . In this case, each $\alpha $ in the summation has parts $0$ and $1$ such that $\alpha _1=\cdots =\alpha _k = 1$ . Deleting the first k parts from $\alpha $ , we get a weak composition consisting of $0$ s and $1$ s of size $n-k$ and length $s-k$ (and the same number of coinversions as $\alpha $ ). Thus, the left-hand side of (5.1) can be rewritten as

$$\begin{align*}\sum_{\alpha \in \mathrm{Comp}(n-k,s-k)} q^{\operatorname{\mathrm{coinv}}(\alpha)}=\genfrac{[}{]}{0pt}{}{s-k}{n-k}_q = \genfrac{[}{]}{0pt}{}{s-k}{s-n}_q = \genfrac{[}{]}{0pt}{}{\nu_0^{\prime}-\lambda_1^{\prime}}{\nu_0^{\prime}-\nu_1^{\prime}}_q, \end{align*}$$

which equals the right-hand side, so the base case holds.

Let $m>1$ and assume by way of induction that the identity holds for all $\nu $ with $\nu _1=m-1$ , and let $\nu \in \mathrm {Par}(n,s)$ such that $\lambda \subseteq \nu $ . Define $\overline {\nu }$ and $\overline {\lambda }$ by removing all cells in column m of the Young diagrams of $\nu $ and $\lambda $ , respectively. Then $\alpha \in \mathrm {Comp}(n,s)$ such that $\lambda \subseteq \alpha $ and $\mathrm {sort}(\alpha ) = \nu $ is obtained uniquely by the following process:

  • Start with $\overline {\alpha } \in \mathrm {Comp}(n-\nu _m^{\prime },s)$ such that $\overline {\lambda }\subseteq \overline {\alpha }$ and $\mathrm {sort}(\overline {\alpha }) = \overline {\nu }$ ,

  • Append one cell to the first $\lambda _m^{\prime }$ rows of $[\overline {\alpha }]$ ,

  • Append one cell to $(\nu _m^{\prime }-\lambda _m^{\prime })$ many of the remaining rows of $[\overline {\alpha }]$ that have length $m-1$ .

There are $(\nu _{m-1}^{\prime }-\lambda _m^{\prime })$ many rows of $[\overline {\alpha }]$ with length $m-1$ (apart from the first $\lambda _m^{\prime }$ rows). Furthermore, the difference $\operatorname {\mathrm {coinv}}(\alpha )-\operatorname {\mathrm {coinv}}(\overline {\alpha })$ is the number of pairs $i<j$ such that $\alpha _i= m-1$ and $\alpha _j=m$ . For a fixed $\overline {\alpha }$ , the total contribution to the left-hand side of (5.1) is thus

$$\begin{align*}q^{\operatorname{\mathrm{coinv}}(\overline{\alpha})} \genfrac{[}{]}{0pt}{}{\nu_{m-1}^{\prime}-\lambda_m^{\prime}}{\nu_m^{\prime}-\lambda_m^{\prime}}_q = q^{\operatorname{\mathrm{coinv}}(\overline{\alpha})} \genfrac{[}{]}{0pt}{}{\nu_{m-1}^{\prime}-\lambda_m^{\prime}}{\nu_{m-1}^{\prime}-\nu_m^{\prime}}_q, \end{align*}$$

which is $q^{\operatorname {\mathrm {coinv}}(\overline {\alpha })}$ times the $i=m-1$ factor on the right-hand side of (5.1). An application of the inductive hypothesis then completes the proof.

Theorem 5.2. We have

(5.2) $$ \begin{align} \mathrm{Frob}(H^{*}(Y_{n,\lambda,s};\mathbb{Q});q) = \sum_{\substack{\nu\in \mathrm{Par}(n,s),\\ \nu\supseteq \lambda}} q^{\sum_i (s-\nu_i^{\prime})(\nu_{i+1}^{\prime}-\lambda_{i+1}^{\prime})}\prod_{i\geq 0} \genfrac{[}{]}{0pt}{}{\nu_i^{\prime}-\lambda_{i+1}^{\prime}}{\nu_i^{\prime}-\nu_{i+1}^{\prime}}_q \widetilde{H}_\nu(\mathbf{x};q). \end{align} $$

Proof. Combining (1.1), Theorem 3.8, Theorem 4.2 and Lemma 5.1, we have for all prime powers q the following string of identities.

(5.3) $$ \begin{align} &\mathrm{Frob}(H^{*}(Y_{n,\lambda,s};\mathbb{Q});q) \end{align} $$
(5.4) $$ \begin{align} &= \sum_{\mu\vdash n} |Y^{\mu}_{n,\lambda,s}(\mathbb{F}_q)| m_{\mu}(\mathbf{x}) \end{align} $$
(5.5) $$ \begin{align} &= \sum_{\mu\vdash n} \sum_{\substack{\alpha\in \mathrm{Comp}(n,s),\\ \alpha\supseteq \lambda}} |\widehat{Z}^{\mu}_\alpha (\mathbb{F}_q)| m_{\mu}(\mathbf{x}) \end{align} $$
(5.6) $$ \begin{align} &= \sum_{\mu\vdash n} \sum_{\substack{\alpha\in \mathrm{Comp}(n,s),\\ \alpha\supseteq \lambda}} q^{\sum_i (s-\alpha_i^{\prime})(\alpha_{i+1}^{\prime} - \lambda_{i+1}^{\prime}) + \operatorname{\mathrm{coinv}}(\alpha)} |Z^{\mu}_\alpha(\mathbb{F}_q)| m_{\mu}(\mathbf{x}) \end{align} $$
(5.7) $$ \begin{align} &= \sum_{\substack{\alpha\in \mathrm{Comp}(n,s),\\ \alpha\supseteq \lambda}} q^{\sum_i (s-\alpha_i^{\prime})(\alpha_{i+1}^{\prime} - \lambda_{i+1}^{\prime}) + \operatorname{\mathrm{coinv}}(\alpha)} \left(\sum_{\mu\vdash n} |Z^{\mu}_\alpha (\mathbb{F}_q)| m_{\mu}(\mathbf{x})\right) \end{align} $$
(5.8) $$ \begin{align} &= \sum_{\substack{\alpha\in \mathrm{Comp}(n,s),\\ \alpha\supseteq \lambda}} q^{\sum_i (s-\alpha_i^{\prime})(\alpha_{i+1}^{\prime} - \lambda_{i+1}^{\prime}) + \operatorname{\mathrm{coinv}}(\alpha)} \widetilde{H}_{\mathrm{sort}(\alpha)}(\mathbf{x};q) \end{align} $$
(5.9) $$ \begin{align} &= \sum_{\substack{\nu\in \mathrm{Par}(n,s),\\ \nu\supseteq \lambda}} q^{\sum_i (s-\nu_i^{\prime})(\nu_{i+1}^{\prime} - \lambda_{i+1}^{\prime})} \sum_{\substack{\alpha\in \mathrm{Comp}(n,s),\\ \mathrm{sort}(\alpha) = \nu,\\ \alpha\supseteq \lambda}} q^{\operatorname{\mathrm{coinv}}(\alpha)} \widetilde{H}_{\nu}(\mathbf{x};q) \end{align} $$
(5.10) $$ \begin{align} &= \sum_{\substack{\nu\in \mathrm{Par}(n,s),\\ \nu\supseteq \lambda}} q^{\sum_i (s-\nu_i^{\prime})(\nu_{i+1}^{\prime} - \lambda_{i+1}^{\prime})} \prod_{i\geq 0} \genfrac{[}{]}{0pt}{}{\nu_i^{\prime}-\lambda_{i+1}^{\prime}}{\nu_i^{\prime}-\nu_{i+1}^{\prime}}_q \widetilde{H}_{\nu}(\mathbf{x};q). \end{align} $$

In (5.9), we have used the fact that if $\mathrm {sort}(\alpha ) = \nu $ , then $\alpha _i^{\prime } = \nu _i^{\prime }$ for all i. Since the identities hold for infinitely many values of q, the final identity holds for q a formal parameter.

Corollary 5.3. We have

(5.11) $$ \begin{align} \mathrm{Frob}(H^{*}(Y_{n,\lambda,s};\mathbb{Q});q) = \mathrm{rev}_q\left[ \sum_{\substack{\nu\in \mathrm{Par}(n,s),\\ \nu\supseteq \lambda}} q^{n(\nu/\lambda)} \prod_{i\geq 0} \genfrac{[}{]}{0pt}{}{\nu_i^{\prime}-\lambda_{i+1}^{\prime}}{\nu_i^{\prime}-\nu_{i+1}^{\prime}}_q H_\nu(\mathbf{x};q)\right], \end{align} $$

where , , and .

Proof. By [Reference Griffin, Levinson and Woo10, Theorem 1.2], the degree of $\mathrm {Frob}(H^{*}(Y_{n,\lambda ,s};\mathbb {Q});q)$ is $n(\lambda )+(s-1)(n-k)$ . By Theorem 5.2, it suffices to show that $\mathrm {rev}_q$ applied to the right-hand side of (5.2) is equal to the expression in the right-hand side of (5.11) inside of $\mathrm {rev}_q$ . In other words, it suffices to prove that

(5.12) $$ \begin{align} q^{n(\lambda)+(s-1)(n-k)}\sum_{\substack{\nu\in \mathrm{Par}(n,s),\\ \nu\supseteq \lambda}} q^{-\sum_i (s-\nu_i^{\prime})(\nu_{i+1}^{\prime}-\lambda_{i+1}^{\prime})}\prod_{i\geq 0} \genfrac{[}{]}{0pt}{}{\nu_i^{\prime}-\lambda_{i+1}^{\prime}}{\nu_i^{\prime}-\nu_{i+1}^{\prime}}_{q^{-1}} \widetilde{H}_\nu(\mathbf{x};q^{-1}) = \end{align} $$
(5.13) $$ \begin{align} \sum_{\substack{\nu\in \mathrm{Par(n,s)},\\ \nu\supseteq \lambda}} q^{n(\nu/\lambda)} \prod_{i\geq 0} \genfrac{[}{]}{0pt}{}{\nu_i^{\prime}-\lambda_{i+1}^{\prime}}{\nu_i^{\prime}-\nu_{i+1}^{\prime}}_q H_\nu(\mathbf{x};q). \end{align} $$

Since $\widetilde {H}_\nu (\mathbf {x};q^{-1}) =q^{-n(\nu )}H_\nu (\mathbf {x};q)$ and $\genfrac {[}{]}{0pt}{}{a}{b}_{q^{-1}} = q^{-b(a-b)}\genfrac {[}{]}{0pt}{}{a}{b}_q$ , we are reduced to proving that

(5.14) $$ \begin{align} n(\nu/\lambda) = n(\lambda) + (s-1)(n-k) -\sum_i (s-\nu_i^{\prime})(\nu_{i+1}^{\prime}-\lambda_{i+1}^{\prime}) - \sum_i(\nu_i^{\prime}-\nu_{i+1}^{\prime})(\nu_{i+1}^{\prime}-\lambda_{i+1}^{\prime}) -n(\nu), \end{align} $$

which follows by a straightforward calculation using the facts that $\sum _i \nu _i^{\prime } = n$ and $\sum _i\lambda _i^{\prime } = k$ . Indeed, combining terms in the right-hand side of (5.14), we have

$$ \begin{align*} &\frac{1}{2}\left(\sum_i \lambda_i^{\prime}(\lambda_i^{\prime}-1) - 2(s-1)(n-k) - \sum_i 2(s-\nu_{i+1}^{\prime})(\nu_{i+1}^{\prime}-\lambda_{i+1}^{\prime}) -\sum_i \nu_i^{\prime}(\nu_i^{\prime}-1)\right)\\ &= \frac{1}{2}\left(-2(s-1)(n-k) + \sum_i\left( 2s(\nu_{i+1}^{\prime}-\lambda_{i+1}^{\prime}) + \nu_i^{\prime} -\lambda_i^{\prime} + (\lambda_i^{\prime})^2 + (\nu_i^{\prime})^2 - 2\nu_{i+1}^{\prime}\lambda_{i+1}^{\prime}\right)\right)\\ &=\frac{1}{2} \left(-2(s-1)(n-k) + 2sn - 2sk + 2\sum_i(\nu_i^{\prime}-\lambda_i^{\prime}) + \sum_i ((\lambda_i^{\prime})^2 + (\nu_i^{\prime})^2 - 2\nu_i^{\prime}\lambda_i^{\prime} - \nu_i^{\prime} - \lambda_i^{\prime})\right)\\ &=\frac{1}{2} \left(0 + \sum_i (\nu_i^{\prime} - \lambda_i^{\prime})(\nu_i^{\prime} - \lambda_i^{\prime} - 1)\right) = n(\nu/\lambda). \end{align*} $$

The proof is thus complete.

6. Further directions

We list a few open problems and possible further connections with geometry and combinatorics:

  • Counting partial flags also has connections with the q-Burge correspondence by work of Karp and Thomas [Reference Karp and Thomas16]. Is there a generalization of the q-Burge correspondence that corresponds to counting pairs of points of the $\Delta $ -Springer varieties?

  • The proof of Theorem 1.3 given in this article is geometric, relying on counting the points of the $\Delta $ -Springer variety over $\mathbb {F}_q$ using different ways to partition the space. A more direct combinatorial proof should be possible starting from Theorem 1.1. Such a combinatorial proof would find a weight-preserving bijection that collects terms of this formula into sums that can be identified as monomial expansions of Hall-Littlewood symmetric functions.

  • Formulas for Macdonald polynomials, which are two-parameter generalizations of Hall-Littlewood symmetric functions, have been obtained by Mellit [Reference Mellit18] as weighted sums over points of affine Springer fibers. It may be possible to define generalizations of $\Delta $ -Springer varieties in the setting of affine flag varieties. One can then ask whether weighted point counts over these varieties yield symmetric functions that can simultaneously be defined using Macdonald eigenoperators. In particular, since $\Delta ^{\prime }_{e_{k-1}}e_n|_{t=0}$ is, up to a minor twist, the graded Frobenius characteristic of the cohomology of $Y_{n,(1^k),k}$ , one might hope that extending the definition of $Y_{n,(1^k),k}$ to the affine setting and taking a weighted point count can recover the full symmetric function $\Delta ^{\prime }_{e_{k-1}}e_n$ .

Acknowledgements

The author would like to thank Jake Levinson and Alexander Woo for many helpful discussions and the anonymous referees for many helpful comments that improved the article and for pointing out an error in the proof of Lemma 4.12 in an earlier version of this article.

Competing interest

The authors have no competing interest to declare.

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Figure 0

Figure 1. An example of $[\Lambda ]$ for $n=7$, $\lambda =(2,1)$, $s=3$, with the two copies of the Young diagram of $\lambda $ shaded.

Figure 1

Figure 2. The reading order filling T of $[\Lambda (7,(2,2),4)]$, and the associated labelings $T^{(i)}$.

Figure 2

Figure 3. For T as in Figure 2, the partial row-decreasing filling $\operatorname {\mathrm {PRD}}_T(w)$ associated to the admissible function $w=2713594$.

Figure 3

Figure 4. The reverse reading order filling T for $[\Lambda (7,(2,2),4)]$, with $[\lambda ] = [(2,2)]$ shaded in orange. The diagram of $\alpha = (2,4,0,1)\in \mathrm {Comp}(7,4)$ is the union of the orange and blue cells.