Hostname: page-component-78c5997874-t5tsf Total loading time: 0 Render date: 2024-11-11T08:37:26.238Z Has data issue: false hasContentIssue false

Cordial elements and dimensions of affine Deligne–Lusztig varieties

Published online by Cambridge University Press:  08 September 2021

Xuhua He*
Affiliation:
The Institute of Mathematical Sciences and Department of Mathematics, The Chinese University of Hong Kong, Shatin, N.T., Hong Kong SAR, China

Abstract

The affine Deligne–Lusztig variety $X_w(b)$ in the affine flag variety of a reductive group ${\mathbf G}$ depends on two parameters: the $\sigma $ -conjugacy class $[b]$ and the element w in the Iwahori–Weyl group $\tilde {W}$ of ${\mathbf G}$ . In this paper, for any given $\sigma $ -conjugacy class $[b]$ , we determine the nonemptiness pattern and the dimension formula of $X_w(b)$ for most $w \in \tilde {W}$ .

Type
Number Theory
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 (http://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), 2021. Published by Cambridge University Press

1. Introduction

1.1. Motivation

The notion of the affine Deligne–Lusztig variety was introduced by Rapoport in [Reference RapoportRa05]. It plays an important role in arithmetic geometry and the Langlands programme. One of the main motivations comes from the reduction of Shimura varieties. In this paper we focus on the affine Deligne–Lusztig varieties in the affine flag variety. In this case, the affine Deligne–Lusztig varieties are closely related to the Shimura varieties with Iwahori level structure. On the special fibres, there are two important stratifications:

  • Newton stratification, indexed by specific $\sigma $ -conjugacy classes $[b]$ in the associated p-adic group

  • Kottwitz–Rapoport stratification, indexed by specific elements w in the associated Iwahori–Weyl group

A fundamental question is to determine when the intersection of a Newton stratum indexed by $[b]$ and a Kottwitz–Rapoport stratum indexed by w is nonempty and to determine its dimension. Such an intersection is closely related to the affine Deligne–Lusztig variety $X_w(b)$ (see, e.g., [Reference He and RapoportHR17]). In a parallel story over function fields, affine Deligne–Lusztig varieties also arise naturally in the study of local shtukas (see, e.g., [Reference Hartl and ViehmannHV11]).

Motivated by the study of Shimura varieties and local shtukas, we would like to understand the following fundamental questions on affine Deligne–Lusztig varieties:

  • When is the affine Deligne–Lusztig variety nonempty?

  • If nonempty, what is its dimension?

It is also worth pointing out that much information on affine Deligne–Lusztig varieties in partial affine flag varieties (which are closely related to Shimura varieties with other parahoric level structures) can be deduced from the information on affine Deligne-Lusztig varieties in the affine flag variety.

1.2. The main result

In this paper we determine, for any given $\sigma $ -conjugacy class $[b]$ , the nonemptiness pattern and dimension formula of $X_w(b)$ for most w in the Iwahori–Weyl group $\tilde {W}$ . To state the result, we introduce some notation first. For simplicity, we will consider here only the split groups ${\mathbf G}$ . The general case will be studied in the body of the paper.

The Iwahori–Weyl group $\tilde {W}$ is the semidirect product of the coweight lattice with the relative Weyl group $W_0$ . We may write $\tilde {W}$ as $\tilde {W}=\sqcup _{\lambda \text { is dominant}} W_0 t^{\lambda } W_0$ . For any $w \in W_0 t^{\lambda } W_0$ , we set $\lambda _w=\lambda $ . The $\sigma $ -conjugacy classes $[b]$ are classified by Kottwitz [Reference KottwitzKo85] via two invariants: the image under the Kottwitz map $\kappa $ and the Newton point $\nu _b$ (which is a dominant rational coweight). By Mazur’s inequality for affine Deligne–Lusztig varieties in the affine Grassmannian [Reference GashiGa10], we deduce that if $X_w(b) \neq \emptyset $ , then $\kappa (w)=\kappa (b)$ and $\lambda _w \ge \nu _b$ with respect to the dominance order of the rational coweights.

The converse, however, is far from being true. The main result of this paper is the following:

Theorem 1.1. Let $w \in \tilde {W}$ . Suppose that w is in a shrunken Weyl chamber. If $\kappa (w)=\kappa (b)$ , $\lambda _w-\nu _b$ is a linear combination of the simple coroots with all the coefficients positive and $\lambda _w^{\flat \mkern -2.4mu\flat } \ge \nu _b$ , then we have a complete description of the nonemptiness pattern and dimension formula for $X_w(b)$ .

We refer to Section 2.2 for the definition of shrunken Weyl chambers, Section 5.2 for the definition of $-^{\flat \mkern -2.4mu\flat }$ and Theorem 6.1 for the precise description of the nonemptiness pattern and dimension formula. These assumptions are satisfied for example when $\lambda _w \ge \nu _b+2 \rho ^\vee $ , where $\rho ^\vee $ is the half sum of positive coroots (see Corollary 6.4).

As an application of Theorem 1.1, in joint work with Q. Yu [Reference Yu and HeHY21] we establish a dimension formula for the group-theoretic analogue of Newton strata for sufficiently large dominant coweights.

1.3. Some previous results

In [Reference Görtz, Haines, Kottwitz and ReumanGHKR10, Conjecture 9.5.1], Görtz, Haines, Kottwitz and Reuman made several influential conjectures on the nonemptiness pattern and dimension formula of $X_w(b)$ .

First, for the basic $\sigma $ -conjugacy class $[b]$ , they gave a conjecture in [Reference Görtz, Haines, Kottwitz and ReumanGHKR10, Conjecture 9.5.1 (a)] on the nonemptiness pattern and dimension formula of $X_w(b)$ for w in the shrunken Weyl chamber. This conjecture was established in [Reference HeHe14]. For $X_w(b)$ with $[b]$ basic and w outside the shrunken Weyl chamber, in [Reference Görtz, Haines, Kottwitz and ReumanGHKR10, Conjecture 9.4.2] they gave a conjecture on the nonemptiness pattern. This conjecture is established in [Reference Görtz, He and NieGHN15]. But for $[b]$ basic and w outside the shrunken Weyl chamber, no conjectural dimension formula of $X_w(b)$ has even been formulated so far.

For arbitrary $\sigma $ -conjugacy class $[b]$ , they made an interesting conjecture in [Reference Görtz, Haines, Kottwitz and ReumanGHKR10, Conjecture 9.5.1 (b)] which predicts the difference of the dimensions of $X_w(b)$ and $X_w(b_{basic})$ , where $[b_{basic}]$ is the unique basic $\sigma $ -conjugacy class such that $\kappa (b)=\kappa (b_{basic})$ . In this conjecture, w is not required to be shrunken, but the length of w is required to be big enough with some (unspecified) lower bound. In later works, we studied $X_w(b)$ via a somewhat different direction. First, the assumption that w is in the shrunken Weyl chamber is added, as even for the basic b, the dimension formula of $X_w(b)$ with w outside the shrunken Weyl chamber is still very mysterious. Second, we would like to have a specific lower bound on w.

For split groups and the case where $[b]$ is represented by translation elements, under the ‘very shrunken’ assumption the nonemptiness pattern and the dimension formula of $X_w(b)$ were given in [Reference HeHe15, Theorem 2.28 & Theorem 2.34]. A similar result was obtained in [Reference Milićević, Schwer and ThomasMST19] under a different condition on w.

For other nonbasic $\sigma $ -conjugacy classes, little is known so far on the nonemptiness pattern and dimension formula of $X_w(b)$ .

1.4. Old strategies

We discuss several strategies used in previous work to study the nonemptiness pattern and dimension formula for $X_w(b)$ .

The emptiness pattern is established via the method of P-alcove elements introduced in [Reference Görtz, Haines, Kottwitz and ReumanGHKR10, Definition 2.1.1]. The upper bound of $\dim X_w(b)$ is given by the virtual dimension $d_w(b)$ introduced in [Reference HeHe14, §10.1].

In [Reference HeHe14], we combined the Deligne–Lusztig reduction with some remarkable properties of minimal length elements in their conjugacy classes in $\tilde {W}$ to establish a method to compute $\dim X_w(b)$ for arbitrary w and arbitrary $[b]$ . As a consequence, in [Reference HeHe14, Theorem 6.1] we established the ‘dimension=degree’ theorem, which relates the dimension of affine Deligne–Lusztig varieties with the degree of the class polynomials of the affine Hecke algebras. However, the computation of the class polynomials, in general, is extremely difficult. The dimension=degree theorem does not lead to explicit descriptions of the nonemptiness pattern and the dimension formula of $X_w(b)$ .

For basic $[b]$ , assume that $X_w(b) \neq \emptyset $ . It remains to show that $\dim X_w(b)$ reaches the upper bound $d_w(b)$ . Note that for any Coxeter element c, $\dim X_c(b)$ is easy to compute. This will be used as the starting point. In [Reference HeHe14, §11], we constructed an explicit ‘reduction path’ from an element w in the shrunken Weyl chamber to an element $w'$ with finite part a Coxeter element. By [Reference He and YangHY12, Theorem 1.1], the minimal length elements in the conjugacy class of $w'$ in $\tilde {W}$ are the Coxeter elements c. This gives a reduction path from w to c and thus leads to a lower bound of $\dim X_w(b)$ . Fortunately, the lower bound also equals the virtual dimension $d_w(b)$ . Thus we proved the nonemptiness pattern and the dimension formula of $X_w(b)$ with basic $[b]$ .

For split groups and the case where $[b]$ is represented by translation elements, in [Reference HeHe15] we used the superset method of [Reference Görtz, Haines, Kottwitz and ReumanGHKR10] to relate the nonemptiness pattern and dimension formula of $X_w(b)$ with $X_{w'}(1)$ for a given $w'$ . Note that $[1]$ is a basic $\sigma $ -conjugacy class. We then used the result on $X_{w'}(1)$ established in [Reference HeHe14] to obtain the desired result on $X_w(b)$ . A very different approach was introduced in [Reference Milićević, Schwer and ThomasMST19], where the authors used alcove walks and Littelmann paths to study the nonemptiness pattern and dimension formula of $X_w(b)$ .

It is unclear how or whether the methods in [Reference HeHe15] or in [Reference Milićević, Schwer and ThomasMST19] for the translation elements may be generalised to arbitrary $\sigma $ -conjugacy classes $[b]$ . The reduction method introduced in [Reference HeHe14] works, in theory, for an arbitrary $\sigma $ -conjugacy class $[b]$ . However, constructing an explicit reduction path from a given w to a minimal length element associated to a nonbasic $[b]$ is very challenging. Q. Yu has written a computer program to construct the reduction path for groups with small ranks. But so far it is not clear how such a reduction path may be constructed in general.

1.5. New strategy

The new strategy in this paper is as follows. Instead of using minimal length elements as the starting point, we use the cordial elements introduced by Milićević and Viehmann in [Reference Milićević and ViehmannMV20] as the starting point. In Section 4, we construct a new family of cordial elements. For any element $w'$ in this family, $\dim X_{w'}(b)$ equals the virtual dimension. We then construct in Section 5 an explicit reduction path from an element w in the shrunken Weyl chamber to an element in this family. This is where the assumption $\lambda _w^{\flat \mkern -2.4mu\flat } \ge \nu _b$ is used. This shows that $\dim X_w(b) \ge d_w(b)$ . Finally we use the result that $\dim X_w(b) \le d_w(b)$ established in [Reference HeHe14] to prove the desired nonemptiness pattern and the dimension formula of $X_w(b)$ .

Another issue we would like to point out here is that previous works (e.g., [Reference Görtz and HeGH10]) are in less general situations (e.g., with the assumption that G is split or tamely ramified) than the one we consider here. However, in this paper we use the geometric results Theorem 3.2 and Proposition 3.3, which hold for any reductive group G, and then use combinatorics of the Iwahori–Weyl groups $\tilde {W}$ . The results from previous works that we use here are to deduce certain nice combinatorial properties of $\tilde {W}$ . Thus we may apply the previous works in the more general setup here.

2. Preliminaries

2.1. The reductive group ${\mathbf G}$ and its Iwahori–Weyl group

Let F be a nonarchimedean local field and $\breve F$ be the completion of the maximal unramified extension of F. We write $\Gamma $ for $\operatorname {\mathrm {Gal}}\left (\overline F/F\right )$ , where $\overline F$ is an algebraic closure of F. We write $\Gamma _0$ for the inertia subgroup of $\Gamma $ . Let t be a uniformiser in F.

Let ${\mathbf G}$ be a connected reductive group over F. Let $\sigma $ be the Frobenius morphism of $\breve F/F$ . We write $\breve G$ for $\mathbf G\left (\breve F\right )$ . We use the same symbol $\sigma $ for the induced Frobenius morphism on $\breve G$ .

We fix a maximal $\breve F$ -split torus S in ${\mathbf G}$ defined over F which contains a maximal F-split torus. Let T be the centraliser of S in ${\mathbf G}$ . Then T is a maximal torus. Let $\mathcal A$ be the apartment of $\mathbf G_{\breve F}$ corresponding to $S_{\breve F}$ . Thus $\mathcal A$ is (noncanonically) isomorphic to $V=X_*(T)_{\Gamma _0} \otimes _{\mathbb Z} \mathbb R$ . The Frobenius $\sigma $ naturally acts on $\mathcal A$ . We fix a $\sigma $ -stable alcove $\mathfrak a$ in $\mathcal A$ , and let $\breve I \subset \breve G$ be the Iwahori subgroup corresponding to $\mathfrak a$ . Thus $\breve I$ is $\sigma $ -stable.

We denote by N the normaliser of T in ${\mathbf G}$ . The relative Weyl group $W_0$ is defined to be $N\left (\breve F\right )/T\left (\breve F\right )$ . The Iwahori–Weyl group (associated to S) is defined as

$$ \begin{align*}\tilde{W}= N\left(\breve F\right)/T\left(\breve F\right) \cap \breve I.\end{align*} $$

For any $w \in \tilde {W}$ , we choose a representative $\dot w$ in $N(L)$ .

We have a natural short exact sequence $0 \rightarrow X_*(T)_{\Gamma _0} \rightarrow \tilde {W} \rightarrow W_0 \rightarrow 0$ . We choose a special vertex of $\mathfrak a$ and represent $\tilde {W}$ as a semidirect product,

$$ \begin{align*}\tilde{W}=X_*(T)_{\Gamma_0} \rtimes W_0=\left\{t^{\lambda} w; \lambda \in X_*(T)_{\Gamma_0}, w \in W_0\right\}.\end{align*} $$

The Iwahori–Weyl group $\tilde {W}$ contains the affine Weyl group $W_a$ as a normal subgroup and we have

$$ \begin{align*} \tilde{W}=W_a \rtimes \Omega, \end{align*} $$

where $\Omega $ is the stabiliser of $\mathfrak a$ . The length function $\ell $ and Bruhat order $\le $ on $W_a$ extend in a natural way to $\tilde {W}$ . The Frobenius $\sigma $ naturally acts on $\tilde {W}$ , in such a way that the subset $\tilde {\mathbb {S}} \subset \tilde {W}$ is stable.

For any $K \subset \tilde {\mathbb {S}}$ , we denote by $W_K$ the subgroup of $\tilde {W}$ generated by $s \in K$ . Let ${}^K \tilde {W}$ (resp., $\tilde {W}^K$ ) be the set of minimal length elements in their cosets in $W_K \backslash \tilde {W}$ (resp., $\tilde {W}/W_K$ ).

Let $\mathbb {S} \subset \tilde {\mathbb {S}}$ be the set of simple reflections of $W_0$ . By convention, the dominant Weyl chamber of V is opposite to the unique Weyl chamber containing $\mathfrak a$ . Let $\Delta $ be the set of relative simple roots determined by the dominant Weyl chamber. For any $s \in \mathbb {S}$ , we denote by $\alpha _s \in \Delta $ the corresponding simple root and $\alpha _s^\vee $ the corresponding simple coroot. We denote by $w_{\mathbb {S}}$ the longest element of $W_0$ .

We define the $\sigma $ -conjugation action on $\breve G$ by $g \cdot _{\sigma } g'=g g' \sigma (g) ^{-1}$ . Let $B(\mathbf G)$ be the set of $\sigma $ -conjugacy classes on $\breve G$ . The classification of the $\sigma $ -conjugacy classes was obtained by Kottwitz in [Reference KottwitzKo85]. Any $\sigma $ -conjugacy class $[b]$ is determined by two invariants:

  • the element $\kappa ([b]) \in \Omega _{\sigma }$ and

  • the Newton point $\nu _b \in \left (\left (X_*(T)_{\Gamma _0, \mathbb {Q}}\right )^+\right )^{\langle \sigma \rangle }$ .

Here $-_{\sigma }$ denotes the $\sigma $ -coinvariants and $\left (X_*(T)_{\Gamma _0, \mathbb {Q}}\right )^+$ denotes the set of dominant elements in $X_*(T)_{\Gamma _0}\otimes \mathbb {Q}=X_*(T)^{\Gamma _0}\otimes \mathbb {Q}$ ; the action of $\sigma $ on $\left (X_*(T)_{\Gamma _0, \mathbb {Q}}\right )/W_0$ is transferred to an action on $\left (X_*(T)_{\mathbb {Q}}\right )^+$ (L-action).

For any $w \in \tilde {W}$ , we write $\kappa (w)$ for $\kappa (\dot w)$ . It is easy to see that $\kappa (w)$ is independent of the choice of the representative w.

We use the convention of Bruhat and Tits that the translation element $t^{\lambda }$ acts by $-\lambda $ on the apartment. In this way, we have $\ell \left (x t^{\lambda }\right )=\ell (x)+\ell \left (t^{\lambda }\right )$ for any $x \in W_0$ and $\lambda $ dominant.

2.2. Affine Deligne–Lusztig varieties

We have the following generalisation of the Bruhat decomposition:

$$ \begin{align*}\breve G=\sqcup_{w \in \tilde{W}} \breve I \dot w \breve I,\end{align*} $$

due to Iwahori and Matsumoto [Reference Iwahori and MatsumotoIM65] in the split case and to Bruhat and Tits [Reference Bruhat and TitsBT72] in the general case. Let $Fl=\breve G/\breve I$ be the affine flag variety. For any $b \in \breve G$ and $w \in \tilde {W}$ , we define the corresponding affine Deligne–Lusztig variety in the affine flag variety:

$$ \begin{align*}X_w(b)=\left\{g \breve I \in \breve G/\breve I; g ^{-1} b \sigma(g) \in \breve I \dot w \breve I\right\} \subset Fl.\end{align*} $$

In the equal characteristic, $X_w(b)$ is the set of $\bar {\mathbb F}_q$ -points of a scheme [Reference Bhatt and ScholzeBS17].

As discussed in [Reference Görtz, He and NieGHN15, §2], the study of the nonemptiness pattern and dimension formula of affine Deligne–Lusztig varieties for an arbitrary reductive group may be reduced to simple and quasi-split groups over F. From now on, we assume that ${\mathbf G}$ is simple and quasi-split over F. In this case, the $\sigma $ -action on $\tilde {W}$ preserves $W_0$ and $X_*(T)_{\Gamma _0}$ . Moreover, we have $\sigma (\mathbb {S})=\mathbb {S}$ and $\sigma (\Delta )=\Delta $ .

Now we recall the definition of the virtual dimension in [Reference HeHe14, §10.1].

Note that any element $w \in \tilde {W}$ may be written in a unique way as $w=x t^\mu y$ with $\mu $ dominant, $x, y \in W_0$ , such that $t^\mu y \in {}^{\mathbb {S}} \tilde {W}$ . In this case,

(2.1) $$ \begin{align} \ell(w)=\ell(x)+\ell(t^\mu)-\ell(y). \end{align} $$

We set

$$ \begin{align*}\eta_{\sigma}(w) = \sigma^{-1}(y) x.\end{align*} $$

Let $\mathbf J_b$ be the reductive group over F with $\mathbf J_b(F)=\left \{g \in \breve G; g b \sigma (g) ^{-1}=b\right \}.$ The defect of b is defined by $\text {def}(b)=\operatorname {\mathrm {rank}}_F \mathbf G-\operatorname {\mathrm {rank}}_F \mathbf J_b.$ Here for a reductive group $\mathbb H$ defined over F, $\operatorname {\mathrm {rank}}_F$ is the F-rank of the group $\mathbb H$ . Let $\rho $ be the dominant weight with $\left \langle \alpha ^\vee , \rho \right \rangle =1$ for any $\alpha \in \Delta $ . The virtual dimension is defined to be

$$ \begin{align*}d_w(b)=\frac 12 \big( \ell(w) + \ell(\eta_{\sigma}(w)) -\text{def}(b) \big)-\langle\nu_b, \rho\rangle.\end{align*} $$

The following result is proved in [Reference HeHe14, Corollary 10.4] for residually split groups and in [Reference HeHe15, Theorem 2.30] for the general case:

Theorem 2.1. Let $b \in \breve G$ and $w \in \tilde {W}$ . Then $\dim X_w(b) \le d_w(b)$ .

For any $w \in W_0$ , we denote by $\operatorname {\mathrm {supp}}(w) \subset \mathbb {S}$ the set of simple reflections appearing in some (or equivalently, any) reduced expression of w. We set $\operatorname {\mathrm {supp}}_{\sigma }(w)=\cup _{i \in \mathbb {Z}} \sigma ^i(\operatorname {\mathrm {supp}}(w))$ .

For any $w \in \tilde {W}$ , let $\lambda _w$ be the unique dominant coweight such that $w \in W_0 t^{\lambda _w} W_0$ . For any $\lambda \in X_*(T)_{\Gamma _0}$ , we denote by $\lambda ^{\diamondsuit }$ the average of the $\sigma $ -orbit of $\lambda $ . For any $\lambda , \lambda ' \in X_*(T)^+_{\mathbb {Q}}$ , we write $\lambda \ge \lambda '$ if $\lambda -\lambda ' \in \sum _{\alpha \in \Delta } \mathbb {Q}_{\ge 0} \alpha ^\vee $ and write $\lambda \ge _{\mathbb {Z}} \lambda '$ if $\lambda -\lambda ' \in \sum _{\alpha \in \Delta } \mathbb {N} \alpha ^\vee $ . Here $\mathbb {N}$ is the set of natural numbers, that is, the set of nonnegative integers.

A critical strip of the apartment V is the subset $\left \{v; -1<\langle v, \alpha \rangle <0\right \}$ for a given positive root $\alpha $ in the reduced root system associated to the affine Weyl group $W_a$ . We remove all the critical strips from V and call each connected component of the remaining subset of V a shrunken Weyl chamber.

3. Some combinatorial properties

3.1. Minimal length elements

For any $\sigma $ -conjugacy class $\mathcal O$ in $\tilde {W}$ , we denote by $\mathcal O_{\min }$ the set of minimal length elements in $\mathcal O$ . For $w, w' \in \tilde {W}$ and $s \in \tilde {\mathbb {S}}$ , we write $w {\xrightarrow {s}}_{\sigma } w'$ if $w'=s w \sigma (s)$ and $\ell (w') \le \ell (w)$ . We write $w {\rightarrow }_{\sigma } w'$ if there is a sequence $w=w_0, w_1, \dotsc , w_n=w'$ of elements in $\tilde {W}$ such that for any k, $w_{k-1} {\xrightarrow {s}}_{\sigma } w_k$ for some $s \in \tilde {\mathbb {S}}$ . We write $w \approx _{\sigma } w'$ if $w \rightarrow _{\sigma } w'$ and $w' \rightarrow _{\sigma } w$ . It is easy to see that $w \approx _{\sigma } w'$ if $w \rightarrow _{\sigma } w'$ and $\ell (w)=\ell (w')$ .

The following result is proved in [Reference He and NieHN14, §2]:

Theorem 3.1. Let $\mathcal O$ be a $\sigma $ -conjugacy class of $\tilde {W}$ and $w \in {\mathcal O}$ . Then there exists $w' \in {\mathcal O}_{\min }$ such that $w \rightarrow _{\sigma } w'$ .

Theorem 3.2. Let $b \in \breve G$ and $w \in {\mathcal O}_{\min }$ for some $\sigma $ -conjugacy class ${\mathcal O}$ of $\tilde {W}$ . Then $X_w(b) \neq \emptyset $ if and only if $\dot w \in [b]$ . In this case, $\dim X_w(b)=\ell (w)-\langle \nu _b, 2 \rho \rangle $ .

3.2. Deligne–Lusztig reduction

Now we recall the ‘reduction’ à la Deligne and Lusztig for affine Deligne–Lusztig varieties (see [Reference Deligne and LusztigDL76, Proof of Theorem 1.6] and [Reference Görtz and HeGH10, Corollary 2.5.3]).

Proposition 3.3. Let $b \in \breve G$ . Then

  1. (1) if $w, w' \in \tilde {W}$ with $w \approx _{\sigma } w'$ , we have

    $$ \begin{align*} \dim X_w(b)=\dim X_{w'}(b); \end{align*} $$
  2. (2) if $w \in \tilde {W}$ and $s \in \tilde {\mathbb {S}}$ with $\ell (s w \sigma (s))=\ell (w)-2$ , we have

    $$ \begin{align*} \dim X_w(b)=\max\left\{\dim X_{s w}(b), \dim X_{s w \sigma(s)}(b)\right\}+1. \end{align*} $$

Here, by convention, we set $\dim \emptyset =-\infty $ and $-\infty +n=-\infty $ for any $n \in \mathbb {R}$ .

3.3. The relation $\Rightarrow $

Following [Reference Görtz and HeGH10, Definition 3.1.4], for $w, w' \in \tilde {W}$ we write $w \Rightarrow _{\sigma } w'$ if for any $b \in \breve G$ ,

$$ \begin{align*} \dim X_w(b)-d_w(b) \ge \dim X_{w'}(b)-d_{w'}(b). \end{align*} $$

Again by convention, we set $\dim \emptyset =-\infty $ . If the right-hand side is $-\infty $ , then the inequality holds regardless of the left-hand side. It is also easy to see that the relation is transitive.

Note that by the definition of virtual dimension, $w \Rightarrow _{\sigma } w'$ if and only if for any $b \in \breve G$ with $X_{w'}(b) \neq \emptyset $ , $X_w(b) \neq \emptyset $ , and in this case,

$$ \begin{align*} \dim X_w(b)-\dim X_{w'}(b) \ge \frac{1}{2}\bigl( \ell(w) + \ell(\eta_{\sigma}(w)) -\ell(w')-\ell(\eta_{\sigma}(w'))\bigr). \end{align*} $$

We write $w \Leftrightarrow _{\sigma } w'$ if $w \Rightarrow _{\sigma } w'$ and $w' \Rightarrow _{\sigma } w$ .

3.4. The monoid structure on $\tilde {W}$

By [Reference HeHe09, Lemma 1], for any $w, w' \in \tilde {W}$ the subset $\{u w'; u \le w\}$ of $\tilde {W}$ contains a unique maximal element which we denote by $w \ast w'$ . Moreover, $w \ast w'=\max \{u v; u \le w, v \le w'\}$ . Hence $\ast $ is associative. This gives a monoid structure on $\tilde {W}$ . If $w_1 \le w$ and $w^{\prime }_1 \le w'$ , then $w_1 \ast w^{\prime }_1 \le w \ast w'$ .

4. The cordial elements

4.1. Definition

There is a natural partial ordering $\le $ on $B(\mathbf G)$ defined as follows: Set $[b], [b'] \in B(\mathbf G)$ . Then $[b] \le [b']$ if $\kappa (b)=\kappa (b')$ and $\nu _b \le \nu _{b'}$ .

Now we recall the cordial elements introduced by Milićević and Viehmann in [Reference Milićević and ViehmannMV20].

For any $w \in \tilde {W}$ , there is a unique maximal $\sigma $ -conjugacy class $[b]$ such that $X_w(b) \neq \emptyset $ . We denote this $\sigma $ -conjugacy class by $[b_w]$ . The element w is called cordial if $\dim X_w(b_w)=d_w(b_w)$ . Equivalently, w is cordial if and only if $\ell (w)-\ell (\eta _{\sigma }(w))=\left \langle \nu _{b_w}, 2 \rho \right \rangle -\text {def}(b_w)$ [Reference Milićević and ViehmannMV20, Definition 3.14].

By definition, if $w \Leftrightarrow _{\sigma } w'$ , then w is a cordial element if and only if $w'$ is a cordial element. The following result is proved in [Reference Milićević and ViehmannMV20, Theorem 1.1 & Corollary 3.17]:

Theorem 4.1. Let $w \in \tilde {W}$ be a cordial element. Then the following hold:

  1. (1) Set $[b], [b'] \in B(\mathbf G)$ . If $[b] \le [b'] \le [b_w]$ and $X_w(b) \neq \emptyset $ , then $X_w(b') \neq \emptyset $ .

  2. (2) If $X_w(b) \neq \emptyset $ , then $\dim X_w(b)=d_w(b)$ .

It is mentioned in [Reference Milićević and ViehmannMV20] that fully characterising the cordial elements is fairly difficult. In [Reference Milićević and ViehmannMV20, Theorem 1.2], some interesting families of cordial elements are provided. The main result of this section is to provide another family of cordial elements.

Theorem 4.2. Let $\lambda $ be a dominant coweight and set $x \in W_0$ . Then $x t^{\lambda }$ is a cordial element and $\left [b_{x t^{\lambda }}\right ]=\left [\dot t^{\lambda }\right ]$ .

Remark 4.3. The original proof we had was a bit technical. The proof to come was suggested by E. Viehmann.

4.2. Mazur’s inequality

Recall that ${\mathbf G}$ is quasi-split over F. Let $\breve K \supset \breve I$ be a $\sigma $ -stable special maximal parahoric subgroup of $\breve G$ . The nonemptiness pattern of the affine Deligne–Lusztig varieties in the affine Grassmannian $\breve G/\breve K$ is determined in terms of Mazur’s inequality. This was established by Gashi [Reference GashiGa10, Theorem 1.1] for unramified groups and proved in the general case in [Reference HeHe14, Theorem 7.1]. We may reformulate the result as follows:

Theorem 4.4. Let $\lambda $ be a dominant coweight and set $b \in \breve G$ . Then $[b] \cap \breve K \dot t^{\lambda } \breve K \neq \emptyset $ if and only if $\kappa (b)=\kappa \left (t^{\lambda }\right )$ and $\nu _b \le \lambda ^{\diamondsuit }$ .

4.3. Proof of Theorem 4.2

Set $w \in \tilde {W}$ . By definition, $[b_w]$ is the unique maximal $\sigma $ -conjugacy class that intersects $\breve I \dot w \breve I$ . By [Reference ViehmannVi14, Corollary 5.6], $[b_w]$ is also the unique maximal $\sigma $ -conjugacy class that intersects $\overline {\breve I \dot w \breve I}$ . Since $t^{\lambda } \le x t^{\lambda } \le w_{\mathbb {S}} t^{\lambda }$ , we have

$$ \begin{align*}\breve I \dot t^{\lambda} \breve I \subset \overline{\breve I \dot x \dot t^{\lambda} \breve I} \subset \overline{\breve I \dot w_{\mathbb {S}} \dot t^{\lambda} \breve I}=\overline{\breve K \dot t^{\lambda} \breve K}.\end{align*} $$

By Theorem 4.4, $\left [b_{w_{\mathbb {S}} t^{\lambda }}\right ]=\left [\dot t^{\lambda }\right ]$ . Thus $\left [b_{x t^{\lambda }}\right ]=\left [\dot t^{\lambda }\right ]$ .

Now $\nu _{b_{x t^{\lambda }}}=\lambda ^{\diamondsuit }$ and $\text {def}\left (b_{x t^{\lambda }}\right )=0$ . Hence

$$ \begin{align*}\ell\left(x t^{\lambda}\right)-\ell\left(\eta_{\sigma}\left(x t^{\lambda}\right)\right)=\ell(x)+\ell\left(t^{\lambda}\right)-\ell(x)=\ell\left(t^{\lambda}\right)=\langle \lambda, 2\rho\rangle=\left\langle \lambda^{\diamondsuit}, 2 \rho\right\rangle.\end{align*} $$

Thus $x t^{\lambda }$ is a cordial element.

4.4. Another family of cordial elements

Set $w \in \tilde {W}$ such that $w \mathfrak a$ is in the dominant Weyl chamber–that is, $w=w_{\mathbb {S}} t^{\lambda } y$ , where $\lambda $ is a dominant coweight and $y \in W_0$ with $t^{\lambda } y \in {}^{\mathbb {S}} \tilde {W}$ . It was proved by Milićević and Viehmann in [Reference Milićević and ViehmannMV20, Theorem 1.2 (a)] that w is also a cordial element.

Now we show that it can also be deduced from Theorem 4.2.

Set $w'=\sigma ^{-1}(y) w_{\mathbb {S}} t^{\lambda }$ . By Theorem 4.2, $w'$ is a cordial element. Note that $\eta _{\sigma }(w')=\eta _{\sigma }(w)=\sigma ^{-1}(y) w_{\mathbb {S}}$ . Moreover, it is easy to see that $w \approx _{\sigma } w'$ . Hence $w \Leftrightarrow _{\sigma } w'$ , and w is also a cordial element.

It is also worth mentioning that not every element of the form $x t^{\lambda }$ is $\approx _{\sigma }$ -equivalent to an element in the dominant Weyl chamber.

5. From w to a cordial element

We first show the following:

Proposition 5.1. Let $\lambda , \lambda '$ be dominant coweights. Then the set

$$ \begin{align*}\{\mu'; \mu' \text{ is dominant}, \mu'+\lambda' \ge_{\mathbb {Z}} \lambda\}\end{align*} $$

contains a unique minimal element with respect the dominance order $\ge _{\mathbb {Z}}$ .

Remark 5.2. The proof is due to S. Nie.

Proof. Let $\mu ^{\prime }_1, \mu ^{\prime }_2$ be dominant coweights with $\mu ^{\prime }_1+\lambda ' \ge _{\mathbb {Z}} \lambda $ and $\mu ^{\prime }_2+\lambda ' \ge _{\mathbb {Z}} \lambda $ . We may write $\mu ^{\prime }_1-\mu ^{\prime }_2$ as $\mu ^{\prime }_1-\mu ^{\prime }_2=\gamma _1-\gamma _2$ , where $\gamma _1 \in \sum _{\alpha \in J_1} \mathbb {Z}_{>0} \alpha $ , $\gamma _2 \in \sum _{\alpha \in J_2} \mathbb {Z}_{>0} \alpha $ for some $J_1, J_2 \subset \Delta $ with $J_1 \cap J_2=\emptyset $ .

Set $\mu =\mu ^{\prime }_1-\gamma _1=\mu ^{\prime }_2-\gamma _2$ . Set $\alpha \in \Delta $ . Since $J_1 \cap J_2=\emptyset $ , we have $\alpha \notin J_1$ or $\alpha \notin J_2$ . If $\alpha \notin J_1$ , then $\langle \mu , \alpha \rangle \ge \left \langle \mu ^{\prime }_1, \alpha \right \rangle \ge 0$ . If $\alpha \notin J_2$ , then $\langle \mu , \alpha \rangle \ge \left \langle \mu ^{\prime }_2, \alpha \right \rangle \ge 0$ . Thus $\mu $ is dominant. By definition, $\mu ^{\prime }_1 \ge _{\mathbb {Z}} \mu $ and $\mu ^{\prime }_2 \ge _{\mathbb {Z}} \mu $ . Moreover,

$$ \begin{align*}\lambda'-\lambda+\mu^{\prime}_1=\lambda'-\lambda+\mu^{\prime}_2+\gamma_1-\gamma_2 \in \left(\sum_{\alpha \in \Delta} \mathbb {Z}_{>0} \alpha+\gamma_1-\gamma_2\right) \cap \sum_{\alpha \in \Delta} \mathbb {Z}_{>0} \alpha.\end{align*} $$

Since $J_1 \cap J_2=\emptyset $ , we have $\lambda '-\lambda +\mu ^{\prime }_1-\gamma _1 \in \sum _{\alpha \in \Delta } \mathbb {Z}_{>0} \alpha $ . In other words, $\lambda '+\mu \ge _{\mathbb {Z}} \lambda $ .

The statement is proved.

5.1. The normalised subtraction

For any dominant coweights $\lambda , \lambda '$ , we denote by $\lambda -_{\text {dom}} \lambda '$ the unique minimal element in the set

$$ \begin{align*}\{\mu'; \mu' \text{ is dominant}, \mu'+\lambda' \ge_{\mathbb {Z}} \lambda\}.\end{align*} $$

It is easy to see that if $\lambda -\lambda '$ is dominant, then $\lambda -_{\text {dom}} \lambda '=\lambda -\lambda '$ . We call $-_{\text {dom}}$ the normalised subtraction. Now we prove some of its properties.

Corollary 5.3. Let $\lambda , \lambda '$ be dominant coweights. Let $\lambda ''$ be a dominant coweight with $\lambda ' \ge _{\mathbb {Z}} \lambda ''$ . Set $x \in W_0$ and let $\mu $ be the unique dominant coweight in the $W_0$ -orbit of $\lambda -x(\lambda '')$ . Then $\mu \ge _{\mathbb {Z}} \lambda -_{\text {dom}} \lambda '$ .

Proof. Note that $\mu -(\lambda -x(\lambda '')) \in \sum _{\alpha \in \Delta } \mathbb {N} \alpha $ , $\lambda ''-x(\lambda '') \in \sum _{\alpha \in \Delta } \mathbb {N} \alpha $ and $\lambda '-\lambda '' \in \sum _{\alpha \in \Delta } \mathbb {N} \alpha $ . Thus

$$ \begin{align*} \mu+\lambda' &=(\mu-\lambda+x(\lambda''))+\lambda-x(\lambda'')+\lambda' \\ &=(\mu-\lambda+x(\lambda''))+(\lambda''-x(\lambda''))+(\lambda'-\lambda'')+\lambda \\ & \ge_{\mathbb {Z}} \lambda.\end{align*} $$

Corollary 5.4. Let $\lambda , \lambda _1, \lambda _2$ be dominant coweights. Then

$$ \begin{align*}(\lambda-_{\text{dom}} \lambda_1)-_{\text{dom}} \lambda_2=\lambda-_{\text{dom}} (\lambda_1+\lambda_2).\end{align*} $$

Proof. Set $\mu _1=(\lambda -_{\text {dom}} \lambda _1)-_{\text {dom}} \lambda _2$ and $\mu _2=\lambda -_{\text {dom}} (\lambda _1+\lambda _2)$ . By definition,

$$ \begin{align*}(\lambda_1+\lambda_2)+\mu_1=\lambda_1+(\lambda_2+\mu_1) \ge_{\mathbb {Z}} \lambda_1+(\lambda-_{\text{dom}} \lambda_1) \ge_{\mathbb {Z}} \lambda.\end{align*} $$

So $\mu _1 \ge _{\mathbb {Z}} \mu _2.$

On the other hand,

$$ \begin{align*}\lambda_1+(\lambda_2+\mu_2)=(\lambda_1+\lambda_2)+\mu_2 \ge_{\mathbb {Z}} \lambda.\end{align*} $$

So by definition, $\lambda _2+\mu _2 \ge _{\mathbb {Z}} \lambda -_{\text {dom}} \lambda _1$ and $\mu _2 \ge _{\mathbb {Z}} \mu _1$ .

5.2. The double flat operator

For any subset J of $\mathbb {S}$ , we denote by $\rho ^\vee _J$ the dominant coweight with

$$ \begin{align*}\left\langle\rho^\vee_J, \alpha_s\right\rangle=\begin{cases} 1 & \text{if } s \in J, \\ 0 & \text{if } s \notin J.\end{cases}\end{align*} $$

Let $\eta ^\vee _J$ be the unique dominant coweight in the $W_0$ -orbit of $-\sigma ^{-1}\left (\rho ^\vee _J\right )$ .

Set $w \in \tilde {W}$ . We write w as $w=x t^{\lambda } y$ with $\lambda $ dominant, $x, y \in W_0$ and $t^{\lambda } y \in {}^{\mathbb {S}} \tilde {W}$ . Let $J=\{s \in \mathbb {S}; {s y<y}\}$ . Since $t^{\lambda } y \in {}^{\mathbb {S}} \tilde {W}$ , we have $\langle \lambda , \alpha _s\rangle>0$ for any $s \in J$ . In particular, $\lambda -\rho ^\vee _J$ is dominant. We set

$$ \begin{align*}\lambda_w^{\flat\mkern-2.4mu\flat}=\left(\lambda-\rho^\vee_J\right)-_{\text{dom}} \eta^\vee_J=\lambda-_{\text{dom}} \left(\rho^\vee_J+\eta^\vee_J\right).\end{align*} $$

The main result of this section is as follows:

Theorem 5.5. Assume that ${\mathbf G}$ is quasi-split over F. Set $w \in \tilde {W}$ such that $w \mathfrak a$ is in a shrunken Weyl chamber. Then there exist a dominant coweight $\gamma $ with $\gamma \ge _{\mathbb {Z}} \lambda _w^{\flat \mkern -2.4mu\flat }$ and $a \in W_0$ with $\operatorname {\mathrm {supp}}_{\sigma }(a) \supset \operatorname {\mathrm {supp}}_{\sigma }(\eta _{\sigma }(w))$ such that

$$ \begin{align*}w \Rightarrow_{\sigma} a t^\gamma.\end{align*} $$

5.3. A convenient notation

Following [Reference Görtz and HeGH10, §2.4], we give a convenient notation for varieties of tuples of elements in $Fl$ . We explain the notation by examples. Let $\mathcal O_w=\left \{\left (g \breve I, g \dot w \breve I\right ); g \in \breve G\right \} \subset Fl\times Fl$ . Then we set

Similarly,

The affine Deligne–Lusztig varieties can be written as

In all these cases, we do not distinguish between the sets given by the conditions on the relative position and the corresponding locally closed sub-ind-schemes of the product of affine flag varieties. The following result is proved in [Reference Görtz and HeGH10, Proposition 2.5.2]:

Proposition 5.6. Set $w, w'\in \tilde {W}$ , and set $w'' \in \{ ww', w \ast w' \}$ . Then the map

is surjective. Moreover, all the fibres have dimension

$$ \begin{align*} \dim\pi^{-1}( ( g, g') ) \ge \begin{cases} \ell(w) + \ell(w') - \ell(w*w') & \text{if } w'' = w \ast w',\\ \frac 12 \bigl( \ell(w) + \ell(w') - \ell(ww') \bigr) & \text{if } w'' = ww'. \end{cases} \end{align*} $$

5.4. Proof of Theorem 5.5

We write w as $w=x t^{\lambda _w} y$ with $x, y \in W_0$ and $t^{\lambda _w} y \in {}^{\mathbb {S}} \tilde {W}$ . Let $J=\{s \in \mathbb {S}; s y<y\}$ and $J'=\left \{s \in \mathbb {S}; s\left (\lambda _w-\rho ^\vee _J\right )=\lambda _w-\rho ^\vee _J\right \}$ . We write $\sigma ^{-1}(y) x$ as $\sigma ^{-1}(y)x=x' z$ for some $x' \in W_0^{J'}$ and $z \in W_{J'}$ . By [Reference Görtz and HeGH10, §2.3], the assumption that $w \mathfrak a$ is in a shrunken Weyl chamber implies that $x \alpha _j<0$ for any $j \in J'$ . In particular,

(5.1) $$ \begin{align} \ell\left(x z ^{-1}\right)=\ell(x)-\ell(z). \end{align} $$

Let $\gamma $ be the unique dominant coweight in the $W_0$ -orbit of $\lambda _w-\rho ^\vee _J+(x') ^{-1} \sigma ^{-1}\left (\rho ^\vee _J\right )$ . By Corollary 5.3, $\gamma \ge _{\mathbb {Z}} \lambda _w^{\flat \mkern -2.4mu\flat }$ . Let $K=\{s \in \mathbb {S}; s(\gamma )=\gamma \}$ and set $y' \in W_0^K$ with $\lambda _w-\rho ^\vee _J+(x') ^{-1} \sigma ^{-1}\left (\rho ^\vee _J\right ) =y'(\gamma )$ .

Set $\alpha>0$ with $(y') ^{-1} \alpha <0$ . Then $\left \langle \gamma , (y') ^{-1} \alpha \right \rangle \le 0$ . On the other hand, if $\left \langle \gamma , (y') ^{-1} \alpha \right \rangle =0$ , then since $y' \in W_0^K$ , we have $\alpha =y' \bigl ((y') ^{-1} \alpha \bigr )<0$ . That is a contradiction. Hence $\langle y'(\gamma ), \alpha \rangle =\left \langle \gamma , (y') ^{-1} \alpha \right \rangle <0$ . Since $\lambda _w-\rho ^\vee _J$ is dominant, $\left \langle \lambda _w-\rho ^\vee _J, \alpha \right \rangle \ge 0$ . Thus $\left \langle (x') ^{-1} \sigma ^{-1}\left (\rho ^\vee _J\right ), \alpha \right \rangle =\left \langle \sigma ^{-1}\left (\rho ^\vee _J\right ), x'(\alpha )\right \rangle <0$ . Since $\sigma ^{-1}\left (\rho ^\vee _J\right )$ is dominant, $x'(\alpha )<0$ . By [Reference Görtz and HeGH10, Lemma 2.6.1], we have

(5.2) $$ \begin{align} \ell(x' y')=\ell(x')-\ell(y'). \end{align} $$

Set $s \in J'$ . Since $x' \in W_0^{J'}$ , we have $\ell (x' s)=\ell (x')+1$ . Thus $\ell (x')-\ell (y')=\ell (x' y')=\ell \bigl ((x' s) (s y') \bigr ) \ge \ell (x' s)-\ell (s y')=\ell (x')+1-\ell (s y')$ . So $\ell (s y') \ge \ell (y')+1$ . Therefore

(5.3) $$ \begin{align} y' \in {}^{J'} W_0. \end{align} $$

In particular, we have

(5.4) $$ \begin{align} \ell\left((y') ^{-1} z\right)=\ell(y')+\ell(z). \end{align} $$

Set $w_1=x z ^{-1} t^{\lambda _w-\rho ^\vee _J} y'$ and $w_2=(y') ^{-1} z t^{\rho ^\vee _J} y$ . Then $w=w_1 w_2$ . By formula (5.3), $t^{\lambda _w-\rho ^\vee _J} y' \in {}^{\mathbb {S}} \tilde {W}$ . By the definition of J, we have $t^{\rho ^\vee _J} y \in {}^{\mathbb {S}} \tilde {W}$ . Hence by equation (2.1), we have

(5.5) $$ \begin{align} \ell(w)=\ell(x)+\ell\left(t^{\lambda_w}\right)-\ell(y) \end{align} $$
(5.6) $$ \begin{align} \ell(w_1)=\ell\left(x z ^{-1}\right)+\ell\left(t^{\lambda_w-\rho^\vee_J}\right)-\ell(y') \end{align} $$
(5.7) $$ \begin{align} \ell(w_2)=\ell\left((y') ^{-1} z\right)+\ell\left(t^{\rho^\vee_J}\right)-\ell(y). \end{align} $$

By equations (5.1) and (5.4), we have

(5.8) $$ \begin{align} \ell(w_1)+\ell(w_2) &=\ell(x)-\ell(z)+\ell\left(t^{\lambda_w-\rho^\vee_J}\right)-\ell(y')+\ell(y')+\ell(z)+\ell\left(t^{\rho^\vee_J}\right)-\ell(y) \nonumber \\ &=\ell(x)+\ell\left(t^{\lambda_w}\right)-\ell(y)=\ell(w). \end{align} $$

By equations (5.2) and (5.4), we have

(5.9) $$ \begin{align} \ell\left((y') ^{-1} z\right)+\ell(x' y') &=\ell(y')+\ell(z)+\ell(x')-\ell(y')=\ell(x')+\ell(z) \nonumber \\ &=\ell(x'z)=\ell\left(\sigma ^{-1}(y) x\right). \end{align} $$

By equation (5.8) we have

Set

Here the isomorphism follows from equation (5.7).

The map $(g, g_1) \mapsto (g_1, b \sigma (g))$ is a universal homeomorphism from $X_{w}(b)$ to $X_1$ . We have $y \sigma \left (x z ^{-1}\right )=\sigma \left (\sigma ^{-1}(y) x z ^{-1}\right )=\sigma (x')$ and

$$ \begin{align*}t^{\rho^\vee_J} y \sigma(w_1)=t^{\rho^\vee_J} \sigma\left(x' t^{\lambda_w-\rho^\vee_J} y'\right)=\sigma(x') \sigma\left(t^{y'(\gamma)}\right) \sigma(y')=\sigma(x' y' t^\gamma).\end{align*} $$

Let

We have

$$ \begin{align*}\dim(X_w(b))=\dim(X_1) \ge \dim(X_2).\end{align*} $$

Since $\gamma $ is dominant, we have $\ell (\sigma (x' y' t^\gamma ))=\ell (\sigma (x' y'))+\ell (\sigma (t^\gamma ))$ . Set

Let $\pi : X_2 \rightarrow X_3$ be the projection map. Set $N_1=\frac {\ell \left (t^{\rho ^\vee _J} y\right )+\ell \left (w_1\right )-\ell \left (x' y' t^\gamma \right )}{2}$ . By Proposition 5.6, the map $\pi $ is surjective and the dimension of each fibre is larger than or equal to $N_1$ .

We show that

(a) $\dim (X_2) \ge \dim (X_3)+N_1$ .

Now suppose that $\dim (X_2)<\dim (X_3)+N_1$ . Let Z be an irreducible component of $X_3$ with $\dim Z=\dim X_3$ . For each irreducible component Y of $\pi ^{-1} (Z)$ , we construct a closed subscheme $Z_Y$ of Z such that $\dim \left (\pi ^{-1}(z) \cap Y\right )<N_1$ if $z \in Z-Z_Y$ . The construction is as follows.

If $\pi (Y)$ is not dense in Z, then let $Z_Y$ be the closure of $\pi (Y)$ . If $\pi (Y)$ is dense in Z, then the morphism $\pi : Y \rightarrow Z$ is dominant. By [Reference Görtz and WedhornGW10, Corollary 14.116], there exists an open dense subscheme V of Z contained in $\pi (Y)$ such that for any $z \in V$ , we have $\dim \left (\pi ^{-1}(z) \cap Y\right )=\dim (Y)-\dim (Z) \le \dim (X_2)-\dim (X_3)<N_1$ . We set $Z_Y=Z-V$ . This finishes our construction.

Note that in either case, $Z_Y$ is a proper subscheme of Z. Hence $\cup _Y Z_Y \subsetneqq Z$ . Set $z \in Z-\cup _Y Z_Y$ . Then $\dim \left (\pi ^{-1}(z) \cap Y\right )<N_1$ for any irreducible component Y of $\pi ^{-1}(Z)$ . Thus $\dim \left (\pi ^{-1}(z)\right )<N_1$ . That gives a contradiction.

So (a) is proved.

Set $a =\sigma ^{-1}\left ((y')^{-1} z\right ) * (x' y')$ . Then

$$ \begin{align*} \operatorname{\mathrm{supp}}_{\sigma}(a) &=\operatorname{\mathrm{supp}}_{\sigma}(\sigma(a))=\operatorname{\mathrm{supp}}_{\sigma}\left((y') ^{-1} z\right) \cup \operatorname{\mathrm{supp}}_{\sigma}(\sigma(x'y')) \\[4pt] &=\operatorname{\mathrm{supp}}_{\sigma}\left((y') ^{-1} z\right) \cup \operatorname{\mathrm{supp}}_{\sigma}(x'y') \\[4pt] & \supset \operatorname{\mathrm{supp}}_{\sigma}\left(x' y' (y') ^{-1} z\right)=\operatorname{\mathrm{supp}}_{\sigma}(x' z) \\[4pt] &=\operatorname{\mathrm{supp}}_{\sigma}(\eta_{\sigma}(w)).\end{align*} $$

We set

By Proposition 5.6 and the same argument as in (a),

$$ \begin{align*}\dim(X_3) \ge \dim(X_5)+\ell\left((y') ^{-1} z\right)+\ell(x' y')-\ell(a)=\dim(X_5)+\ell(\eta_{\sigma}(w))-\ell(a).\end{align*} $$

Notice that $\ell (\sigma (a t^\gamma ))=\ell (\sigma (a))+\ell (\sigma (t^\gamma ))$ . Thus the map $(g_1, g_4) \mapsto g_1$ gives an isomorphism $X_5 \cong X_{\sigma \left (a t^\gamma \right )}(b)$ , which is universally homeomorphic to $X_{a t^\gamma }(b)$ . If $X_{a t^\gamma }(b)\ne \emptyset $ , then $X_{\sigma \left (a t^\gamma \right )}(b) \neq \emptyset $ and $X_{w}(b)\ne \emptyset $ . Note that $\ell \left ((y') ^{-1} z\right )+\ell (x' y')=\ell \left (\sigma ^{-1}(y) x\right )=\ell (\eta _{\sigma }(w))$ . Therefore,

$$ \begin{align*} \dim & X_w(b)-\dim X_{a t^\gamma}(b) \\[4pt] & \ge \frac{\ell\left(t^{\rho^\vee_J} y\right)+\ell(w_1)-\ell\left(x' y' t^\gamma\right)}{2}+\ell(\eta_{\sigma}(w))-\ell(a)\\[4pt] &=\frac{\ell\left(t^{\rho^\vee_J} y\right)+\ell\left((y') ^{-1} z\right)+\ell(w_1)-\ell(x' y' t^\gamma)+\ell(x' y')-\ell(a)}{2}+\frac{\ell(\eta_{\sigma}(w))}{2}-\frac{\ell(a)}{2} \\[4pt] & =\frac{\ell(w_2)+\ell(w_1)-\ell(a t^\gamma)}{2}+\frac{\ell(\eta_{\sigma}(w))}{2}-\frac{\ell(a)}{2} \\[4pt] &=\frac{\ell(w)-\ell(a t^\gamma)}{2}+\frac{\ell(\eta_{\sigma}(w))}{2}-\frac{\ell(a)}{2}=d_{w}(b)-d_{a t^\gamma}(b).\end{align*} $$

So $w \Rightarrow _{\sigma } a t^\gamma $ . The theorem is proved.

6. Proof of main theorem

Now we state our main result.

Theorem 6.1. Suppose that ${\mathbf G}$ is quasi-split over F. Set $b \in \breve G$ and $w \in \tilde {W}$ such that $w \mathfrak a$ is in a shrunken Weyl chamber, $\lambda _w^{\diamondsuit }-\nu _b \in \sum _{\alpha \in \Delta } \mathbb {Q}_{>0} \alpha ^\vee $ and $\left (\lambda _w^{\flat \mkern -2.4mu\flat }\right )^{\diamondsuit } \ge \nu _b$ . Then $X_w(b) \neq \emptyset $ if and only if $\kappa (b)=\kappa (w)$ and $\operatorname {\mathrm {supp}}_{\sigma }(\eta _{\sigma }(w))=\mathbb {S}$ . In this case, $\dim X_w(b)=d_w(b)$ .

Remark 6.2. It is worth mentioning that in most cases, $\lambda _w-\lambda _w^{\flat \mkern -2.4mu\flat }$ is dominant and nonzero. In this case, $\lambda _w^{\diamondsuit }-\left (\lambda _w^{\flat \mkern -2.4mu\flat }\right )^{\diamondsuit } \in \sum _{\alpha \in \Delta } \mathbb {Q}_{>0} \alpha ^\vee $ . However, if ${\mathbf G}$ is split over F and $\lambda _w$ is a minuscule coweight, then $\lambda _w^{\flat \mkern -2.4mu\flat }=\lambda _w$ . Thus the assumption $\lambda _w^{\diamondsuit }-\nu _b \in \sum _{\alpha \in \Delta } \mathbb {Q}_{>0} \alpha ^\vee $ is needed in our statement.

We first prove the theorem and then discuss the assumptions in the statement. In particular, we will give a simple condition where the assumptions are satisfied in Corollary 6.4.

6.1. The $(J, w, \delta )$ -alcove elements

We recall the alcove elements introduced in [Reference Görtz, Haines, Kottwitz and ReumanGHKR10] for split groups and then generalised to quasi-split groups in [Reference Görtz, He and NieGHN15].

For any $J \subset \mathbb {S}$ with $\sigma (J)=J$ , we denote by $\mathbb M_J \subset \mathbf G$ the standard Levi subgroup corresponding to J and let $\mathbb P_J \supset \mathbb M_J$ be the standard parabolic subgroup. Let $\mathbb U_{\mathbb P_J}$ be the unipotent radical of $\mathbb P_J$ .

Set $J \subset \mathbb {S}$ with $\sigma (J)=J$ and $x \in W_0$ . Set $w\in \tilde {W}$ . We say that w is a $(J, x, \sigma )$ -alcove element if $x ^{-1} w \sigma (x) \in \tilde {W}_J$ and $\mathbb {}^{\dot x} \mathbb U_{\mathbb P_J}\left (\breve F\right ) \cap {}^{\dot w} \breve I \subseteq \mathbb {}^{\dot x} \mathbb U_{\mathbb P_J}\left (\breve F\right ) \cap \breve I$ . The following result is proved in [Reference Görtz, He and NieGHN15, Corollary 3.6.1].Footnote 1

Theorem 6.3. Set $[b] \in B(\mathbf G)$ and $w \in \tilde {W}$ . Suppose that w is a $(J, x, \sigma )$ -alcove element. Let $\kappa _{\mathbb M_J}$ be the Kottwitz map for the group $\mathbb M_J$ . If $\kappa _{\mathbb M_J}\left (x ^{-1} w \sigma (x)\right ) \neq \kappa _{\mathbb M_J}(b')$ for any $b' \in [b] \cap \mathbb M_J\left (\breve F\right )$ , then $X_w(b)=\emptyset $ .

6.2. The emptiness pattern

Suppose that $w \mathfrak a$ is in a shrunken Weyl chamber and $\left (\lambda _w^{\flat \mkern -2.4mu\flat }\right )^{\diamondsuit } \ge \nu _b$ . We write w as $w=x t^{\lambda } y$ with $x, y \in W_0$ and $t^{\lambda } y \in {}^{\mathbb {S}} \tilde {W}$ . If $\kappa (b) \neq \kappa (w)$ , then $X_w(b)=\emptyset $ .

Now suppose that $\kappa (b)=\kappa (w)$ and $\operatorname {\mathrm {supp}}_{\sigma }\left (\sigma ^{-1}(y) x\right )\neq \mathbb {S}$ . Set $J=\operatorname {\mathrm {supp}}_{\sigma }\left (\sigma ^{-1}(y) x\right )$ . By [Reference Görtz, He and NieGHN15, Lemma 3.6.3], w is a $\left (J, \sigma ^{-1}(y), \sigma \right )$ -alcove element. Set $b' \in [b] \cap \mathbb M_J\left (\breve F\right )$ . We denote by $\nu ^{\mathbb M_J}_{b'}$ the image of $b'$ under the Newton map for $\mathbb M_J$ . Then $\nu ^{\mathbb M_J}_{b'} \in W_0 (\nu _b)$ . Hence $\nu _b-\nu ^{\mathbb M_J}_{b'} \in \sum _{\alpha \in \Delta } \mathbb {Q}_{\ge 0} \alpha ^\vee $ .

By assumption, $\lambda ^{\diamondsuit }-\nu _b \in \sum _{\alpha \in \Delta } \mathbb {Q}_{>0} \alpha ^\vee $ . Thus $\lambda ^{\diamondsuit }-\nu ^{\mathbb M_J}_{b'} \in \sum _{\alpha \in \Delta } \mathbb {Q}_{>0} \alpha ^\vee $ and cannot be written as a linear combination of the coroots in $\mathbb M_J$ . Therefore $\kappa _{\mathbb M_J}\left (\sigma ^{-1} (y) w y ^{-1}\right ) \neq \kappa _{\mathbb M_J}(b')$ . By Theorem 6.3, $X_w(b)=\emptyset $ .

6.3. Dimension formula

Suppose that $\kappa (w)=\kappa (b)$ and $\operatorname {\mathrm {supp}}_{\sigma }(\eta _{\sigma }(w))=\mathbb {S}$ . By Theorem 5.5, there exist a dominant coweight $\gamma \ge _{\mathbb {Z}} \lambda _w^{\flat \mkern -2.4mu\flat }$ and $a \in W_0$ with $\operatorname {\mathrm {supp}}_{\sigma }(a)=\mathbb {S}$ such that

$$ \begin{align*}w \Rightarrow_{\sigma} a t^\gamma.\end{align*} $$

By our assumption, $\gamma ^{\diamondsuit } \ge \left (\lambda _w^{\flat \mkern -2.4mu\flat }\right )^{\diamondsuit } \ge \nu _b$ . By Theorem 4.2, $\left [\dot t^\gamma \right ]=\left [b_{a t^\gamma }\right ]$ . Since $\kappa (w)=\kappa (t^\gamma )=\kappa (b)$ , we have $[b] \le \left [\dot t^\gamma \right ]$ .

By [Reference HeHe15, Theorem 2.27], $X_{a t^\gamma }(\dot {\tau } ) \neq \emptyset $ , where $\tau \in \Omega $ with $\kappa (w)=\kappa (t^\gamma )=\kappa (\tau )$ . Since $\kappa (w)=\kappa (b)$ , we have $[\dot \tau ] \le [b]$ .

By Theorem 4.2, $a t^\gamma $ is a cordial element. Hence by Theorem 4.1(1), $X_{a t^\gamma }(b) \neq \emptyset $ , and by Theorem 4.1(2), $\dim X_{a t^\gamma }(b)=d_{a t^\gamma }(b)$ .

So by the definition of $\Rightarrow _{\sigma }$ , we have $X_w(b) \neq \emptyset $ and

$$ \begin{align*}\dim X_w(b)-d_w(b) \ge \dim X_{a t^\gamma}(b)-d_{a t^\gamma}(b)=0.\end{align*} $$

Hence $\dim X_w(b) \ge d_w(b)$ . On the other hand, by Theorem 2.1, $\dim X_w(b) \le d_w(b)$ . So $\dim X_w(b)=d_w(b)$ .

6.4. Some remarks on the condition $\left (\lambda _w^{\flat \mkern -2.4mu\flat }\right )^{\diamondsuit } \ge \nu _b$

We first consider the case where $[b]$ is basic. In this case, the condition $\left (\lambda _w^{\flat \mkern -2.4mu\flat }\right )^{\diamondsuit } \ge \nu _b$ follows directly from the condition $\kappa (b)=\kappa (w)$ .

Now we consider nonbasic $[b]$ . Suppose that $\lambda _w^{\diamondsuit } \ge \nu _b+2 \rho ^\vee $ . In this case, although $\lambda _w-2 \rho ^\vee $ may not be dominant, its $\sigma $ -average is dominant and is larger than or equal to $\nu _b$ . By definition, $\lambda _w^{\flat \mkern -2.4mu\flat }-\left (\lambda _w-\rho ^\vee _J-\eta ^\vee _J\right ) \in \sum _{\alpha \in \Delta } \mathbb {Q}_{\ge 0} \alpha ^\vee $ for some J. Note that $2 \rho ^\vee -\rho ^\vee _J-\eta ^\vee _J \in \sum _{\alpha \in \Delta } \mathbb {Q}_{\ge 0} \alpha ^\vee $ . We have $\lambda _w^{\flat \mkern -2.4mu\flat }-\left (\lambda _w-2 \rho ^\vee \right ) \in \sum _{\alpha \in \Delta } \mathbb {Q}_{\ge 0} \alpha ^\vee $ . Hence $\left (\lambda _w^{\flat \mkern -2.4mu\flat }\right )^{\diamondsuit } \ge \lambda _w^{\diamondsuit }-2 \rho ^\vee \ge \nu _b$ . It is also easy to see that $\lambda _w^{\diamondsuit }-\nu _b \in \sum _{\alpha \in \Delta } \mathbb {Q}_{>0} \alpha ^\vee $ .

In particular, if $\lambda _w=n \omega ^\vee $ , where $\omega ^\vee $ is a fundamental coweight and $n \gg 0$ with respect to $[b]$ , then $\lambda _w^{\diamondsuit } \ge \nu _b+2 \rho ^\vee $ , and hence the condition $\left (\lambda _w^{\flat \mkern -2.4mu\flat }\right )^{\diamondsuit } \ge \nu _b$ is satisfied in this case.

Corollary 6.4. Suppose that ${\mathbf G}$ is simple and quasi-split over F. Set $b \in \breve G$ and $w \in \tilde {W}$ such that $w \mathfrak a$ is in a shrunken Weyl chamber. Suppose that $\lambda _w^{\diamondsuit } \ge \nu _b+2 \rho ^\vee $ . Then $X_w(b) \neq \emptyset $ if and only if $\kappa (b)=\kappa (w)$ and $\operatorname {\mathrm {supp}}_{\sigma }(\eta _{\sigma }(w))=\mathbb {S}$ . In this case, $\dim X_w(b)=d_w(b)$ .

6.5. A side remark

By Theorem 4.4, if $X_w(b) \neq \emptyset $ , then $\kappa (b)=\kappa (w)$ and $\nu _b \le \lambda _w^{\diamondsuit }$ .

Set $w \in \tilde {W}$ such that $w \mathfrak a$ is in a shrunken Weyl chamber. If $\operatorname {\mathrm {supp}}_{\sigma }(\eta _{\sigma }(w))=\mathbb {S}$ , then Theorem 6.1 describes the nonemptiness pattern and the dimension formula of $X_w(b)$ for most of the $\sigma $ -conjugacy classes $[b]$ with $\kappa (b)=\kappa (w)$ and $\nu _b \le \lambda _w^{\diamondsuit }$ .

If $\operatorname {\mathrm {supp}}_{\sigma }(\eta _{\sigma }(w))=J \subsetneqq \mathbb {S}$ , then by [Reference Görtz, He and NieGHN15, Lemma 3.6.3] w is a $\left (J, \sigma ^{-1}(y), \sigma \right )$ -alcove element for some $y \in W_0$ . Then the Hodge–Newton decomposition (see [Reference Görtz, Haines, Kottwitz and ReumanGHKR10, Theorem 2.1.4] for the split group and [Reference Görtz, He and NieGHN15, Propositon 2.5.1 & Theorem 3.3.1] in general) reduces the study of $X_w(b)$ to the study of a suitable affine Deligne–Lusztig variety associated to the Levi subgroup $\mathbb M_J$ . One may apply Theorem 6.1 to the latter. In this way, one also obtains an explicit description of the nonemptiness pattern and the dimension formula of $X_w(b)$ for most of the $\sigma $ -conjugacy classes $[b]$ with $\kappa (b)=\kappa (w)$ and $\nu _b \le \lambda _w^{\diamondsuit }$ .

Acknowledgments

We thank S. Nie, E. Viehmann and Q. Yu for helpful discussions. This paper was written during a visit to H. Bao at NUS. We thank the excellent working environment there. We also thank U. Görtz, S. Nie and E. Viehmann for useful comments on a previous version of the paper. Finally, we thank the referees for their helpful suggestions.

The research was partially supported by Hong Kong RGC grant 14300220, by funds connected with the Choh-Ming Chair at CUHK, and by the Xplorer prize.

Conflict of Interest

None.

Footnotes

1 There we assume that $[b]$ is basic. In fact, the assumption is required in [Reference Görtz, He and NieGHN15, Propositon 3.5.1 & Remark 3.6.2], but it is not needed in [Reference Görtz, He and NieGHN15, Corollary 3.6.1].

References

Bhatt, B. and Scholze, P., ‘Projectivity of the Witt vector Grassmannian’, Invent. Math. 209 (2017), 329423.CrossRefGoogle Scholar
Bruhat, F. and Tits, J., ‘Groupes rèductifs sur un corps local, I’, Publ. Math. Inst. Hautes Études Sci. 41 (1972), 5276.CrossRefGoogle Scholar
Deligne, P. and Lusztig, G., ‘Representations of reductive groups over finite fields’, Ann. of Math. (2) 103(1) (1976), 103161.CrossRefGoogle Scholar
Gashi, Q., ‘On a conjecture of Kottwitz and Rapoport’, Ann. Sci. Éc. Norm. Supér. (4) 43(6) (2010), 10171038.CrossRefGoogle Scholar
Görtz, U., Haines, T., Kottwitz, R. and Reuman, D., ‘Affine Deligne-Lusztig varieties in affine flag varieties’, Compos. Math. 146 (2010), 13391382.CrossRefGoogle Scholar
Görtz, U. and He, X., ‘Dimension of affine Deligne-Lusztig varieties in affine flag varieties’, Doc. Math. 15 (2010), 10091028.Google Scholar
Görtz, U., He, X. and Nie, S., ‘ $P$ -alcoves and nonemptiness of affine Deligne-Lusztig varieties’, Ann. Sci. Èc. Norm. Supér. (4) 48 (2015), 647665.CrossRefGoogle Scholar
Görtz, U. and Wedhorn, T., Algebraic Geometry I. Schemes with Examples and Exercises , Advanced Lectures in Mathematics (Vieweg + Teubner, Wiesbaden, Germany, 2010).Google Scholar
Hartl, U. and Viehmann, E., ‘The Newton stratification on deformations of local $G$ -shtukas’, J. Reine Angew. Math. 656 (2011), 87129.CrossRefGoogle Scholar
He, X., ‘A subalgebra of $0$ -Hecke algebra’, J. Algebra 322 (2009), 40304039.CrossRefGoogle Scholar
He, X., ‘Geometric and homological properties of affine Deligne-Lusztig varieties’, Ann. of Math. (2) 179 (2014), 367404.CrossRefGoogle Scholar
He, X., ‘Hecke algebras and $p$ -adic groups’, in Current Developments in Mathematics 2015 (International Press, Somerville, MA, 2016), 73135.Google Scholar
He, X. and Nie, S., ‘Minimal length elements of extended affine Weyl group’, Compos. Math. 150(11) (2014), 19031927.CrossRefGoogle Scholar
He, X. and Rapoport, M., ‘Stratifications in the reduction of Shimura varieties’, Manuscripta Math. 152 (2017), 317343.CrossRefGoogle Scholar
He, X. and Yang, Z., ‘Elements with finite Coxeter part in an affine Weyl group’, J. Algebra 372 (2012), 204210.CrossRefGoogle Scholar
Yu, Q. and He, X., ‘Dimension formula of the affine Deligne-Lusztig variety $X\left(\mu, b\right)$ , Math. Ann. 379 (2021), 17471765.Google Scholar
Iwahori, N. and Matsumoto, H., ‘On some Bruhat decomposition and the structure of the Hecke rings of $p$ -adic Chevalley groups’, Publ. Math. Inst. Hautes Études Sci. 25 (1965), 548.CrossRefGoogle Scholar
Kottwitz, R., ‘Isocrystals with additional structure’, Compos. Math. 56 (1985), 201220.Google Scholar
Kottwitz, R., ‘Isocrystals with additional structure. II’, Compos. Math. 109 (1997), 255339.CrossRefGoogle Scholar
Milićević, E., Schwer, P. and Thomas, A., Dimensions of Affine Deligne-Lusztig Varieties: A New Approach via Labeled Folded Alcove Walks and Root Operators, Memoirs of the American Mathematical Society, vol. 261 (2019), no. 1260.CrossRefGoogle Scholar
Milićević, E. and Viehmann, E., ‘Generic Newton points and the Newton poset in Iwahori-double cosets’, Forum Math. Sigma 8 (2020), E50.Google Scholar
Rapoport, M., ‘A guide to the reduction modulo $p$ of Shimura varieties’, Astérisque 298 (2005), 271318.Google Scholar
Viehmann, E., ‘Truncations of level 1 of elements in the loop group of a reductive group’, Ann. of Math. (2) 179(3) (2014), 10091040.CrossRefGoogle Scholar
Zhu, X., ‘Affine Grassmannians and the geometric Satake in mixed characteristic’, Ann. of Math. (2) 185 (2017), 403492.CrossRefGoogle Scholar