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Derived categories of Gushel–Mukai varieties

Published online by Cambridge University Press:  25 May 2018

Alexander Kuznetsov
Affiliation:
Steklov Mathematical Institute of Russian Academy of Sciences, 8 Gubkin str., Moscow 119991, Russia Interdisciplinary Scientific Center J.-V. Poncelet (CNRS UMI 2615), Moscow, Russia National Research University, Higher School of Economics, Russian Federation email [email protected]
Alexander Perry
Affiliation:
Department of Mathematics, Columbia University, New York, NY 10027, USA email [email protected]
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Abstract

We study the derived categories of coherent sheaves on Gushel–Mukai varieties. In the derived category of such a variety, we isolate a special semiorthogonal component, which is a K3 or Enriques category according to whether the dimension of the variety is even or odd. We analyze the basic properties of this category using Hochschild homology, Hochschild cohomology, and the Grothendieck group. We study the K3 category of a Gushel–Mukai fourfold in more detail. Namely, we show this category is equivalent to the derived category of a K3 surface for a certain codimension 1 family of rational Gushel–Mukai fourfolds, and to the K3 category of a birational cubic fourfold for a certain codimension 3 family. The first of these results verifies a special case of a duality conjecture which we formulate. We discuss our results in the context of the rationality problem for Gushel–Mukai varieties, which was one of the main motivations for this work.

Type
Research Article
Copyright
© The Authors 2018 

1 Introduction

This paper studies the derived categories of coherent sheaves on smooth Gushel–Mukai varieties, with a special focus on the relation to birational geometry and the case of fourfolds.

1.1 Background

For the purpose of this paper, we use the following definition.

Definition 1.1. A Gushel–Mukai (GM) variety is a smooth $n$ -dimensional intersection

$$\begin{eqnarray}X=\operatorname{Cone}(\operatorname{Gr}(2,5))\cap \mathbf{P}^{n+4}\cap Q,\quad 2\leqslant n\leqslant 6,\end{eqnarray}$$

where $\operatorname{Cone}(\operatorname{Gr}(2,5))\subset \mathbf{P}^{10}$ is the cone over the Grassmannian $\operatorname{Gr}(2,5)\subset \mathbf{P}^{9}$ in its Plücker embedding, $\mathbf{P}^{n+4}\subset \mathbf{P}^{10}$ is a linear subspace, and $Q\subset \mathbf{P}^{n+4}$ is a quadric hypersurface.

We note that a more general definition of GM varieties, which includes singular varieties and curves, is given in [Reference Debarre and KuznetsovDK18a, Definition 2.1]. However, the definition there agrees with ours after imposing the condition that a GM variety is smooth of dimension at least $2$ , see [Reference Debarre and KuznetsovDK18a, Proposition 2.28]. The classification results of Gushel [Reference GushelGus83] and Mukai [Reference MukaiMuk89], generalized and simplified in [Reference Debarre and KuznetsovDK18a, Theorem 2.16], show that this class of varieties coincides with the class of all smooth Fano varieties of Picard number 1, coindex 3, and degree 10, together with Brill–Noether general polarized K3 surfaces of degree 10.

In the Fano–Iskovskikh–Mori–Mukai classification of Fano threefolds, GM threefolds occupy an intermediate position between complete intersections in weighted projective spaces and linear sections of homogeneous varieties, and possess a particularly rich birational geometry. The case of GM fourfolds is even more interesting, and was our original source of motivation. These fourfolds are similar to cubic fourfolds from several points of view: birational geometry, Hodge theory, and as we will see, derived categories.

In terms of birational geometry, both types of fourfolds are unirational and rational examples are known. On the other hand, a very general fourfold of either type is expected to be irrational, but to date irrationality has not been shown for a single example.

At the level of Hodge theory, a fourfold of either type has middle cohomology of K3 type, i.e. $h^{0,4}=0$ and $h^{1,3}=1$ . Moreover, there is a classification of Noether–Lefschetz loci where the ‘non-special cohomology’ is isomorphic to (a Tate twist of) the primitive cohomology of a polarized K3 surface. This is due to Hassett for cubics [Reference HassettHas00], and Debarre et al. [Reference Debarre, Iliev and ManivelDIM15] for GM fourfolds.

Finally, the first author studied the derived categories of cubic fourfolds in [Reference KuznetsovKuz10]. For any cubic fourfold $X^{\prime }$ , a ‘K3 category’ ${\mathcal{A}}_{X^{\prime }}$ is constructed as a semiorthogonal component of the derived category $\text{D}^{\text{b}}(X^{\prime })$ , and it is shown for many rational $X^{\prime }$ that ${\mathcal{A}}_{X^{\prime }}$ is equivalent to the derived category of an actual K3 surface. Since their introduction, the categories ${\mathcal{A}}_{X^{\prime }}$ have attracted a great deal of attention, see for instance [Reference Macrì and StellariMS12, Reference Addington and ThomasAT14, Reference Calabrese and ThomasCT16, Reference HuybrechtsHuy17].

1.2 GM categories

We show in this paper that the parallel between GM and cubic fourfolds persists at the level of derived categories. In fact, for any GM variety $X$ (not necessarily of dimension $4$ ) we define a semiorthogonal component ${\mathcal{A}}_{X}$ of its derived category as the orthogonal to an exceptional sequence of vector bundles. Namely, projection from the vertex of $\operatorname{Cone}(\operatorname{Gr}(2,5))$ gives a morphism $f:X\rightarrow \operatorname{Gr}(2,5)$ , which corresponds to a rank $2$ bundle ${\mathcal{U}}_{X}$ on $X$ . If $n=\dim X$ , we show in Proposition 2.3 that there is a semiorthogonal decomposition

$$\begin{eqnarray}\text{D}^{\text{b}}(X)=\langle {\mathcal{A}}_{X},{\mathcal{O}}_{X},{\mathcal{U}}_{X}^{\vee },{\mathcal{O}}_{X}(1),{\mathcal{U}}_{X}^{\vee }(1),\ldots ,{\mathcal{O}}_{X}(n-3),{\mathcal{U}}_{X}^{\vee }(n-3)\rangle .\end{eqnarray}$$

The GM category ${\mathcal{A}}_{X}$ is the main object of study in this paper. Its properties depend on the parity of the dimension $n$ . For instance, we show that in terms of Serre functors, ${\mathcal{A}}_{X}$ is a ‘K3 category’ or ‘Enriques category’ according to whether $n$ is even or odd (Proposition 2.6). We support the K3-Enriques analogy by showing that each GM category has a canonical involution such that the corresponding equivariant category is equivalent to a GM category of opposite parity (Proposition 2.7).

We also compute the Hochschild homology (Proposition 2.9), Hochschild cohomology (Corollary 2.11 and Proposition 2.12), and (in the very general case) the numerical Grothendieck group (Proposition 2.25 and Lemma 2.27) of GM categories. Our computation of Hochschild homology and Grothendieck groups is based on their additivity, while for Hochschild cohomology we rely on results about equivariant Hochschild cohomology from [Reference PerryPer18].

We deduce from our computations structural properties of GM categories. Notably, we show that for any GM variety of odd dimension or for a very general GM variety of even dimension greater than $2$ , the category ${\mathcal{A}}_{X}$ is not equivalent to the derived category of any variety (Proposition 2.29).

1.3 Conjectures on duality and rationality

We formulate two conjectures about GM categories. First we introduce a notion of ‘generalized duality’ between GM varieties. The precise definition of this notion is somewhat involved (see § 3.2), but its salient features are as follows. Generalized duals have the same parity of dimension, and when they have the same dimension they are dual in the sense of [Reference Debarre and KuznetsovDK18a, Definition 3.26]. The space of generalized duals of $X$ is parameterized by the quotient of the projective space  $\mathbf{P}^{5}$ by a finite group. We also formulate a similar notion of ‘generalized GM partners’, which reduces to [Reference Debarre and KuznetsovDK18a, Definition 3.22] when the varieties have the same dimension. We conjecture that generalized dual GM varieties and generalized GM partners have equivalent GM categories (Conjecture 3.7).

Our second conjecture concerns the rationality of GM fourfolds, and is directly inspired by an analogous conjecture for cubic fourfolds from [Reference KuznetsovKuz10]. Namely, we conjecture that the GM category of a rational GM fourfold is equivalent to the derived category of a K3 surface (Conjecture 3.12). Together with Proposition 2.29, this conjecture implies that a very general GM fourfold is not rational.

1.4 Main results

Our first main result gives evidence for the above two conjectures. A GM variety as in Definition 1.1 is called ordinary if $\mathbf{P}^{n+4}$ does not intersect the vertex of $\operatorname{Cone}(\operatorname{Gr}(2,5))$ .

Theorem 1.2. Let $X$ be an ordinary GM fourfold containing a quintic del Pezzo surface. Then there is a $K3$ surface $Y$ such that ${\mathcal{A}}_{X}\simeq \text{D}^{\text{b}}(Y)$ .

For a more precise statement, see Theorem 4.1. The K3 surface $Y$ is in fact a GM surface which is generalized dual to $X$ , and the GM fourfold $X$ is rational (Lemma 4.7). Thus Theorem 1.2 verifies special cases of our duality and rationality conjectures. We note that GM fourfolds as in the theorem form a $23$ -dimensional (codimension 1 in moduli) family.

By Theorem 1.2, the categories ${\mathcal{A}}_{X}$ of GM fourfolds are deformations of the derived category of a K3 surface. Yet, as mentioned above, for very general $X$ these categories are not equivalent to the derived category of a K3 surface. There even exist $X$ such that ${\mathcal{A}}_{X}$ is not equivalent to the twisted derived category of a K3 surface (see Remark 5.9). Families of categories with these properties appear to be quite rare; this is the first example since [Reference KuznetsovKuz10].

Our second main result shows that the K3 categories attached to GM and cubic fourfolds are not only analogous, but in some cases even coincide.

Theorem 1.3. Let $X$ be a generic ordinary GM fourfold containing a plane of type $\operatorname{Gr}(2,3)$ . Then there is a cubic fourfold $X^{\prime }$ such that ${\mathcal{A}}_{X}\simeq {\mathcal{A}}_{X^{\prime }}$ .

For a more precise statement, see Theorem 5.8. The cubic fourfold $X^{\prime }$ is given explicitly by a construction of Debarre et al. [Reference Debarre, Iliev and ManivelDIM15]. In fact, $X^{\prime }$ is birational to $X$ and we use the structure of this birational isomorphism to establish the result. We note that GM fourfolds as in the theorem form a $21$ -dimensional (codimension $3$ in moduli) family. Theorem 1.3 can be considered as a step toward a $4$ -dimensional analogue of [Reference KuznetsovKuz09a], which exhibits mysterious coincidences among the derived categories of Fano threefolds.

1.5 Further directions

The above results relate the K3 categories attached to three different types of varieties: GM fourfolds, cubic fourfolds, and K3 surfaces (in the last case the K3 category is the whole derived category). We call two such varieties $X_{1}$ and $X_{2}$ derived partners if their K3 categories are equivalent. There is also a notion of $X_{1}$ and $X_{2}$ being Hodge-theoretic partners. Roughly speaking, this means that there is an ‘extra’ integral middle-degree Hodge class $\unicode[STIX]{x1D6FC}_{i}$ on $X_{i}$ , such that if $K_{i}\subset \text{H}^{\dim (X_{i})}(X_{i},\mathbf{Z})$ denotes the lattice generated by $\unicode[STIX]{x1D6FC}_{i}$ and certain tautological algebraic cycles on  $X_{i}$ , then the orthogonals $K_{1}^{\bot }$ and $K_{2}^{\bot }$ are isomorphic as polarized Hodge structures (up to a Tate twist). This notion was studied in [Reference HassettHas00, Reference Debarre, Iliev and ManivelDIM15], under the terminology that ‘ $X_{2}$ is associated to $X_{1}$ ’. Using lattice theoretic techniques, countably many families of GM fourfolds with Hodge-theoretic K3 and cubic fourfold partners are produced in [Reference Debarre, Iliev and ManivelDIM15].

We expect that a GM fourfold has a derived partner of a given type if and only if it has a Hodge-theoretic partner of the same type. Theorems 1.2 and 1.3 can be thought of as evidence for this expectation, since by [Reference Debarre, Iliev and ManivelDIM15, §§ 7.5 and 7.2] a GM fourfold as in Theorem 1.2 or Theorem 1.3 has a Hodge-theoretic K3 or cubic fourfold partner, respectively. Addington and Thomas [Reference Addington and ThomasAT14] proved (generically) the analogous expectation for K3 partners of cubic fourfolds. Their method is deformation theoretic, and requires as a starting point an analogue of Theorem 1.2 for cubic fourfolds.

Finally, we note that there are some other Fano varieties which fit into the above story, i.e. whose derived category contains a K3 category. One example is provided by a hyperplane section of the Grassmannian $\operatorname{Gr}(3,10)$ , see [Reference Debarre and VoisinDV10] for a discussion of related geometric questions and [Reference KuznetsovKuz16a, Corollary 4.4] for the construction of a K3 category. To find other examples, one can use available classification results for Fano fourfolds. In [Reference KüchleKüc95] Küchle classified Fano fourfolds of index $1$ which can be represented as zero loci of equivariant vector bundles on Grassmannians. Among these, three types, labeled (c5), (c7), and (d3) in [Reference KüchleKüc95], have middle Hodge structure of K3 type. In [Reference KuznetsovKuz15b] it was shown that fourfolds of type (d3) are isomorphic to the blowup of the space $\mathbf{P}^{1}\times \mathbf{P}^{1}\times \mathbf{P}^{1}\times \mathbf{P}^{1}$ in a K3 surface, and those of type (c7) are isomorphic to the blowup of a cubic fourfold in a Veronese surface. In particular, these fourfolds do indeed have a K3 category in their derived category, but they reduce to known examples. Fourfolds of type (c5), however, conjecturally give rise to genuinely new K3 categories (see [Reference KuznetsovKuz16c] for a discussion of the geometry of these fourfolds).

1.6 Organization of the paper

In § 2, we define GM categories and study their basic properties. After recalling some facts about GM varieties in § 2.1, we define GM categories in § 2.2. In §§ 2.32.7, we study some basic invariants of GM categories (Serre functors, Hochschild homology and cohomology, and Grothendieck groups) and as an application show that GM categories are usually not equivalent to the derived category of a variety. In § 2.8 we show that GM categories are self-dual, i.e. admit an equivalence with the opposite category.

In § 3, we formulate our conjectures about the duality and rationality of GM varieties. The preliminary § 3.1 recalls from [Reference Debarre and KuznetsovDK18a, § 3] a description of the set of isomorphism classes of GM varieties in terms of Lagrangian data. In § 3.2 we state the duality conjecture and discuss its consequences, and in § 3.3 we discuss the rationality conjecture. This section is independent of the material in §§ 2.32.8.

The purpose of § 4 is to prove Theorem 4.1, a more precise version of Theorem 1.2 from above. The statement of Theorem 4.1 requires the duality terminology introduced in § 3.2. However, in § 4.2 we translate Theorem 4.1 into a statement that does not involve this terminology. From then on, § 4 can be read independently from the rest of the paper.

The goal of § 5 is to prove Theorem 5.8, a more precise version of Theorem 1.3 from above. This section can also be read independently from the rest of the paper.

Finally, in Appendix A, we prove that GM varieties of a fixed dimension form a smooth and irreducible Deligne–Mumford stack, whose dimension we compute. This result is not used in an essential way in the body of the paper, but it is psychologically useful.

1.7 Notation and conventions

We work over an algebraically closed field $\mathbf{k}$ of characteristic  $0$ . A variety is an integral, separated scheme of finite type over  $\mathbf{k}$ . A vector bundle on a variety $X$ is a finite locally free ${\mathcal{O}}_{X}$ -module. The projective bundle of a vector bundle ${\mathcal{E}}$ on a variety $X$ is

with ${\mathcal{O}}_{\mathbf{P}({\mathcal{E}})}(1)$ normalized so that $\unicode[STIX]{x1D70B}_{\ast }{\mathcal{O}}_{\mathbf{P}({\mathcal{E}})}(1)={\mathcal{E}}^{\vee }$ . We often commit the following convenient abuse of notation: given a divisor class $D$ on a variety $X$ , we denote still by $D$ its pullback to any variety mapping to $X$ . Throughout the paper, we use $V_{n}$ to denote an $n$ -dimensional vector space. We denote by $\mathbf{G}=\operatorname{Gr}(2,V_{5})$ the Grassmannian of $2$ -dimensional subspaces of  $V_{5}$ .

In this paper, triangulated categories are $\mathbf{k}$ -linear and functors between them are $\mathbf{k}$ -linear and exact. For a variety $X$ , by the derived category $\text{D}^{\text{b}}(X)$ we mean the bounded derived category of coherent sheaves on $X$ , regarded as a triangulated category. For a morphism of varieties $f:X\rightarrow Y$ , we write $f_{\ast }:\text{D}^{\text{b}}(X)\rightarrow \text{D}^{\text{b}}(Y)$ for the derived pushforward (provided  $f$ is proper), and $f^{\ast }:\text{D}^{\text{b}}(Y)\rightarrow \text{D}^{\text{b}}(X)$ for the derived pullback (provided $f$ has finite $\operatorname{Tor}$ -dimension). For objects ${\mathcal{F}},{\mathcal{G}}\in \text{D}^{\text{b}}(X)$ , we write ${\mathcal{F}}\otimes {\mathcal{G}}$ for the derived tensor product.

We write ${\mathcal{T}}=\langle {\mathcal{A}}_{1},\ldots ,{\mathcal{A}}_{n}\rangle$ for a semiorthogonal decomposition of a triangulated category  ${\mathcal{T}}$ with components ${\mathcal{A}}_{1},\ldots ,{\mathcal{A}}_{n}$ . For an admissible subcategory ${\mathcal{A}}\subset {\mathcal{T}}$ we write

$$\begin{eqnarray}\displaystyle {\mathcal{A}}^{\bot } & = & \displaystyle \{{\mathcal{F}}\in {\mathcal{T}}\mid \operatorname{Hom}({\mathcal{G}},{\mathcal{F}})=0\text{ for all }{\mathcal{G}}\in {\mathcal{A}}\},\nonumber\\ \displaystyle \,^{\bot }{\mathcal{A}} & = & \displaystyle \{{\mathcal{F}}\in {\mathcal{T}}\mid \operatorname{Hom}({\mathcal{F}},{\mathcal{G}})=0\text{ for all }{\mathcal{G}}\in {\mathcal{A}}\},\nonumber\end{eqnarray}$$

for its right and left orthogonals, so that we have ${\mathcal{T}}=\langle {\mathcal{A}}^{\bot },{\mathcal{A}}\rangle =\langle {\mathcal{A}},^{\bot }{\mathcal{A}}\rangle$ .

We regard graded vector spaces as complexes with trivial differential, so that any such vector space can be written as $W_{\bullet }=\bigoplus _{n}W_{n}[-n]$ , where $W_{n}$ denotes the degree $n$ piece. We often suppress the degree $0$ shift $[0]$ from our notation.

2 GM categories

In this section, we define GM categories and study their basic properties. We start with a quick review of the key features of GM varieties.

2.1 GM varieties

Let $V_{5}$ be a $5$ -dimensional vector space and $\mathbf{G}=\operatorname{Gr}(2,V_{5})$ the Grassmannian of $2$ -dimensional subspaces. Consider the Plücker embedding $\mathbf{G}{\hookrightarrow}\mathbf{P}(\wedge ^{2}V_{5})$ and let $\operatorname{Cone}(\mathbf{G})\subset \mathbf{P}(\mathbf{k}\oplus \wedge ^{2}V_{5})$ be the cone over $\mathbf{G}$ . Further, let

$$\begin{eqnarray}W\subset \mathbf{k}\oplus \wedge ^{2}V_{5}\end{eqnarray}$$

be a linear subspace of dimension $n+5$ with $2\leqslant n\leqslant 6$ , and $Q\subset \mathbf{P}(W)$ a quadric hypersurface. By Definition 1.1, if the intersection

(2.1) $$\begin{eqnarray}X=\operatorname{Cone}(\mathbf{G})\cap Q\end{eqnarray}$$

is smooth and transverse, then $X$ is a GM variety of dimension $n$ , and every GM variety can be written in this form.

There is a natural polarization $H$ on a GM variety $X$ , given by the restriction of the hyperplane class on $\mathbf{P}(\mathbf{k}\oplus \wedge ^{2}V_{5})$ ; we denote by ${\mathcal{O}}_{X}(1)$ the corresponding line bundle on $X$ . It is straightforward to check that

(2.2) $$\begin{eqnarray}H^{n}=10\quad \text{and}\quad -K_{X}=(n-2)H.\end{eqnarray}$$

Moreover, we have

(2.3) $$\begin{eqnarray}\begin{array}{@{}ll@{}}\text{if }\dim (X)\geqslant 3, & \text{then }\operatorname{Pic}(X)=\mathbf{Z}H,\quad \text{and}\\ \text{if }\dim (X)=2, & \text{then }(X,H)\text{ is a Brill–Noether general K3 surface}.\end{array}\end{eqnarray}$$

Conversely, by [Reference Debarre and KuznetsovDK18a, Theorem 2.16] any smooth projective polarized variety of dimension ${\geqslant}2$ satisfying (2.3) and (2.2) is a GM variety.

The intersection $\operatorname{Cone}(\mathbf{G})\cap Q$ does not contain the vertex of the cone, since $X$ is smooth. Hence projection from the vertex defines a regular map

$$\begin{eqnarray}f:X\rightarrow \mathbf{G},\end{eqnarray}$$

called the Gushel map. Let ${\mathcal{U}}$ be the rank $2$ tautological subbundle on $\mathbf{G}$ . Then ${\mathcal{U}}_{X}=f^{\ast }{\mathcal{U}}$ is a rank 2 vector bundle on $X$ , called the Gushel bundle. By [Reference Debarre and KuznetsovDK18a, § 2.1], the Gushel map and the Gushel bundle are canonically associated to $X$ , i.e. only depend on the abstract polarized variety $(X,H)$ and not on the particular realization (2.1). In particular, so is the space $V_{5}$ (being the dual of the space of sections of  ${\mathcal{U}}_{X}^{\vee }$ ), and we will sometimes write it as $V_{5}(X)$ to emphasize this. The space $W$ is also canonically associated to $X$ , since its dual is the space of global sections of the line bundle ${\mathcal{O}}_{X}(1)$ . The quadric $Q$ , however, is not canonically associated to $X$ , see § 3.1.

The intersection

$$\begin{eqnarray}M_{X}=\operatorname{Cone}(\mathbf{G})\cap \mathbf{P}(W)\end{eqnarray}$$

is called the Grassmannian hull of $X$ . Note that $X=M_{X}\cap Q$ is a quadric section of $M_{X}$ . Let  $W^{\prime }$ be the projection of $W$ to $\wedge ^{2}V_{5}$ . The intersection

(2.4) $$\begin{eqnarray}M_{X}^{\prime }=\mathbf{G}\cap \mathbf{P}(W^{\prime })\end{eqnarray}$$

is called the projected Grassmannian hull of $X$ . Again by [Reference Debarre and KuznetsovDK18a], both $M_{X}$ and $M_{X}^{\prime }$ are canonically associated to $X$ .

The Gushel map is either an embedding or a double covering of $M_{X}^{\prime }$ , according to whether the projection map $W\rightarrow W^{\prime }$ is an isomorphism or has $1$ -dimensional kernel. In the first case, $W\cong W^{\prime }$ and $M_{X}\cong M_{X}^{\prime }$ . Then considering $Q$ as a subvariety of $\mathbf{P}(W^{\prime })$ , we have

(2.5) $$\begin{eqnarray}X\cong M_{X}^{\prime }\cap Q.\end{eqnarray}$$

That is, $X$ is a quadric section of a linear section of the Grassmannian $\mathbf{G}$ . A GM variety of this type is called ordinary.

If the map $W\rightarrow W^{\prime }$ has $1$ -dimensional kernel, then we have $\mathbf{P}(W)=\operatorname{Cone}(\mathbf{P}(W^{\prime }))$ and $M_{X}=\operatorname{Cone}(M_{X}^{\prime })$ . As $Q$ does not contain the vertex of the cone (by smoothness of  $X$ ), projection from the vertex gives a double cover

(2.6) $$\begin{eqnarray}X\xrightarrow[{}]{~2:1~}M_{X}^{\prime }.\end{eqnarray}$$

That is, $X$ is a double cover of a linear section of the Grassmannian $\mathbf{G}$ . A GM variety of this type is called special.

Lemma 2.1 [Reference Debarre and KuznetsovDK18a, Proposition 2.22].

Let $X$ be a GM variety of dimension $n$ . Then the intersection (2.4) defining $M_{X}^{\prime }$ is dimensionally transverse. Moreover:

  1. (1) if $n\geqslant 3$ , or if $n=2$ and $X$ is special, then $M_{X}^{\prime }$ is smooth;

  2. (2) if $n=2$ and $X$ is ordinary, then $M_{X}^{\prime }$ has at worst rational double point singularities.

By Lemma 2.1, if $X$ is special then $M_{X}^{\prime }$ is smooth. Further, by [Reference Debarre and KuznetsovDK18a, § 2.5] the branch divisor of the double cover (2.6) is the smooth intersection $X^{\prime }=\mathbf{G}\cap Q^{\prime }$ , where $Q^{\prime }=Q\cap \mathbf{P}(W^{\prime })$ is a quadric hypersurface in $\mathbf{P}(W^{\prime })$ . Hence, as long as $n\geqslant 3$ , the branch divisor $X^{\prime }$ of (2.6) is an ordinary GM variety of dimension $n-1$ . This gives rise to an operation taking a GM variety of one type to the opposite type, by defining in this situation

(2.7) $$\begin{eqnarray}X^{\text{op}}=X^{\prime }\quad \text{and}\quad (X^{\prime })^{\text{op}}=X.\end{eqnarray}$$

Note that we have $\dim X^{\text{op}}=\dim X\pm 1$ . The opposite GM variety is not defined for special GM surfaces.

2.2 Definition of GM categories

By the discussion in § 2.1, any GM variety $X$ of dimension $n\geqslant 3$ is obtained from a smooth linear section $M_{X}^{\prime }$ of $\mathbf{G}$ by taking a quadric section or a branched double cover. To describe a natural semiorthogonal decomposition of $\text{D}^{\text{b}}(X)$ , we first recall that $\mathbf{G}$ and its smooth linear sections of dimension at least  $3$ admit rectangular Lefschetz decompositions (in the sense of [Reference KuznetsovKuz07, § 4]) of their derived categories. Note that the bundles ${\mathcal{O}}_{\mathbf{G}},{\mathcal{U}}^{\vee }$ form an exceptional pair in $\text{D}^{\text{b}}(\mathbf{G})$ , where recall ${\mathcal{U}}$ denotes the tautological rank $2$ bundle. Let

(2.8) $$\begin{eqnarray}{\mathcal{B}}=\langle {\mathcal{O}}_{\mathbf{G}},{\mathcal{U}}^{\vee }\rangle \subset \text{D}^{\text{b}}(\mathbf{G})\end{eqnarray}$$

be the triangulated subcategory they generate. The following result holds by [Reference KuznetsovKuz06, § 6.1].

Lemma 2.2. Let $M$ be a smooth linear section of the Grassmannian $\mathbf{G}\subset \mathbf{P}(\wedge ^{2}V_{5})$ of dimension $N\geqslant 3$ . Let $i:M{\hookrightarrow}\mathbf{G}$ be the inclusion.

  1. (1) The functor $i^{\ast }:\text{D}^{\text{b}}(\mathbf{G})\rightarrow \text{D}^{\text{b}}(M)$ is fully faithful on ${\mathcal{B}}\subset \text{D}^{\text{b}}(\mathbf{G})$ .

  2. (2) Denoting the essential image of ${\mathcal{B}}$ by ${\mathcal{B}}_{M}$ , there is a semiorthogonal decomposition

    (2.9) $$\begin{eqnarray}\text{D}^{\text{b}}(M)=\langle {\mathcal{B}}_{M},{\mathcal{B}}_{M}(1),\ldots ,{\mathcal{B}}_{M}(N-2)\rangle .\end{eqnarray}$$

The next result gives a semiorthogonal decomposition of the derived category of a GM variety.

Proposition 2.3. Let $X$ be a GM variety of dimension $n\geqslant 3$ . Let $f:X\rightarrow \mathbf{G}$ be the Gushel map.

  1. (1) The functor $f^{\ast }:\text{D}^{\text{b}}(\mathbf{G})\rightarrow \text{D}^{\text{b}}(X)$ is fully faithful on ${\mathcal{B}}\subset \text{D}^{\text{b}}(\mathbf{G})$ .

  2. (2) Denoting the essential image of ${\mathcal{B}}$ by ${\mathcal{B}}_{X}$ , so that ${\mathcal{B}}_{X}=\langle {\mathcal{O}}_{X},{\mathcal{U}}_{X}^{\vee }\rangle$ , there is a semiorthogonal decomposition

    (2.10) $$\begin{eqnarray}\text{D}^{\text{b}}(X)=\langle {\mathcal{A}}_{X},{\mathcal{B}}_{X},{\mathcal{B}}_{X}(1),\ldots ,{\mathcal{B}}_{X}(n-3)\rangle ,\end{eqnarray}$$
    where ${\mathcal{A}}_{X}$ is the right orthogonal category to $\langle {\mathcal{B}}_{X},\ldots ,{\mathcal{B}}_{X}(n-3)\rangle \subset \text{D}^{\text{b}}(X)$ .

Thus $\text{D}^{\text{b}}(X)$ has a semiorthogonal decomposition with the category ${\mathcal{A}}_{X}$ and $2(n-2)$ exceptional objects as components.

Remark 2.4. If $n=2$ we set ${\mathcal{A}}_{X}=\text{D}^{\text{b}}(X)$ , so that (2.10) still holds.

Proof. The Gushel map factors through the map $X\rightarrow M_{X}^{\prime }$ to the projected Grassmannian hull  $M_{X}^{\prime }$ defined by (2.4). By Lemma 2.1, $M_{X}^{\prime }$ is smooth and has dimension $n+1$ if $X$ is ordinary, or dimension $n$ if $X$ is special. In particular, $\text{D}^{\text{b}}(M_{X}^{\prime })$ has a semiorthogonal decomposition of the form (2.9). Further, $X\rightarrow M_{X}^{\prime }$ realizes $X$ as a quadric section (2.5) if $X$ is ordinary, or as a double cover (2.6) if $X$ is special. Now applying [Reference Kuznetsov and PerryKP17, Lemmas 5.1 and 5.5] gives the result.◻

Definition 2.5. Let $X$ be a GM variety. The GM category of $X$ is the category ${\mathcal{A}}_{X}$ defined by the semiorthogonal decomposition (2.10).

More explicitly, using the definition (2.8) of ${\mathcal{B}}$ , the defining semiorthogonal decomposition of a GM category ${\mathcal{A}}_{X}$ can be written as

(2.11) $$\begin{eqnarray}\text{D}^{\text{b}}(X)=\langle {\mathcal{A}}_{X},{\mathcal{O}}_{X},{\mathcal{U}}_{X}^{\vee },\ldots ,{\mathcal{O}}_{X}(n-3),{\mathcal{U}}_{X}^{\vee }(n-3)\rangle .\end{eqnarray}$$

The GM category ${\mathcal{A}}_{X}$ is the main object of study in this paper. As we will see below, its properties depend strongly on the parity of $\dim (X)$ . For this reason, we sometimes emphasize the parity of $\dim (X)$ by calling ${\mathcal{A}}_{X}$ an even or odd GM category according to whether $\dim (X)$ is even or odd.

2.3 Serre functors of GM categories

Recall from [Reference Bondal and KapranovBK90] that a Serre functor for a triangulated category ${\mathcal{T}}$ is an autoequivalence  $\text{S}_{{\mathcal{T}}}$ of  ${\mathcal{T}}$ with bifunctorial isomorphisms

$$\begin{eqnarray}\operatorname{Hom}({\mathcal{F}},\text{S}_{{\mathcal{T}}}({\mathcal{G}}))\cong \operatorname{Hom}({\mathcal{G}},{\mathcal{F}})^{\vee }\end{eqnarray}$$

for ${\mathcal{F}},{\mathcal{G}}\in {\mathcal{T}}$ . If a Serre functor exists, it is unique. If $X$ is a smooth proper variety, then $\text{D}^{\text{b}}(X)$ has a Serre functor given by the formula

(2.12) $$\begin{eqnarray}\text{S}_{\text{D}^{\text{b}}(X)}({\mathcal{F}})={\mathcal{F}}\otimes \unicode[STIX]{x1D714}_{X}[\dim X].\end{eqnarray}$$

Moreover, given an admissible subcategory ${\mathcal{A}}\subset {\mathcal{T}}$ , if ${\mathcal{T}}$ admits a Serre functor then so does  ${\mathcal{A}}$ . Using [Reference KuznetsovKuz16a], we can describe the Serre functor of a GM category.

Proposition 2.6. Let $X$ be a GM variety of dimension $n$ .

  1. (1) If $n$ is even, the Serre functor of the GM category ${\mathcal{A}}_{X}$ satisfies $\text{S}_{{\mathcal{A}}_{X}}\cong [2]$ .

  2. (2) If $n$ is odd, the Serre functor of the GM category ${\mathcal{A}}_{X}$ satisfies $\text{S}_{{\mathcal{A}}_{X}}\cong \unicode[STIX]{x1D70E}\circ [2]$ for a non-trivial involutive autoequivalence $\unicode[STIX]{x1D70E}$ of ${\mathcal{A}}_{X}$ . If in addition $X$ is special, then $\unicode[STIX]{x1D70E}$ is induced by the involution of the double cover (2.6).

Proof. If $n=2$ , then ${\mathcal{A}}_{X}=\text{D}^{\text{b}}(X)$ and $X$ is a K3 surface, so the result holds by (2.12). If $n\geqslant 3$ , then as in the proof of Proposition 2.3 we may express $X$ as a quadric section or double cover of the smooth variety $M_{X}^{\prime }$ . It is easy to see the length $m$ of the semiorthogonal decomposition of $\text{D}^{\text{b}}(M_{X}^{\prime })$ given by Lemma 2.2 satisfies $K_{M_{X}^{\prime }}=-mH$ , where $H$ is the restriction of the ample generator of $\operatorname{Pic}(\mathbf{G})$ . Hence we may apply [Reference KuznetsovKuz16a, Corollaries 3.7 and 3.8] to see that the Serre functors have the desired form.

If $\unicode[STIX]{x1D70E}$ were trivial, then the Hochschild homology $\operatorname{HH}_{-2}({\mathcal{A}}_{X})$ would be non-trivial (see Proposition 2.10), which contradicts the computation of Proposition 2.9 below.◻

Proposition 2.6 shows that even GM categories can be regarded as ‘non-commutative K3 surfaces’, and odd GM categories can be regarded as ‘non-commutative Enriques surfaces’. This analogy goes further than the relation between Serre functors. For instance, any Enriques surface (in characteristic $0$ ) is the quotient of a K3 surface by an involution. Similarly, the results of [Reference Kuznetsov and PerryKP17] show that odd GM categories can be described as ‘quotients’ of even GM categories by involutions. To state this precisely, recall from § 2.1 that unless $X$ is a special GM surface, there is an associated GM variety $X^{\text{op}}$ of the opposite type and parity of dimension. The following result is proved in [Reference Kuznetsov and PerryKP17, § 8.2].

Proposition 2.7. Let $X$ be a GM variety which is not a special GM surface. Then there is a  $\mathbf{Z}/2$ -action on the GM category  ${\mathcal{A}}_{X}$ such that if ${\mathcal{A}}_{X}^{\mathbf{Z}/2}$ denotes the equivariant category, then there is an equivalence

$$\begin{eqnarray}{\mathcal{A}}_{X}^{\mathbf{Z}/2}\simeq {\mathcal{A}}_{X^{\text{op}}}.\end{eqnarray}$$

If $\unicode[STIX]{x1D70E}$ is the autoequivalence generating the $\mathbf{Z}/2$ -action on ${\mathcal{A}}_{X}$ , then $\unicode[STIX]{x1D70E}$ is induced by the involution of the double covering $X\rightarrow M_{X}^{\prime }$ if $X$ is special, and $\unicode[STIX]{x1D70E}=\text{S}_{{\mathcal{A}}_{X}}\circ [-2]$ if $\dim (X)$ is odd.

2.4 Hochschild homology of GM categories

Given a suitably enhanced triangulated category ${\mathcal{A}}$ , there is an invariant $\operatorname{HH}_{\bullet }({\mathcal{A}})$ called its Hochschild homology, which is a graded $\mathbf{k}$ -vector space. We will exclusively be interested in admissible subcategories of the derived category of a smooth projective variety. For a definition of Hochschild homology in this context, see [Reference KuznetsovKuz09b].

If ${\mathcal{A}}=\text{D}^{\text{b}}(X)$ , we write $\operatorname{HH}_{\bullet }(X)$ for $\operatorname{HH}_{\bullet }({\mathcal{A}})$ . The Hochschild–Kostant–Rosenberg (HKR) isomorphism gives the following explicit description of Hochschild homology in this case [Reference MarkarianMar09]:

(2.13) $$\begin{eqnarray}\operatorname{HH}_{i}(X)\cong \bigoplus _{q-p=i}\text{H}^{q}(X,\unicode[STIX]{x1D6FA}_{X}^{p}).\end{eqnarray}$$

An important property of Hochschild homology is that it is additive under semiorthogonal decompositions.

Theorem 2.8 [Reference KuznetsovKuz09b, Theorem 7.3].

Let $X$ be a smooth projective variety. Given a semiorthogonal decomposition $\text{D}^{\text{b}}(X)=\langle {\mathcal{A}}_{1},{\mathcal{A}}_{2},\ldots ,{\mathcal{A}}_{m}\rangle$ , there is an isomorphism

$$\begin{eqnarray}\operatorname{HH}_{\bullet }(X)\cong \bigoplus _{i=1}^{m}\operatorname{HH}_{\bullet }({\mathcal{A}}_{i}).\end{eqnarray}$$

By combining this additivity property with the HKR isomorphism for GM varieties, we can compute the Hochschild homology of GM categories.

Proposition 2.9. Let $X$ be a GM variety of dimension $n$ . Then

$$\begin{eqnarray}\operatorname{HH}_{\bullet }({\mathcal{A}}_{X})\cong \left\{\begin{array}{@{}cccccl@{}}\mathbf{k}[2]\hspace{4.0pt} & \oplus \hspace{4.0pt} & \mathbf{k}^{22}\hspace{4.0pt} & \oplus \hspace{4.0pt} & \mathbf{k}[-2] & \text{if }n\text{ is even,}\\ \mathbf{k}^{10}[1]\hspace{4.0pt} & \oplus \hspace{4.0pt} & \mathbf{k}^{2}\hspace{4.0pt} & \oplus \hspace{4.0pt} & \mathbf{k}^{10}[-1] & \text{if }n\text{ is odd.}\end{array}\right.\end{eqnarray}$$

Proof. By (2.11) there is a semiorthogonal decomposition of $\text{D}^{\text{b}}(X)$ with ${\mathcal{A}}_{X}$ and  $2(n-2)$ exceptional objects as components. Since the category generated by an exceptional object is equivalent to the derived category of a point, its Hochschild homology is just $\mathbf{k}$ . Hence by additivity,

$$\begin{eqnarray}\operatorname{HH}_{\bullet }(X)\cong \operatorname{HH}_{\bullet }({\mathcal{A}}_{X})\oplus \mathbf{k}^{2(n-2)}.\end{eqnarray}$$

By (2.13) the graded dimension of $\operatorname{HH}_{\bullet }(X)$ can be computed by summing the columns of the Hodge diamond of $X$ , which looks as follows (see [Reference LogachevLog12, Reference Iliev and ManivelIM11, Reference NagelNag98, Reference Debarre and KuznetsovDK17]):

Now the lemma follows by inspection. ◻

2.5 Hochschild cohomology of GM categories

Given a suitably enhanced triangulated category ${\mathcal{A}}$ , there is also an invariant $\operatorname{HH}^{\bullet }({\mathcal{A}})$ called its Hochschild cohomology, which has the structure of a graded $\mathbf{k}$ -algebra. Again, for a definition in the case where ${\mathcal{A}}$ is an admissible subcategory of the derived category of a smooth projective variety, see [Reference KuznetsovKuz09b].

If ${\mathcal{A}}=\text{D}^{\text{b}}(X)$ , we write $\operatorname{HH}^{\bullet }(X)$ for $\operatorname{HH}^{\bullet }({\mathcal{A}})$ . There is the following version of the HKR isomorphism for Hochschild cohomology [Reference MarkarianMar09]:

(2.14) $$\begin{eqnarray}\operatorname{HH}^{i}(X)\cong \bigoplus _{p+q=i}\text{H}^{q}(X,\wedge ^{p}\text{T}_{X}).\end{eqnarray}$$

Hochschild cohomology is not additive under semiorthogonal decompositions, and so it is generally much harder to compute than Hochschild homology. There is, however, a case when the computation simplifies considerably. Recall that a triangulated category ${\mathcal{A}}$ is called $n$ -Calabi–Yau if the shift functor $[n]$ is a Serre functor for ${\mathcal{A}}$ .

Proposition 2.10 [Reference KuznetsovKuz16a, Proposition 5.2].

Let ${\mathcal{A}}$ be an admissible subcategory of $\text{D}^{\text{b}}(X)$ for a smooth projective variety $X$ . If ${\mathcal{A}}$ is an $n$ -Calabi–Yau category, then for each $i$ there is an isomorphism of vector spaces

$$\begin{eqnarray}\operatorname{HH}^{i}({\mathcal{A}})\cong \operatorname{HH}_{i-n}({\mathcal{A}}).\end{eqnarray}$$

This immediately applies to even GM categories, as by Proposition 2.6 they are $2$ -Calabi–Yau.

Corollary 2.11. Let $X$ be a GM variety of even dimension. Then

$$\begin{eqnarray}\operatorname{HH}^{\bullet }({\mathcal{A}}_{X})\cong \mathbf{k}\oplus \mathbf{k}^{22}[-2]\oplus \mathbf{k}[-4].\end{eqnarray}$$

The Hochschild cohomology of odd GM categories is significantly harder to compute. Our strategy is to exploit the fact that there is a $\mathbf{Z}/2$ -action on such a category, with invariants an even GM category. By the results of [Reference PerryPer18], this reduces us to a problem involving the Hochschild cohomology of an even GM category and the Hochschild homology of an odd GM category.

Proposition 2.12. Let $X$ be a GM variety of odd dimension. Then

$$\begin{eqnarray}\operatorname{HH}^{\bullet }({\mathcal{A}}_{X})\cong \mathbf{k}\oplus \mathbf{k}^{20}[-2]\oplus \mathbf{k}[-4].\end{eqnarray}$$

Proof. Recall that by Proposition 2.7 there is a $\mathbf{Z}/2$ -action on ${\mathcal{A}}_{X}$ such that if $\unicode[STIX]{x1D70E}:{\mathcal{A}}_{X}\rightarrow {\mathcal{A}}_{X}$ denotes the corresponding involutive autoequivalence, then:

  1. (1) $\text{S}_{{\mathcal{A}}_{X}}=\unicode[STIX]{x1D70E}\circ [2]$ is a Serre functor for ${\mathcal{A}}_{X}$ ;

  2. (2) ${\mathcal{A}}_{X}^{\mathbf{Z}/2}\simeq {\mathcal{A}}_{X^{\text{op}}}$ , where $X^{\text{op}}$ is the opposite variety to $X$ .

As stated, these are results at the level of triangulated categories, but they also hold at the enhanced level. Namely, in the terminology of [Reference PerryPer18], there is a $\mathbf{k}$ -linear stable $\infty$ -category $\text{D}^{\text{b}}(X)^{\text{enh}}$ (denoted $\text{Perf}(X)$ in [Reference PerryPer18]) with homotopy category $\text{D}^{\text{b}}(X)$ . The category $\text{D}^{\text{b}}(X)^{\text{enh}}$ admits a semiorthogonal decomposition of the same form as (2.10), which defines a $\mathbf{k}$ -linear stable $\infty$ -category ${\mathcal{A}}_{X}^{\text{enh}}$ whose homotopy category is ${\mathcal{A}}_{X}$ . If $\unicode[STIX]{x1D70E}^{\text{enh}}:{\mathcal{A}}_{X}^{\text{enh}}\rightarrow {\mathcal{A}}_{X}^{\text{enh}}$ denotes the corresponding involutive autoequivalence, then (1) and (2) above hold with ${\mathcal{A}}_{X}$ , $\text{S}_{{\mathcal{A}}_{X}}$ , $\unicode[STIX]{x1D70E}$ , and  ${\mathcal{A}}_{X^{\text{op}}}$ replaced by their enhanced versions, and (1) and (2) are recovered by passing to homotopy categories. The Hochschild (co)homology of ${\mathcal{A}}_{X}$ and ${\mathcal{A}}_{X^{\text{op}}}$ agree with the corresponding invariants of their enhancements. Hence [Reference PerryPer18, Corollary 1.3] gives

(2.15) $$\begin{eqnarray}\operatorname{HH}^{\bullet }({\mathcal{A}}_{X^{\text{op}}})\cong \operatorname{HH}^{\bullet }({\mathcal{A}}_{X})\oplus (\operatorname{HH}_{\bullet }({\mathcal{A}}_{X})^{\mathbf{Z}/2}[-2]),\end{eqnarray}$$

where the $\mathbf{Z}/2$ -action on $\operatorname{HH}_{\bullet }({\mathcal{A}}_{X})$ is induced by $\unicode[STIX]{x1D70E}$ .

Since $X$ has odd dimension (and hence $X^{\text{op}}$ has even dimension), by Corollary 2.11 we have

$$\begin{eqnarray}\operatorname{HH}^{\bullet }({\mathcal{A}}_{X^{\text{op}}})\cong \mathbf{k}\oplus \mathbf{k}^{22}[-2]\oplus \mathbf{k}[-4],\end{eqnarray}$$

and by Proposition 2.9 we have

$$\begin{eqnarray}\operatorname{HH}_{\bullet }({\mathcal{A}}_{X})\cong \mathbf{k}^{10}[1]\oplus \mathbf{k}^{2}\oplus \mathbf{k}^{10}[-1].\end{eqnarray}$$

Combined with (2.15), this immediately shows $\operatorname{HH}_{\bullet }({\mathcal{A}}_{X})^{\mathbf{Z}/2}$ is concentrated in degree $0$ , i.e. we have $\operatorname{HH}_{\bullet }({\mathcal{A}}_{X})^{\mathbf{Z}/2}\cong \mathbf{k}^{d}$ for some $0\leqslant d\leqslant 2$ , and

$$\begin{eqnarray}\operatorname{HH}^{\bullet }({\mathcal{A}}_{X})\cong \mathbf{k}\oplus \mathbf{k}^{22-d}[-2]\oplus \mathbf{k}[-4].\end{eqnarray}$$

To prove $d=2$ , we apply [Reference PolishchukPol14, Corollary 3.11], which gives an equality

(2.16) $$\begin{eqnarray}\mathop{\sum }_{i}(-1)^{i}\dim \operatorname{HH}^{i}({\mathcal{A}}_{X})=\mathop{\sum }_{i}(-1)^{i}\,\text{Tr}((\text{S}_{{\mathcal{A}}_{X}}^{-1})_{\ast }:\operatorname{HH}_{i}({\mathcal{A}}_{X})\rightarrow \operatorname{HH}_{i}({\mathcal{A}}_{X})).\end{eqnarray}$$

Note that since $\text{S}_{{\mathcal{A}}_{X}}=\unicode[STIX]{x1D70E}\circ [2]$ , the map $(\text{S}_{{\mathcal{A}}_{X}}^{-1})_{\ast }:\operatorname{HH}_{i}({\mathcal{A}}_{X})\rightarrow \operatorname{HH}_{i}({\mathcal{A}}_{X})$ induced by $\text{S}_{{\mathcal{A}}_{X}}^{-1}$ on Hochschild homology coincides with the map induced by $\unicode[STIX]{x1D70E}$ , and in particular squares to the identity. It follows that the right side of (2.16) is bounded above by $\sum _{i}\dim \operatorname{HH}_{i}({\mathcal{A}}_{X})=22$ . But the left side of (2.16) equals $24-d$ where $0\leqslant d\leqslant 2$ , so $d=2$ .◻

Remark 2.13. As a byproduct, the above proof shows that $\text{S}_{{\mathcal{A}}_{X}}$ acts on $\operatorname{HH}_{i}({\mathcal{A}}_{X})$ by $(-1)^{i}$ for any GM category ${\mathcal{A}}_{X}$ .

Remark 2.14. It is possible to show $d=2$ in the above proof without appealing to the equality (2.16), as follows. Note that the statement is deformation invariant, since it is equivalent to the Euler characteristic $\sum _{i}(-1)^{i}\dim \operatorname{HH}^{i}({\mathcal{A}}_{X})$ being $22$ . So we may assume $X$ is special. Then the $\mathbf{Z}/2$ -action on ${\mathcal{A}}_{X}$ is induced by the involution of the double cover $X\rightarrow M_{X}^{\prime }$ . We want to show that $\mathbf{Z}/2$ acts trivially on $\operatorname{HH}_{0}({\mathcal{A}}_{X})$ . But $\operatorname{HH}_{\bullet }({\mathcal{A}}_{X})$ is canonically a summand of $\operatorname{HH}_{\bullet }(X)$ , and we claim that the involution of the double cover acts trivially on  $\operatorname{HH}_{0}(X)$ . Indeed, since $X$ is odd-dimensional, pullback under $X\rightarrow M_{X}^{\prime }$ induces a surjection on even-degree cohomology and hence on $\operatorname{HH}_{0}$ . The claim follows.

Remark 2.15. Proposition 2.12 can also be deduced from Conjecture 3.7 stated below. Indeed, the conjecture implies that the GM category of any GM variety of odd dimension is equivalent to that of an ordinary GM threefold, whose Hochschild cohomology can be computed using [Reference KuznetsovKuz09b, Theorem 8.8]. Yet another method for computing the Hochschild cohomology of GM categories is via the normal Hochschild cohomology spectral sequence of [Reference KuznetsovKuz15a], but this method becomes long and complicated for GM varieties of dimension bigger than $3$ .

As an application, we discuss the indecomposability of GM categories. Recall that a triangulated category ${\mathcal{T}}$ is called indecomposable if it admits no non-trivial semiorthogonal decompositions, i.e. if ${\mathcal{T}}=\langle {\mathcal{A}}_{1},{\mathcal{A}}_{2}\rangle$ implies either ${\mathcal{A}}_{1}\simeq 0$ or ${\mathcal{A}}_{2}\simeq 0$ . In general, there are very few techniques for proving indecomposability of a triangulated category. However, for Calabi–Yau categories, we recall a simple criterion below.

If ${\mathcal{A}}$ is an admissible subcategory of the derived category of a smooth projective variety, we say ${\mathcal{A}}$ is connected if $\operatorname{HH}^{0}({\mathcal{A}})=\mathbf{k}$ (see [Reference KuznetsovKuz16a, § 5.2]). By Corollary 2.11 and Proposition 2.12, all GM categories are connected.

Proposition 2.16 [Reference KuznetsovKuz16a, Proposition 5.5].

Let ${\mathcal{A}}$ be a connected admissible subcategory of the derived category of a smooth projective variety. Then ${\mathcal{A}}$ admits no non-trivial completely orthogonal decompositions. If furthermore ${\mathcal{A}}$ is Calabi–Yau, then ${\mathcal{A}}$ is indecomposable.

Corollary 2.17. Let $X$ be a GM variety of dimension $n$ .

  1. (1) If $n$ is even, then ${\mathcal{A}}_{X}$ is indecomposable.

  2. (2) If $n$ is odd, then ${\mathcal{A}}_{X}$ admits no non-trivial completely orthogonal decompositions.

Proof. This follows from Proposition 2.16, the connectivity of ${\mathcal{A}}_{X}$ , and the fact that ${\mathcal{A}}_{X}$ is Calabi–Yau if $n$ is even.◻

Remark 2.18. It is plausible that ${\mathcal{A}}_{X}$ is indecomposable if $X$ is an odd-dimensional GM variety, but we do not know how to prove this.

2.6 Grothendieck groups of GM categories

The Grothendieck group $\text{K}_{0}({\mathcal{T}})$ of a triangulated category ${\mathcal{T}}$ is the free group on isomorphism classes $[{\mathcal{F}}]$ of objects ${\mathcal{F}}\in {\mathcal{T}}$ , modulo the relations $[{\mathcal{G}}]=[{\mathcal{F}}]+[{\mathcal{H}}]$ for every distinguished triangle ${\mathcal{F}}\rightarrow {\mathcal{G}}\rightarrow {\mathcal{H}}$ .

Assume ${\mathcal{T}}$ is proper, i.e. that $\bigoplus _{i}\operatorname{Hom}({\mathcal{F}},{\mathcal{G}}[i])$ is finite dimensional for all ${\mathcal{F}},{\mathcal{G}}\in {\mathcal{T}}$ . For instance, this holds if ${\mathcal{T}}$ is admissible in the derived category of a smooth projective variety. Then for ${\mathcal{F}},{\mathcal{G}}\in {\mathcal{T}}$ , we set

$$\begin{eqnarray}\unicode[STIX]{x1D712}({\mathcal{F}},{\mathcal{G}})=\mathop{\sum }_{i}(-1)^{i}\dim \operatorname{Hom}({\mathcal{F}},{\mathcal{G}}[i]).\end{eqnarray}$$

This descends to a bilinear form $\unicode[STIX]{x1D712}:\text{K}_{0}({\mathcal{T}})\times \text{K}_{0}({\mathcal{T}})\rightarrow \mathbf{Z}$ , called the Euler form. In general this form is neither symmetric nor antisymmetric. However, if ${\mathcal{T}}$ admits a Serre functor (e.g. if ${\mathcal{T}}$ is admissible in the derived category of a smooth projective variety), then the left and right kernels of the form $\unicode[STIX]{x1D712}$ agree, and we denote this common subgroup of $\text{K}_{0}({\mathcal{T}})$ by $\ker (\unicode[STIX]{x1D712})$ . In this situation, the numerical Grothendieck group is the quotient

$$\begin{eqnarray}\text{K}_{0}({\mathcal{T}})_{\text{num}}=\text{K}_{0}({\mathcal{T}})/\text{ker}\,(\unicode[STIX]{x1D712}).\end{eqnarray}$$

Note that $\text{K}_{0}({\mathcal{T}})_{\text{num}}$ is torsion free, since $\ker (\unicode[STIX]{x1D712})$ is evidently saturated.

If $X$ is a smooth projective variety, we write

$$\begin{eqnarray}\text{K}_{0}(X)=\text{K}_{0}(\text{D}^{\text{b}}(X))\quad \text{and}\quad \text{K}_{0}(X)_{\text{num}}=\text{K}_{0}(\text{D}^{\text{b}}(X))_{\text{num}}.\end{eqnarray}$$

Further, let $\text{CH}(X)$ and $\text{CH}(X)_{\text{num}}$ denote the Chow rings of cycles modulo rational and numerical equivalence. The following well-known consequence of Hirzebruch–Riemann–Roch relates the (numerical) Grothendieck ring of $X$ to its (numerical) Chow ring.

Lemma 2.19. Let $X$ be a smooth projective variety. Then there are isomorphisms

$$\begin{eqnarray}\text{K}_{0}(X)\otimes \mathbf{Q}\cong \text{CH}(X)\otimes \mathbf{Q}\quad \text{and}\quad \text{K}_{0}(X)_{\text{num}}\otimes \mathbf{Q}\cong \text{CH}(X)_{\text{num}}\otimes \mathbf{Q}.\end{eqnarray}$$

Proof. The isomorphisms are induced by the Chern character $\text{ch}:\text{K}_{0}(X)\rightarrow \text{CH}(X)\otimes \mathbf{Q}$ . For the first, see [Reference FultonFul98, Example 15.2.16(b)]. The second then follows from the observation that, by Riemann–Roch, the kernel of the Euler form is precisely the preimage under the Chern character of the ideal of numerically trivial cycles.◻

The following well-known lemma says that Grothendieck groups are additive.

Lemma 2.20. Let $X$ be a smooth projective variety. Given a semiorthogonal decomposition $\text{D}^{\text{b}}(X)=\langle {\mathcal{A}}_{1},{\mathcal{A}}_{2},\ldots ,{\mathcal{A}}_{m}\rangle$ , there are isomorphisms

$$\begin{eqnarray}\text{K}_{0}(X)\cong \bigoplus _{i=1}^{m}\text{K}_{0}({\mathcal{A}}_{i})\quad \text{and}\quad \text{K}_{0}(X)_{\text{num}}\cong \bigoplus _{i=1}^{m}\text{K}_{0}({\mathcal{A}}_{i})_{\text{num}}.\end{eqnarray}$$

Proof. The embedding functors ${\mathcal{A}}_{i}{\hookrightarrow}\text{D}^{\text{b}}(X)$ induce a map $\bigoplus _{i}\text{K}_{0}({\mathcal{A}}_{i})\rightarrow \text{K}_{0}(X)$ , whose inverse is the map induced by the projection functors $\text{D}^{\text{b}}(X)\rightarrow {\mathcal{A}}_{i}$ . This isomorphism also descends to numerical Grothendieck groups.◻

Now let $X$ be a GM variety. If $X$ is a surface then ${\mathcal{A}}_{X}=\text{D}^{\text{b}}(X)$ , so the Grothendieck group of ${\mathcal{A}}_{X}$ coincides with that of $X$ . Below we describe $\text{K}_{0}({\mathcal{A}}_{X})_{\text{num}}$ if $X$ is odd dimensional, or if  $X$ is a fourfold or sixfold which is not ‘Hodge-theoretically special’ in the following sense.

First, we note that if $n$ denotes the dimension of $X$ , then by Lefschetz theorems (see [Reference Debarre and KuznetsovDK17, Proposition 3.4(b)]) the Gushel map $f:X\rightarrow \mathbf{G}$ induces an injection

$$\begin{eqnarray}\text{H}^{n}(\mathbf{G},\mathbf{Q}){\hookrightarrow}\text{H}^{n}(X,\mathbf{Q}).\end{eqnarray}$$

If $n$ is odd, then $\text{H}^{n}(\mathbf{G},\mathbf{Q})$ simply vanishes. But if $n=4$ or $6$ , then $\text{H}^{n}(\mathbf{G},\mathbf{Q})=\mathbf{Q}^{2}$ is generated by Schubert cycles, and the vanishing cohomology $\text{H}_{\text{van}}^{n}(X,\mathbf{Q})$ is defined as the orthogonal to  $\text{H}^{n}(\mathbf{G},\mathbf{Q})\subset \text{H}^{n}(X,\mathbf{Q})$ with respect to the intersection form.

Definition 2.21 [Reference Debarre, Iliev and ManivelDIM15].

Let $X$ be a GM variety of dimension $n=4$ or $6$ . Then $X$ is Hodge-special if

$$\begin{eqnarray}\text{H}^{n/2,n/2}(X)\cap \text{H}_{\text{van}}^{n}(X,\mathbf{Q})\neq 0.\end{eqnarray}$$

Lemma 2.22 [Reference Debarre, Iliev and ManivelDIM15].

If $X$ is a very general GM fourfold or sixfold, then $X$ is not Hodge-special.

Remark 2.23. Very general here means that the moduli point $[X]\in {\mathcal{M}}_{n}(\mathbf{k})$ lies in the complement of countably many proper closed substacks of ${\mathcal{M}}_{n}$ , where $n=\dim (X)$ and ${\mathcal{M}}_{n}$ is the moduli stack of $n$ -dimensional GM varieties discussed in Appendix A.

Proof. In the fourfold case, this is [Reference Debarre, Iliev and ManivelDIM15, Corollary 4.6]. The main point of the proof is the computation that the local period map for GM fourfolds is a submersion. The sixfold case can be proved by the same argument. ◻

Remark 2.24. Lemma 2.22 can also be proved by combining the description of the moduli of GM varieties in terms of Eisenbud–Popescu–Walter (EPW) sextics (see Remark 3.3) with [Reference Debarre and KuznetsovDK17, Theorem 5.1].

Proposition 2.25. Let $X$ be a GM variety of dimension $n\geqslant 3$ . If $n$ is even, assume also that  $X$ is not Hodge-special. Then $\text{K}_{0}({\mathcal{A}}_{X})_{\text{num}}\simeq \mathbf{Z}^{2}$ .

Proof. The proof is similar to that of Proposition 2.9. First, note that by Proposition 2.3 there is a semiorthogonal decomposition of $\text{D}^{\text{b}}(X)$ with ${\mathcal{A}}_{X}$ and $2(n-2)$ exceptional objects as components. Since the category generated by an exceptional object is equivalent to the derived category of a point, both its usual and numerical Grothendieck group is $\mathbf{Z}$ . Hence by additivity,

$$\begin{eqnarray}\text{K}_{0}(X)_{\text{num}}\cong \text{K}_{0}({\mathcal{A}}_{X})_{\text{num}}\oplus \mathbf{Z}^{2(n-2)}.\end{eqnarray}$$

On the other hand, $\text{K}_{0}(X)_{\text{num}}\otimes \mathbf{Q}\cong \text{CH}(X)_{\text{num}}\otimes \mathbf{Q}$ . But under our assumptions on $X$ , the rational Hodge classes on $X$ are spanned by the restrictions of Schubert cycles on $\mathbf{G}$ . In particular, the Hodge conjecture holds for $X$ . So numerical equivalence coincides with homological equivalence, and

$$\begin{eqnarray}\textstyle \text{CH}(X)_{\text{num}}\otimes \mathbf{Q}\cong \bigoplus _{k}\text{H}^{k,k}(X,\mathbf{Q}),\end{eqnarray}$$

where $\text{H}^{k,k}(X,\mathbf{Q})=\text{H}^{k,k}(X)\,\cap \,\text{H}^{2k}(X,\mathbf{Q})$ . Thus using the Hodge diamond of $X$ (recorded in the proof of Proposition 2.9) and the assumption that $X$ is not Hodge-special if $n$ is even, we find

$$\begin{eqnarray}\dim (\text{K}_{0}(X)_{\text{num}}\otimes \mathbf{Q})=2n-2.\end{eqnarray}$$

Combined with the above, this shows the rank of $\text{K}_{0}({\mathcal{A}}_{X})_{\text{num}}$ is $2$ . Since $\text{K}_{0}({\mathcal{A}}_{X})_{\text{num}}$ is torsion free, we conclude $\text{K}_{0}({\mathcal{A}}_{X})_{\text{num}}\cong \mathbf{Z}^{2}$ .◻

Remark 2.26. Let $X$ be a GM variety of dimension $n=4$ or $6$ . The proof of the proposition shows that

$$\begin{eqnarray}\text{rank}(\text{K}_{0}({\mathcal{A}}_{X})_{\text{num}})=\dim _{\mathbf{Q}}\text{H}^{n/2,n/2}(X,\mathbf{Q})\end{eqnarray}$$

if the Hodge conjecture holds for $X$ . The Hodge conjecture holds for any uniruled smooth projective fourfold [Reference Conte and MurreCM78], so for $n=4$ the above equality is unconditional. If $n=6$ the Hodge conjecture can be proved using the correspondences studied in [Reference Debarre and KuznetsovDK17], but we do not discuss the details here.

Lemma 2.27. Let $X$ be a GM variety as in Proposition 2.25. Then in a suitable basis, the Euler form on $\text{K}_{0}({\mathcal{A}}_{X})_{\text{num}}=\mathbf{Z}^{2}$ is given by

$$\begin{eqnarray}\left(\begin{array}{@{}cc@{}}-1 & 0\\ 0 & -1\end{array}\right)\quad \text{if }n=3,\quad \left(\begin{array}{@{}cc@{}}-2 & 0\\ 0 & -2\end{array}\right)\quad \text{if }n=4.\end{eqnarray}$$

Remark 2.28. The duality conjecture (Conjecture 3.7) implies that if $X$ is as in Proposition 2.25, then for $n=5$ or $6$ the lattice $\text{K}_{0}({\mathcal{A}}_{X})_{\text{num}}=\mathbf{Z}^{2}$ is isomorphic to the lattice described in Lemma 2.27 for $n=3$ or $4$ , respectively.

Proof. For $n=3$ , this is shown in the proof of [Reference KuznetsovKuz09a, Proposition 3.9].

For $n=4$ , we sketch the proof. First, note that any GM variety contains a line, since by taking a hyperplane section we reduce to the case of dimension $3$ , where the result is well known. Let $P\in X$ be a point, $L\subset X$ be a line, $\unicode[STIX]{x1D6F4}$ be the zero locus of a regular section of  ${\mathcal{U}}_{X}^{\vee }$ , $S$ be a complete intersection of two hyperplanes in $X$ , and $H$ be a hyperplane section of $X$ . The key claim is that

(2.17) $$\begin{eqnarray}\text{K}_{0}(X)_{\text{num}}=\mathbf{Z}\langle [{\mathcal{O}}_{P}],[{\mathcal{O}}_{L}],[{\mathcal{O}}_{\unicode[STIX]{x1D6F4}}],[{\mathcal{O}}_{S}],[{\mathcal{O}}_{H}],[{\mathcal{O}}_{X}]\rangle ,\end{eqnarray}$$

i.e. the structure sheaves of these subvarieties give an integral basis of $\text{K}_{0}(X)_{\text{num}}$ . Once this is known, as in the proof of [Reference KuznetsovKuz09a, Proposition 3.9], the lemma reduces to a (tedious) computation, which we omit.

Using [Reference KuznetsovKuz09a, Remark 5.9] it is easy to see $X$ is AK-compatible in the sense of [Reference KuznetsovKuz09a, Definition 5.1], hence to prove the claim it is enough to show that

$$\begin{eqnarray}\text{CH}(X)_{\text{num}}=\mathbf{Z}\langle [P],[L],[\unicode[STIX]{x1D6F4}],[S],[H],1\rangle .\end{eqnarray}$$

Clearly, this is equivalent to $\text{CH}^{2}(X)_{\text{num}}=\mathbf{Z}\langle [\unicode[STIX]{x1D6F4}],[S]\rangle$ . But $\text{CH}^{2}(X)_{\text{num}}$ coincides with the group $\text{CH}^{2}(X)_{\hom }\subset \text{H}^{4}(X,\mathbf{Z})$ of $2$ -cycles modulo homological equivalence (see the proof of Proposition 2.25), and $\mathbf{Z}\langle [\unicode[STIX]{x1D6F4}],[S]\rangle$ is the image of the inclusion $\text{H}^{4}(\mathbf{G},\mathbf{Z}){\hookrightarrow}\text{CH}^{2}(X)_{\hom }$ . Hence it suffices to show the cokernel of this inclusion is torsion free. Even better, the cokernel of

$$\begin{eqnarray}\text{H}^{4}(\mathbf{G},\mathbf{Z}){\hookrightarrow}\text{H}^{4}(X,\mathbf{Z})\end{eqnarray}$$

is torsion free. Indeed, we may assume $X$ is ordinary, and then the statement holds by the proof of the Lefschetz hyperplane theorem, see [Reference LazarsfeldLaz04, Example 3.1.18].◻

2.7 Geometricity of GM categories

Now we consider the question of whether ${\mathcal{A}}_{X}$ is equivalent to the derived category of a variety. The following two results show that in almost all cases, the answer is negative. In § 3.3 we will discuss a related conjecture about the rationality of GM fourfolds.

Proposition 2.29. Let $X$ be a GM variety of dimension $n$ .

  1. (1) If $n$ is even and $S$ is a variety such that ${\mathcal{A}}_{X}\simeq \text{D}^{\text{b}}(S)$ , then $S$ is a K $3$ surface.

  2. (2) If $n$ is odd, then ${\mathcal{A}}_{X}$ is not equivalent to the derived category of any variety.

  3. (3) If $n=4$ or $n=6$ and $X$ is not Hodge-special (in particular, if $X$ is very general), then ${\mathcal{A}}_{X}$ is not equivalent to the derived category of any variety.

Proof. Suppose $S$ is a variety such that ${\mathcal{A}}_{X}\simeq \text{D}^{\text{b}}(S)$ . Then $S$ is smooth by [Reference KuznetsovKuz06, Lemma D.22], and proper by [Reference OrlovOrl16, Proposition 3.30]. In particular, $\text{D}^{\text{b}}(S)$ has a Serre functor given by

$$\begin{eqnarray}\text{S}_{\text{D}^{\text{b}}(S)}({\mathcal{F}})={\mathcal{F}}\otimes \unicode[STIX]{x1D714}_{S}[\dim (S)],\end{eqnarray}$$

which is unique up to isomorphism. Thus by Proposition 2.6, $S$ is a surface with trivial (if  $n$ is even) or $2$ -torsion (if $n$ is odd) canonical class. Hence $S$ is a K3, Enriques, abelian, or bielliptic surface. Using the HKR isomorphism and the Hodge diamonds of such surfaces, we find

$$\begin{eqnarray}\operatorname{HH}_{\bullet }(S)=\left\{\begin{array}{@{}cccccccccl@{}} & & \mathbf{k}[2] & \oplus & \mathbf{k}^{22} & \oplus & \mathbf{k}[-2] & & & \quad \text{if }S\text{ is K3},\\ & & & & \mathbf{k}^{12} & & & & & \quad \text{if }S\text{ is Enriques},\\ \mathbf{k}[2] & \oplus & \mathbf{k}^{4}[1] & \oplus & \mathbf{k}^{6} & \oplus & \mathbf{k}^{4}[-1] & \oplus & \mathbf{k}[-2] & \quad \text{if }S\text{ is abelian},\\ & & \mathbf{k}^{2}[1] & \oplus & \mathbf{k}^{4} & \oplus & \mathbf{k}^{2}[-1] & & & \quad \text{if }S\text{ is bielliptic}.\end{array}\right.\end{eqnarray}$$

Now parts (1) and (2) follow by comparing with $\operatorname{HH}_{\bullet }({\mathcal{A}}_{X})$ as given by Proposition 2.9. For (3) note that if ${\mathcal{A}}_{X}\simeq \text{D}^{\text{b}}(S)$ , then $\text{K}_{0}({\mathcal{A}}_{X})_{\text{num}}\cong \text{K}_{0}(S)_{\text{num}}$ . But on a projective surface powers of the hyperplane class give $3$ independent elements in  $\text{CH}(S)_{\text{num}}\otimes \mathbf{Q}\cong \text{K}_{0}(S)_{\text{num}}\otimes \mathbf{Q}$ . Hence by Proposition 2.25, $X$ is Hodge-special.◻

2.8 Self-duality of GM categories

The derived category of a smooth proper variety  $X$ is self-dual: if $\text{D}^{\text{b}}(X)^{\text{op}}$ denotes the opposite category of $\text{D}^{\text{b}}(X)$ (note that this has nothing to do with the opposite GM variety), there is an equivalence $\text{D}^{\text{b}}(X)\simeq \text{D}^{\text{b}}(X)^{\text{op}}$ given by the dualization functor ${\mathcal{F}}\mapsto \text{R}{\mathcal{H}}\mathit{om}({\mathcal{F}},{\mathcal{O}}_{X})$ . In general, this self-duality property is not inherited by semiorthogonal components of  $\text{D}^{\text{b}}(X)$ . Nonetheless, we show below that all GM categories are self-dual, which can be thought of as a weak geometricity property.

For the proof, we recall some facts about mutation functors (see [Reference BondalBon89, Reference Bondal and KapranovBK90] for more details). For any admissible subcategory ${\mathcal{A}}\subset {\mathcal{T}}$ of a triangulated category, there are associated left and right mutation functors $\text{L}_{{\mathcal{A}}}:{\mathcal{T}}\rightarrow {\mathcal{T}}$ and $\text{R}_{{\mathcal{A}}}:{\mathcal{T}}\rightarrow {\mathcal{T}}$ . These functors annihilate  ${\mathcal{A}}$ , and their restrictions $\text{L}_{{\mathcal{A}}}|_{^{\bot }{\mathcal{A}}}:^{\bot }{\mathcal{A}}\rightarrow {\mathcal{A}}^{\bot }$ and $\text{R}_{{\mathcal{A}}}|_{{\mathcal{A}}^{\bot }}:{\mathcal{A}}^{\bot }\rightarrow ^{\bot }{\mathcal{A}}$ are mutually inverse equivalences [Reference Bondal and KapranovBK90, Lemma 1.9]. If ${\mathcal{T}}=\langle {\mathcal{A}}_{1},\ldots ,{\mathcal{A}}_{n}\rangle$ is a semiorthogonal decomposition with admissible components, then for $1\leqslant i\leqslant n-1$ there are semiorthogonal decompositions

$$\begin{eqnarray}\displaystyle {\mathcal{T}} & = & \displaystyle \langle {\mathcal{A}}_{1},\ldots ,{\mathcal{A}}_{i-1},\text{L}_{{\mathcal{A}}_{i}}({\mathcal{A}}_{i+1}),{\mathcal{A}}_{i},{\mathcal{A}}_{i+2},\ldots ,{\mathcal{A}}_{n}\rangle ,\nonumber\\ \displaystyle {\mathcal{T}} & = & \displaystyle \langle {\mathcal{A}}_{1},\ldots ,{\mathcal{A}}_{i-1},{\mathcal{A}}_{i+1},\text{R}_{{\mathcal{A}}_{i+1}}({\mathcal{A}}_{i}),{\mathcal{A}}_{i+2},\ldots ,{\mathcal{A}}_{n}\rangle ,\nonumber\end{eqnarray}$$

and equivalences

(2.18) $$\begin{eqnarray}\text{L}_{{\mathcal{A}}_{i}}({\mathcal{A}}_{i+1})\simeq {\mathcal{A}}_{i+1}\quad \text{and}\quad \text{R}_{{\mathcal{A}}_{i+1}}({\mathcal{A}}_{i})\simeq {\mathcal{A}}_{i}\end{eqnarray}$$

induced by the mutation functors $\text{L}_{{\mathcal{A}}_{i}}:{\mathcal{T}}\rightarrow {\mathcal{T}}$ and $\text{R}_{{\mathcal{A}}_{i+1}}:{\mathcal{T}}\rightarrow {\mathcal{T}}$ . When ${\mathcal{T}}$ admits a Serre functor $\text{S}_{{\mathcal{T}}}$ , the effect of mutating ${\mathcal{A}}_{n}$ or ${\mathcal{A}}_{1}$ to the opposite side of the semiorthogonal decomposition of  ${\mathcal{T}}$ can be described as follows [Reference Bondal and KapranovBK90, Proposition 3.6]:

(2.19) $$\begin{eqnarray}{\mathcal{T}}=\langle \text{S}_{{\mathcal{T}}}({\mathcal{A}}_{n}),{\mathcal{A}}_{1},\ldots ,{\mathcal{A}}_{n-1}\rangle \quad \text{and}\quad {\mathcal{T}}=\langle {\mathcal{A}}_{2},\ldots ,{\mathcal{A}}_{n},\text{S}_{{\mathcal{T}}}^{-1}({\mathcal{A}}_{1})\rangle .\end{eqnarray}$$

That is, $\text{L}_{\langle {\mathcal{A}}_{1},\ldots ,{\mathcal{A}}_{n-1}\rangle }({\mathcal{A}}_{n})=\text{S}_{{\mathcal{T}}}({\mathcal{A}}_{n})$ and $\text{R}_{\langle {\mathcal{A}}_{2},\ldots ,{\mathcal{A}}_{n}\rangle }({\mathcal{A}}_{1})=\text{S}_{{\mathcal{T}}}^{-1}({\mathcal{A}}_{1})$ .

Lemma 2.30. For any GM variety $X$ the corresponding GM category ${\mathcal{A}}_{X}$ is self-dual, i.e.

$$\begin{eqnarray}{\mathcal{A}}_{X}\simeq {\mathcal{A}}_{X}^{\text{op}}.\end{eqnarray}$$

Proof. If $\dim (X)=2$ then ${\mathcal{A}}_{X}=\text{D}^{\text{b}}(X)$ , so the result holds by self-duality of $\text{D}^{\text{b}}(X)$ . Now assume $\dim (X)\geqslant 3$ . Applying the dualization functor ${\mathcal{F}}\mapsto \text{R}{\mathcal{H}}\mathit{om}({\mathcal{F}},{\mathcal{O}}_{X})$ to the semiorthogonal decomposition (2.11), we obtain a new semiorthogonal decomposition

(2.20) $$\begin{eqnarray}\text{D}^{\text{b}}(X)=\langle {\mathcal{U}}_{X}(-(n-3)),{\mathcal{O}}_{X}(-(n-3)),\ldots ,{\mathcal{U}}_{X},{\mathcal{O}}_{X},{\mathcal{A}}_{X}^{\prime }\rangle\end{eqnarray}$$

and an equivalence ${\mathcal{A}}_{X}^{\prime }\simeq {\mathcal{A}}_{X}^{\text{op}}$ . It remains to show

(2.21) $$\begin{eqnarray}{\mathcal{A}}_{X}^{\prime }\simeq {\mathcal{A}}_{X}.\end{eqnarray}$$

We mutate the subcategory $\langle {\mathcal{U}}_{X}(-(n-3)),{\mathcal{O}}_{X}(-(n-3)),\ldots ,{\mathcal{U}}_{X}\rangle$ to the far right side of (2.20). By (2.19), the formula (2.12) for the Serre functor of $\text{D}^{\text{b}}(X)$ , and the formula (2.2) for $-K_{X}$ , the result is

$$\begin{eqnarray}\text{D}^{\text{b}}(X)=\langle {\mathcal{O}}_{X},{\mathcal{A}}_{X}^{\prime },{\mathcal{U}}_{X}(1),{\mathcal{O}}_{X}(1),\ldots ,{\mathcal{U}}_{X}(n-2)\rangle .\end{eqnarray}$$

Using the isomorphism ${\mathcal{U}}_{X}(1)\cong {\mathcal{U}}_{X}^{\vee }$ and comparing this decomposition with (2.11), we deduce that ${\mathcal{A}}_{X}=\text{L}_{{\mathcal{O}}_{X}}({\mathcal{A}}_{X}^{\prime })$ . Hence ${\mathcal{A}}_{X}\simeq {\mathcal{A}}_{X}^{\prime }$ by (2.18).◻

Remark 2.31. A similar argument shows that the K3 category associated to a cubic fourfold (as defined by (3.1) below) is self-dual.

3 Conjectures on duality and rationality

In this section, we propose two conjectures related to the variation of GM categories ${\mathcal{A}}_{X}$ as  $X$ varies in moduli. We begin by briefly recalling a description of the moduli of GM varieties in terms of EPW sextics from [Reference Debarre and KuznetsovDK18a, § 3] (see Appendix A for some basic results about the moduli stack of GM varieties). Using this, we formulate a duality conjecture (Conjecture 3.7), which in particular implies that ${\mathcal{A}}_{X}$ is constant in families of GM varieties with the same associated EPW sextic. Next we discuss the rationality problem for GM varieties in terms of GM categories. This problem is most interesting for GM fourfolds, where by analogy with cubic fourfolds we conjecture that the GM category of a rational GM fourfold is equivalent to the derived category of a K3 surface (Conjecture 3.12).

3.1 EPW sextics and moduli of GM varieties

Let $V_{6}$ be a $6$ -dimensional vector space. Its exterior power $\wedge ^{3}V_{6}$ has a natural $\det (V_{6})$ -valued symplectic form, given by wedge product. For any Lagrangian subspace $\mathsf{A}\subset \wedge ^{3}V_{6}$ , we consider the following stratification of $\mathbf{P}(V_{6})$ :

$$\begin{eqnarray}\mathsf{Y}_{\mathsf{A}}^{{\geqslant}k}=\{v\in \mathbf{P}(V_{6})\mid \dim (\mathsf{A}\cap (v\wedge (\wedge ^{2}V_{6})))\geqslant k\}\subset \mathbf{P}(V_{6}).\end{eqnarray}$$

We write $\mathsf{Y}_{\mathsf{A}}^{k}$ for the complement of $\mathsf{Y}_{\mathsf{A}}^{{\geqslant}k+1}$ in $\mathsf{Y}_{\mathsf{A}}^{{\geqslant}k}$ , and $\mathsf{Y}_{\mathsf{A}}$ for $\mathsf{Y}_{\mathsf{A}}^{{\geqslant}1}$ . The variety $\mathsf{Y}_{\mathsf{A}}$ is called an EPW sextic (for Eisenbud, Popescu, and Walter, who first defined it), and the sequence  $\mathsf{Y}_{\mathsf{A}}^{k}$ is called the EPW stratification.

We say $\mathsf{A}$ has no decomposable vectors if $\mathbf{P}(\mathsf{A})$ does not intersect $\operatorname{Gr}(3,V_{6})\subset \mathbf{P}(\wedge ^{3}V_{6})$ . O’Grady [Reference O’GradyO’Gr06, Reference O’GradyO’Gr08, Reference O’GradyO’Gr16, Reference O’GradyO’Gr12, Reference O’GradyO’Gr13, Reference O’GradyO’Gr15] extensively investigated the geometry of EPW sextics, and proved in particular that (see also [Reference Debarre and KuznetsovDK18a, Theorem B.2]) if  $\mathsf{A}$ has no decomposable vectors, then:

  • $\mathsf{Y}_{\mathsf{A}}=\mathsf{Y}_{\mathsf{A}}^{{\geqslant}1}$ is a normal irreducible sextic hypersurface, smooth along $\mathsf{Y}_{\mathsf{A}}^{1}$ ;

  • $\mathsf{Y}_{\mathsf{A}}^{{\geqslant}2}=\operatorname{Sing}(\mathsf{Y}_{\mathsf{A}})$ is a normal irreducible surface of degree 40, smooth along $\mathsf{Y}_{\mathsf{A}}^{2}$ ;

  • $\mathsf{Y}_{\mathsf{A}}^{3}=\operatorname{Sing}(\mathsf{Y}_{\mathsf{A}}^{{\geqslant}2})$ is finite and reduced, and for general $\mathsf{A}$ is empty;

  • $\mathsf{Y}_{\mathsf{A}}^{{\geqslant}4}=\varnothing$ .

For any Lagrangian subspace $\mathsf{A}\subset \wedge ^{3}V_{6}$ , its orthogonal $\mathsf{A}^{\bot }=\ker (\wedge ^{3}V_{6}^{\vee }\rightarrow \mathsf{A}^{\vee })\subset \wedge ^{3}V_{6}^{\vee }$ is also Lagrangian, and $\mathsf{A}$ has no decomposable vectors if and only if the same is true for $\mathsf{A}^{\bot }$ . In particular, $\mathsf{A}^{\bot }$ gives rise to an EPW sequence of subvarieties of $\mathbf{P}(V_{6}^{\vee })$ , which can be written in terms of $\mathsf{A}$ as follows:

$$\begin{eqnarray}\mathsf{Y}_{\mathsf{A}^{\bot }}^{{\geqslant}k}=\{V_{5}\in \mathbf{P}(V_{6}^{\vee })\mid \dim (\mathsf{A}\cap \wedge ^{3}V_{5})\geqslant k\}\subset \mathbf{P}(V_{6}^{\vee }).\end{eqnarray}$$

This stratification has the same properties as the stratification $\mathsf{Y}_{\mathsf{A}}^{{\geqslant}k}$ . By O’Grady’s work $\mathsf{Y}_{\mathsf{A}^{\bot }}$ is projectively dual to $\mathsf{Y}_{\mathsf{A}}$ , and for this reason is called the dual EPW sextic to $\mathsf{Y}_{\mathsf{A}}$ . We note that  $\mathsf{Y}_{\mathsf{A}^{\bot }}$ is not isomorphic to $\mathsf{Y}_{\mathsf{A}}$ for general $\mathsf{A}$ (see [Reference O’GradyO’Gr08, Theorem 1.1]).

One of the main results of [Reference Debarre and KuznetsovDK18a] is the following description of the set of all isomorphism classes of smooth ordinary GM varieties. If $X\subset \mathbf{P}(W)$ is a GM variety, then the space of quadrics in $\mathbf{P}(W)$ containing $X$ is a $6$ -dimensional vector space [Reference Debarre and KuznetsovDK18a, Theorem 2.3], which we denote by $V_{6}(X)$ . The space of Plücker quadrics defining the Grassmannian $\mathbf{G}=\operatorname{Gr}(2,V_{5}(X))$ is canonically identified with $V_{5}(X)$ , so since $X\subset \operatorname{Cone}(\mathbf{G})$ we have an embedding

$$\begin{eqnarray}V_{5}(X)\subset V_{6}(X).\end{eqnarray}$$

The hyperplane $V_{5}(X)$ is called the Plücker hyperplane of $X$ and the corresponding point

$$\begin{eqnarray}\mathbf{p}_{X}\in \mathbf{P}(V_{6}(X)^{\vee })\end{eqnarray}$$

is called the Plücker point of $X$ . Furthermore, in [Reference Debarre and KuznetsovDK18a, Theorem 3.10] it is shown that there is a natural Lagrangian subspace

$$\begin{eqnarray}\mathsf{A}(X)\subset \wedge ^{3}V_{6}(X)\end{eqnarray}$$

associated to $X$ . If $X^{\text{op}}$ is the opposite variety of $X$ as defined by (2.7), then $\mathsf{A}(X^{\text{op}})=\mathsf{A}(X)$ and $\mathbf{p}_{X^{\text{op}}}=\mathbf{p}_{X}$ .

Theorem 3.1 [Reference Debarre and KuznetsovDK18a, Theorem 3.10].

For any $n\geqslant 2$ the maps $X\rightarrow X^{\text{op}}$ and $X\mapsto (\mathsf{A}(X),\mathbf{p}_{X})$ define bijections between:

  1. (1) the set of ordinary GM varieties $X$ of dimension $n\geqslant 2$ whose Grassmannian hull $M_{X}$ is smooth, up to isomorphism;

  2. (2) the set of special GM varieties of dimension $n+1\geqslant 3$ , up to isomorphism; and

  3. (3) the set of pairs $(\mathsf{A},\mathbf{p})$ , where $\mathsf{A}\subset \wedge ^{3}V_{6}$ is a Lagrangian subspace with no decomposable vectors and $\mathbf{p}\in \mathsf{Y}_{\mathsf{A}^{\bot }}^{5-n}$ , up to the action of $\operatorname{PGL}(V_{6})$ .

Note that by Lemma 2.1, the Grassmannian hull $M_{X}$ is automatically smooth for ordinary GM varieties of dimension $n\geqslant 3$ .

Remark 3.2. To include all GM surfaces into the above bijection, we must allow a more general class of Lagrangian subspaces in Theorem 3.1, namely those that contain finitely many decomposable vectors, cf. [Reference Debarre and KuznetsovDK18a, Theorem 3.16 and Remark 3.17].

Remark 3.3. Theorem 3.1 suggests there is a morphism from the moduli stack ${\mathcal{M}}_{n}$ of $n$ -dimensional GM varieties (see Appendix A) to the quotient stack $\operatorname{LG}(\wedge ^{3}V_{6})/\operatorname{PGL}(V_{6})$ (where $\operatorname{LG}(\wedge ^{3}V_{6})$ is the Lagrangian Grassmannian) given by $X\mapsto \mathsf{A}(X)$ at the level of points, whose fiber over a point $\mathsf{A}$ is the union of two EPW strata $\mathsf{Y}_{\mathsf{A}^{\bot }}^{5-n}\sqcup \mathsf{Y}_{\mathsf{A}^{\bot }}^{6-n}$ , modulo the action of the finite stabilizer group of $\mathsf{A}$ in $\operatorname{PGL}(V_{6})$ . This morphism will be discussed in detail in [Reference Debarre and KuznetsovDK18b]. Let us simply note that it gives a geometric way to compute $\dim {\mathcal{M}}_{n}$ (cf. Proposition A.2). Namely, the quotient stack $\operatorname{LG}(\wedge ^{3}V_{6})/\operatorname{PGL}(V_{6})$ has dimension $20$ , and the fibers of the supposed morphism have dimension $5$ , $5$ , $4$ , or $2$ for $n=6,5,4$ , or $3$ , respectively. Finally, for  $n=2$ the morphism is no longer dominant, as its image is the divisor of those $\mathsf{A}$ such that  $\mathsf{Y}_{\mathsf{A}^{\bot }}^{3}\neq \varnothing$ , and its fibers are finite.

The above discussion shows the utility of the EPW stratification of $\mathbf{P}(V_{6}^{\vee })$ from the point of view of moduli. The following proposition gives a geometric interpretation of the EPW stratification of $\mathbf{P}(V_{6})$ , which will be essential later.

As mentioned before, the quadric $Q$ defining $X$ in (2.1) is not unique; such quadrics are parameterized by the affine space $\mathbf{P}(V_{6}(X))\setminus \mathbf{P}(V_{5}(X))$ of non-Plücker quadrics. In other words, a quadric $Q$ defining $X$ in (2.1) corresponds to a quadric point

$$\begin{eqnarray}\mathbf{q}\in \mathbf{P}(V_{6}(X))\end{eqnarray}$$

such that $(\mathbf{q},\mathbf{p}_{X})$ does not lie on the incidence divisor in $\mathbf{P}(V_{6}(X))\times \mathbf{P}(V_{6}(X)^{\vee })$ .

Proposition 3.4 [Reference Debarre and KuznetsovDK18a, Proposition 3.13(b)].

Let $X$ be a GM variety. Under the identification of the affine space $\mathbf{P}(V_{6}(X))\setminus \mathbf{P}(V_{5}(X))$ with the space of non-Plücker quadrics containing  $X$ , the stratum

$$\begin{eqnarray}\mathsf{Y}_{\mathsf{A}(X)}^{k}\cap (\mathbf{P}(V_{6}(X))\setminus \mathbf{P}(V_{5}(X)))\end{eqnarray}$$

corresponds to the quadrics $Q$ such that $\dim (\ker (Q))=k$ .

The symmetry between the Plücker point $\mathbf{p}_{X}$ and the quadric point $\mathbf{q}$ is the basis for the duality of GM varieties, discussed below.

3.2 The duality conjecture

The following definition extends [Reference Debarre and KuznetsovDK18a, Definitions 3.22 and 3.26].

Definition 3.5. Let $X_{1}$ and $X_{2}$ be GM varieties.

  1. (1) If there exists an isomorphism $V_{6}(X_{1})\cong V_{6}(X_{2})$ identifying $\mathsf{A}(X_{1})\subset \wedge ^{3}V_{6}(X_{1})$ with  $\mathsf{A}(X_{2})\subset \wedge ^{3}V_{6}(X_{2})$ , then we say:

    • $X_{1}$ and $X_{2}$ are period partners if $\dim (X_{1})=\dim (X_{2})$ , and

    • $X_{1}$ and $X_{2}$ are generalized partners if $\dim (X_{1})\equiv \dim (X_{2})\hspace{0.6em}({\rm mod}\hspace{0.2em}2)$ .

  2. (2) If there exists an isomorphism $V_{6}(X_{1})\cong V_{6}(X_{2})^{\vee }$ identifying $\mathsf{A}(X_{1})\subset \wedge ^{3}V_{6}(X_{1})$ with  $\mathsf{A}(X_{2})^{\bot }\subset \wedge ^{3}V_{6}(X_{2})^{\vee }$ , then we say:

    • $X_{1}$ and $X_{2}$ are dual if $\dim (X_{1})=\dim (X_{2})$ , and

    • $X_{1}$ and $X_{2}$ are generalized dual if $\dim (X_{1})\equiv \dim (X_{2})\hspace{0.6em}({\rm mod}\hspace{0.2em}2)$ .

Remark 3.6. If $X$ is a GM variety, then either $\mathsf{A}(X)$ does or does not contain decomposable vectors, and these two cases are preserved by generalized partnership and duality. The first case happens only when $X$ is an ordinary surface with singular Grassmannian hull or $X$ is a special surface, see [Reference Debarre and KuznetsovDK18a, Theorem 3.16 and Remark 3.17]. In this paper, we focus on the case where  $\mathsf{A}(X)$ does not contain decomposable vectors.

One of the main results of [Reference Debarre and KuznetsovDK18a, § 4] is that period partners or dual GM varieties of dimension at least $3$ are birational. Our motivation for defining generalized partners and duals is the following conjecture.

Conjecture 3.7. Let $X_{1}$ and $X_{2}$ be GM varieties such that the subspaces $\mathsf{A}(X_{1})$ and $\mathsf{A}(X_{2})$ do not contain decomposable vectors, and let ${\mathcal{A}}_{X_{1}}$ and ${\mathcal{A}}_{X_{2}}$ be their GM categories.

  1. (1) If $X_{1}$ and $X_{2}$ are generalized partners, there is an equivalence ${\mathcal{A}}_{X_{1}}\simeq {\mathcal{A}}_{X_{2}}$ .

  2. (2) If $X_{1}$ and $X_{2}$ are generalized duals, there is an equivalence ${\mathcal{A}}_{X_{1}}\simeq {\mathcal{A}}_{X_{2}}$ .

By Proposition 2.6, GM varieties with equivalent GM categories must have dimensions of the same parity, which explains the parity condition in Definition 3.5. We note that part (1) of the conjecture follows from part (2), since by Definition 3.5 and Theorem 3.1 generalized period partners have a common generalized dual GM variety. For this reason, we refer to Conjecture 3.7 as the duality conjecture.

As evidence for the duality conjecture, we prove in § 4 the special case where $X_{1}$ is an ordinary GM fourfold and $X_{2}$ is a (suitably generic) generalized dual GM surface. In fact, the approach of § 4 can be used to attack the full conjecture, but is quite unwieldy to carry out in the general case. In forthcoming work, we establish the general case as a consequence of a theory of ‘categorical joins’ [Reference Kuznetsov and PerryKP18]. This approach is based on the observation from [Reference Debarre and KuznetsovDK18a, Proposition 3.28] that duality of ordinary GM varieties can be interpreted in terms of projective duality of quadrics (see also § 4.2). We show that this extends to generalized duality by replacing classical projective duality with homological projective duality.

In the rest of this subsection we discuss some consequences of the duality conjecture. We start by describing all generalized duals and partners of a given GM variety.

Lemma 3.8. Let $X$ be an $n$ -dimensional GM variety, and assume $\mathsf{A}(X)$ has no decomposable vectors. Then any quadric point $\mathbf{q}\in \mathbf{P}(V_{6}(X))$ corresponds to a generalized dual  $X_{\mathbf{q}}^{\vee }$ of $X$ . If  $\mathbf{q}$ lies in the stratum $\mathsf{Y}_{\mathsf{A}(X)}^{k}$ for some $k$ , we have:

  • if $5-k\equiv n\hspace{0.6em}({\rm mod}\hspace{0.2em}2)$ , then $X_{\mathbf{q}}^{\vee }$ is an ordinary GM variety of dimension $5-k$ ;

  • if $6-k\equiv n\hspace{0.6em}({\rm mod}\hspace{0.2em}2)$ , then $X_{\mathbf{q}}^{\vee }$ is a special GM variety of dimension $6-k$ .

Similarly, any point $\mathbf{p}\in \mathbf{P}(V_{6}(X)^{\vee })$ corresponds to a generalized partner $X_{\mathbf{p}}$ of $X$ .

Conversely, any generalized dual of  $X$ arises as  $X_{\mathbf{q}}^{\vee }$ for some $\mathbf{q}\in \mathbf{P}(V_{6}(X))$ and any generalized partner of  $X$ arises as  $X_{\mathbf{p}}$ for some $\mathbf{p}\in \mathbf{P}(V_{6}(X)^{\vee })$ .

Proof. The variety $X_{\mathbf{q}}^{\vee }$ corresponding to a quadric point $\mathbf{q}\in \mathbf{P}(V_{6})$ is just the ordinary GM variety of dimension $5-k$ or the special GM variety of dimension $6-k$ associated by Theorem 3.1 to the pair $(\mathsf{A}(X)^{\bot },\mathbf{q})$ (with $V_{6}=V_{6}(X)^{\vee }$ ). It also follows from Theorem 3.1 that any generalized dual of $X$ arises in this way.

The same argument also works for generalized partners. ◻

The argument of Lemma 3.8 shows that the set of isomorphism classes of generalized duals of  $X$ can be identified with the quotient of $\mathbf{P}(V_{6}(X))$ by the action of the finite stabilizer group of  $\mathsf{A}(X)$ in $\operatorname{PGL}(V_{6}(X))$ . Analogously, the isomorphism classes of generalized partners of $X$ are parameterized by a quotient of $\mathbf{P}(V_{6}(X)^{\vee })$ by the same group.

Let us list more explicitly the type of $X_{\mathbf{q}}^{\vee }$ according to the stratum $\mathsf{Y}_{\mathsf{A}(X)}^{k}$ of $\mathbf{q}$ and the parity of $n=\dim X$ :

Recall that the stratum $\mathsf{Y}_{\mathsf{A}(X)}^{k}$ is always non-empty for $k=0,1,2$ , generically empty for $k=3$ , and always empty for $k\geqslant 4$ (under our assumption that $\mathsf{A}(X)$ contains no decomposable vectors). In fact, the condition that $\mathsf{Y}_{\mathsf{A}(X)}^{3}$ is non-empty is divisorial in ${\mathcal{M}}_{n}$ (see Remark 4.3). In the same way, one can describe the types of generalized partners $X_{\mathbf{p}}$ of $X$ depending on the stratum $\mathsf{Y}_{\mathsf{A}(X)^{\bot }}^{k}$ of $\mathbf{p}$ and the parity of $n$ .

Conjecture 3.7 says there are equivalences

$$\begin{eqnarray}{\mathcal{A}}_{X}\simeq {\mathcal{A}}_{X_{\mathbf{p}}}\simeq {\mathcal{A}}_{X_{\mathbf{q}}^{\vee }}\end{eqnarray}$$

for every $\mathbf{p}\in \mathbf{P}(V_{6}(X)^{\vee })$ and every $\mathbf{q}\in \mathbf{P}(V_{6}(X))$ . In particular, it predicts that often GM categories are equivalent to those of lower-dimensional GM varieties, namely that:

  1. (1) if $X$ is a sixfold, then its GM category is equivalent to a fourfold’s GM category;

  2. (2) if $X$ is a fivefold, then its GM category is equivalent to a threefold’s GM category;

  3. (3) if $X$ is a fourfold such that $\mathsf{Y}_{\mathsf{A}(X)^{\bot }}^{3}\neq \varnothing$ or $\mathsf{Y}_{\mathsf{A}(X)}^{3}\neq \varnothing$ , then its GM category is equivalent to the derived category of a GM surface.

As mentioned above, in § 4 we prove (3) in case $\mathsf{Y}_{\mathsf{A}(X)}^{3}\neq \varnothing$ and an additional genericity assumption holds, namely $\mathsf{Y}_{\mathsf{A}(X)}^{3}\not \subset \mathbf{P}(V_{5}(X))$ .

Remark 3.9. Using Theorem 3.1, it is easy to see that to prove the duality conjecture in full generality, it is enough to prove ${\mathcal{A}}_{X}\simeq {\mathcal{A}}_{X_{\mathbf{q}}^{\vee }}$ for all $X$ and $\mathbf{q}\in \mathbf{P}(V_{6}(X))\setminus \mathbf{P}(V_{5}(X))$ . A similar reduction was used in [Reference Debarre and KuznetsovDK18a, § 4] to prove birationality of period partners and of dual GM varieties.

Remark 3.10. A GM variety $X$ as in (1)–(3) above is rational (see the discussion below and Lemma 4.7). It seems likely that for such an $X$ there is a rationality construction that involves a blowup of a generalized partner or dual variety of dimension $2$ less, and gives rise to an equivalence of GM categories. Our approach to (3) in § 4 takes a completely different route.

3.3 Rationality conjectures

Let us recall what is known about rationality of GM varieties. A general GM threefold is irrational by [Reference BeauvilleBea77, Theorem 5.6], while every GM fivefold or sixfold is rational by [Reference Debarre and KuznetsovDK18a, Proposition 4.2] (for a general GM fivefold or sixfold this was already known to Roth). The intermediate case of GM fourfolds is more mysterious, and closely parallels the situation for cubic fourfolds: some rational examples are known [Reference Debarre, Iliev and ManivelDIM15], but while a very general GM fourfold is expected to be irrational, it has not been proven that a single GM fourfold is irrational. Below, we analyze this state of affairs from the point of view of derived categories.

Following [Reference KuznetsovKuz16b, § 3.3], we use the following terminology.

  • For a triangulated category ${\mathcal{A}}$ , the geometric dimension $\text{gdim}({\mathcal{A}})$ is defined as the minimal integer $m$ such that there exists an $m$ -dimensional connected smooth projective variety $M$ and an admissible embedding ${\mathcal{A}}{\hookrightarrow}\text{D}^{\text{b}}(M)$ .

  • If $Y$ is a smooth projective variety and $\text{D}^{\text{b}}(Y)=\langle {\mathcal{A}}_{1},\ldots ,{\mathcal{A}}_{m}\rangle$ is a maximal semiorthogonal decomposition (i.e. the components are indecomposable), then ${\mathcal{A}}_{i}$ is called a Griffiths component if $\text{gdim}({\mathcal{A}}_{i})\geqslant \dim Y-1$ .

If the set of Griffiths components of $Y$ did not depend on the choice of maximal semiorthogonal decomposition, then it would be a birational invariant [Reference KuznetsovKuz16b, Lemma 3.10]; in particular, it would be empty if $Y$ is rational of dimension at least $2$ . Unfortunately, there are examples showing this is not true (see [Reference KuznetsovKuz16b, § 3.4], [Reference Böhning, Graf von Bothmer and SosnaBGS14]). It may be possible to salvage the situation by modifying the definition of a Griffiths component (some possibilities are discussed in [Reference KuznetsovKuz16b, § 3.4]), but this remains an important question.

Nonetheless, the existence of a Griffiths component appears to be related to irrationality in several examples. For instance, if $X^{\prime }\subset \mathbf{P}^{5}$ is a smooth cubic fourfold, there is a semiorthogonal decomposition

(3.1) $$\begin{eqnarray}\text{D}^{\text{b}}(X^{\prime })=\langle {\mathcal{A}}_{X^{\prime }},{\mathcal{O}}_{X^{\prime }},{\mathcal{O}}_{X^{\prime }}(1),{\mathcal{O}}_{X^{\prime }}(2)\rangle ,\end{eqnarray}$$

where ${\mathcal{A}}_{X^{\prime }}$ is a K3 category (see [Reference KuznetsovKuz04, Corollary 4.3] or [Reference KuznetsovKuz16a, Corollary 4.1]). If ${\mathcal{A}}_{X^{\prime }}$ is equivalent to the derived category of a K3 surface, then $\text{gdim}({\mathcal{A}}_{X^{\prime }})=2$ and hence (3.1) contains no Griffiths components. If ${\mathcal{A}}_{X^{\prime }}$ is not geometric (which holds for a very general cubic fourfold by an argument similar to Proposition 2.29), then we expect ${\mathcal{A}}_{X^{\prime }}$ to be a Griffiths component, although this remains an interesting open problem, cf. [Reference KuznetsovKuz16a, Conjecture 5.8]. These considerations motivated the following conjecture.

Conjecture 3.11 [Reference KuznetsovKuz10].

If $X^{\prime }$ is a rational cubic fourfold, then ${\mathcal{A}}_{X^{\prime }}$ is equivalent to the derived category of a K3 surface.

As evidence, this conjecture was proved in [Reference KuznetsovKuz10] for all rational $X^{\prime }$ known at the time. Since then, a nearly complete answer to when ${\mathcal{A}}_{X^{\prime }}$ is equivalent to the derived category of a K3 surface has been given [Reference Addington and ThomasAT14], and some new families of rational cubic fourfolds have been produced [Reference Addington, Hassett, Tschinkel and Várilly-AlvaradoAHTV16].

The same philosophy can be applied to GM fourfolds. If the GM category ${\mathcal{A}}_{X}$ of a GM fourfold $X$ is geometric, then (2.11) contains no Griffiths components, and otherwise we expect  ${\mathcal{A}}_{X}$ to be a Griffiths component. This suggests the following analogue of Conjecture 3.11.

Conjecture 3.12. If $X$ is a rational GM fourfold, then the GM category ${\mathcal{A}}_{X}$ is equivalent to the derived category of a $K3$ surface.

One of the main results of this paper, Theorem 1.2 (or rather Theorem 4.1), verifies Conjecture 3.12 for a certain family of rational GM fourfolds. Another result, Theorem 1.3 (or rather Theorem 5.8), builds a bridge between Conjectures 3.12 and 3.11. Finally, recall that we proved the GM category of a very general GM fourfold is not equivalent to the derived category of a K3 surface (Proposition 2.29). Hence Conjecture 3.12 is consistent with the expectation that a very general GM fourfold is irrational.

Now we consider GM varieties of other dimensions from the perspective of derived categories. The next result shows that for a GM threefold $X$ , any maximal semiorthogonal decomposition of $\text{D}^{\text{b}}(X)$ obtained by refining (2.11) contains a Griffiths component. We view this as evidence that any smooth GM threefold is irrational.

Lemma 3.13 (Cf. [Reference KuznetsovKuz16b, Proposition 3.12]).

Let $X$ be a GM threefold. Then ${\mathcal{A}}_{X}$ does not admit a semiorthogonal decomposition with all components of geometric dimension at most $1$ .

Proof. It is easy to see that any category of geometric dimension $0$ is equivalent to $\text{D}^{\text{b}}(\operatorname{Spec}(\mathbf{k}))$ . Further, by [Reference OkawaOka11] any category of geometric dimension $1$ is equivalent to the derived category of a curve. Note that $\operatorname{HH}_{\bullet }(\operatorname{Spec}(\mathbf{k}))=\mathbf{k}$ , and if $C$ is a curve of genus $g$ then

$$\begin{eqnarray}\operatorname{HH}_{\bullet }(C)=\mathbf{k}^{g}[1]\oplus \mathbf{k}^{2}\oplus \mathbf{k}^{g}[-1].\end{eqnarray}$$

Thus if ${\mathcal{A}}_{X}$ has a semiorthogonal decomposition with all components of geometric dimension at most $1$ , Proposition 2.9 and Theorem 2.8 imply ${\mathcal{A}}_{X}\simeq \text{D}^{\text{b}}(C)$ for a genus $10$ curve $C$ . This cannot happen by Proposition 2.29.◻

If $X$ is a GM fivefold or sixfold, then by the discussion in § 3.2, $X$ has a generalized dual  $X^{\vee }$ with $\dim (X^{\vee })\leqslant \dim (X)-2$ . The duality conjecture (Conjecture 3.7(2)) predicts that  ${\mathcal{A}}_{X}\simeq {\mathcal{A}}_{X^{\vee }}$ , and hence $\text{gdim}({\mathcal{A}}_{X})\leqslant \dim (X)-2$ . So assuming the duality conjecture, we see that (2.11) has no Griffiths components, which is consistent with the rationality of $X$ .

4 Fourfold-to-surface duality

In this section we prove Conjecture 3.7 for ordinary fourfolds with a generalized dual surface corresponding to a quadric point not lying on the Plücker hyperplane.

4.1 Statement of the result

Recall that for any GM fourfold  $X$ and a quadric point $\mathbf{q}\in \mathbf{P}(V_{6}(X))$ , we associated in § 3.2 a generalized dual variety  $X_{\mathbf{q}}^{\vee }$ , which is an ordinary GM surface if  $\mathbf{q}\in \mathsf{Y}_{\mathsf{A}(X)}^{3}$ .

Theorem 4.1. Let $X$ be an ordinary GM fourfold such that

$$\begin{eqnarray}\mathsf{Y}_{\mathsf{A}(X)}^{3}\cap (\mathbf{P}(V_{6}(X))\setminus \mathbf{P}(V_{5}(X)))\neq \varnothing .\end{eqnarray}$$

Then for any point $\mathbf{q}\in \mathsf{Y}_{\mathsf{A}(X)}^{3}\cap (\mathbf{P}(V_{6}(X))\setminus \mathbf{P}(V_{5}(X)))$ , there is an equivalence

$$\begin{eqnarray}{\mathcal{A}}_{X}\simeq \text{D}^{\text{b}}(X_{\mathbf{q}}^{\vee }).\end{eqnarray}$$

The proof of this theorem takes the rest of this section. We start by noting an immediate consequence for period partners.

Corollary 4.2. Assume $X$ and $\mathbf{q}$ are as in Theorem 4.1, and let $X_{\mathbf{p}}$ be a period partner of  $X$ such that $(\mathbf{q},\mathbf{p})$ does not lie on the incidence divisor in $\mathbf{P}(V_{6}(X))\times \mathbf{P}(V_{6}(X)^{\vee })$ . Then there is an equivalence of GM categories ${\mathcal{A}}_{X_{\mathbf{p}}}\simeq {\mathcal{A}}_{X}$ .

Proof. By Theorem 4.1 applied to $X$ and $X_{\mathbf{p}}$ we have a pair of equivalences ${\mathcal{A}}_{X}\simeq \text{D}^{\text{b}}(X_{\mathbf{q}}^{\vee })$ and ${\mathcal{A}}_{X_{\mathbf{p}}}\simeq \text{D}^{\text{b}}(X_{\mathbf{q}}^{\vee })$ . Combining them we obtain an equivalence ${\mathcal{A}}_{X_{\mathbf{p}}}\simeq {\mathcal{A}}_{X}$ .◻

A key ingredient in the proof of Theorem 4.1 is the theory of homological projective duality [Reference KuznetsovKuz07]. Very roughly, this theory relates the derived categories of linear sections of an ambient variety to those of orthogonal linear sections of a ‘dual’ variety. As we explain below, the varieties $X$ and $X_{\mathbf{q}}^{\vee }$ from Theorem 4.1 can be thought of as intersections of $\mathbf{G}\subset \mathbf{P}(\wedge ^{2}V_{5})$ and its dual $\mathbf{G}^{\vee }=\operatorname{Gr}(2,V_{5}^{\vee })\subset \mathbf{P}(\wedge ^{2}V_{5}^{\vee })$ with projectively dual quadric subvarieties. To prove Theorem 1.2, we thus establish a ‘quadratic’ version of homological projective duality, in the case where the ambient variety is $\mathbf{G}$ . Much of our argument is not special to $\mathbf{G}$ , however, and should have interesting applications in other settings.

Remark 4.3. GM fourfolds $X$ as in the theorem form a $23$ -dimensional (codimension $1$ in moduli) family. This can be seen using Theorem 3.1. Indeed, by [Reference O’GradyO’Gr13, Proposition 2.2] Lagrangian subspaces $\mathsf{A}\subset \wedge ^{3}V_{6}$ with no decomposable vectors such that $\mathsf{Y}_{\mathsf{A}}^{3}\neq \varnothing$ form a divisor in the moduli space of all $\mathsf{A}$ , and hence form a $19$ -dimensional family. Having fixed such an $\mathsf{A}$ there are finitely many $\mathbf{q}\in \mathsf{Y}_{\mathsf{A}}^{3}$ , and in order for $\mathbf{q}\in \mathbf{P}(V_{6}(X))\setminus \mathbf{P}(V_{5}(X))$ the Plücker point $\mathbf{p}$ of $X$ can be any point of $\mathsf{Y}_{\mathsf{A}^{\bot }}^{1}$ such that $(\mathbf{q},\mathbf{p})$ is not on the incidence divisor. In other words, $\mathbf{p}\in \mathsf{Y}_{\mathsf{A}^{\bot }}^{1}\setminus \mathbf{q}^{\bot }$ , so we have a 4-dimensional family of choices.

Recall from § 2.1 that if $X$ is an ordinary GM fourfold, there is a (canonical) hyperplane $W\subset \wedge ^{2}V_{5}(X)$ and a (non-canonical) quadric $Q\subset \mathbf{P}(W)$ such that $X=\mathbf{G}\cap Q$ . The fourfolds satisfying the assumption of Theorem 4.1 admit several different characterizations.

Lemma 4.4. Let $X$ be an ordinary GM fourfold. The following are equivalent:

  1. (1) $\mathsf{Y}_{\mathsf{A}(X)}^{3}\cap (\mathbf{P}(V_{6}(X))\setminus \mathbf{P}(V_{5}(X)))\neq \varnothing$ ;

  2. (2) there is a rank $6$ quadric $Q\subset \mathbf{P}(W)$ such that $X=\mathbf{G}\cap Q$ ;

  3. (3) $X$ contains a quintic del Pezzo surface, i.e. a smooth codimension $4$ linear section of the Grassmannian $\mathbf{G}\subset \mathbf{P}(\wedge ^{2}V_{5}(X))$ .

Proof. The equivalence of (1) and (2) follows from Proposition 3.4 since $\dim W=9$ . Note that since $\mathsf{Y}_{\mathsf{A}(X)}^{4}=\varnothing$ , the same proposition also shows that if $X=\mathbf{G}\cap Q$ then $\text{rank}(Q)\geqslant 6$ .

We show (2) is equivalent to (3). First assume (2) holds. Then a maximal isotropic space $I\subset W$ for $Q$ has dimension $6$ , so $\mathbf{G}\cap \mathbf{P}(I)$ is a quintic del Pezzo surface contained in $X$ , provided this intersection is transverse. By the argument of [Reference Debarre and KuznetsovDK18a, Lemma 4.1] (or by Lemma 4.6 below), this is true for a general $I$ .

Conversely, assume (3) holds, i.e. assume there is a $6$ -dimensional subspace $I\subset W$ such that $Z=\mathbf{G}\cap \mathbf{P}(I)\subset X$ is a quintic del Pezzo. The restriction map $V_{6}(X)\rightarrow \text{H}^{0}({\mathcal{I}}_{Z/\mathbf{P}(I)}(2))$ from quadrics in $\mathbf{P}(W)$ containing $X$ to those in $\mathbf{P}(I)$ containing $Z$ is surjective with one-dimensional kernel. If $Q\subset \mathbf{P}(W)$ is the quadric corresponding to this kernel, then $X=\mathbf{G}\,\cap \,Q$ and $\mathbf{P}(I)\subset Q$ . It follows that $\text{rank}(Q)\leqslant 6$ . But as we noted above, the reverse inequality also holds.◻

For the rest of the section, we fix an ordinary GM fourfold $X$ satisfying the equivalent conditions of Lemma 4.4 and a point $\mathbf{q}\in \mathsf{Y}_{\mathsf{A}(X)}^{3}\cap (\mathbf{P}(V_{6}(X))\setminus \mathbf{P}(V_{5}(X)))$ . Further, to ease notation, we denote the generalized dual of $X$ corresponding to the quadric point $\mathbf{q}$ (see Lemma 3.8) by

$$\begin{eqnarray}Y=X_{\mathbf{q}}^{\vee }.\end{eqnarray}$$

Note that $Y$ is a GM surface.

4.2 Setup and outline of the proof

We outline here the strategy for proving Theorem 4.1.

The starting point is the following explicit geometric relation between $X$ and  $Y$ . By Proposition 3.4, the point $\mathbf{q}$ corresponds to a rank $6$ quadric $Q$ cutting out  $X$ , and the Plücker point  $\mathbf{p}_{X}\in \mathbf{P}(V_{6}(X)^{\vee })\cong \mathbf{P}(V_{6}(Y))$ of $X$ corresponds to a quadric $Q^{\prime }$ cutting out  $Y$ . Because  $X$ and $Y$ are ordinary, we may regard $Q$ as a subvariety of $\mathbf{P}(\wedge ^{2}V_{5}(X))$ and $Q^{\prime }$ as a subvariety of $\mathbf{P}(\wedge ^{2}V_{5}(Y))$ . Then [Reference Debarre and KuznetsovDK18a, Proposition 3.28] (which is stated for dual varieties but works just as well for generalized duals) says that there is an isomorphism $V_{5}(X)\cong V_{5}(Y)^{\vee }$ identifying $Q^{\prime }\subset \mathbf{P}(\wedge ^{2}V_{5}(Y))$ with the projective dual to $Q\subset \mathbf{P}(\wedge ^{2}V_{5}(X))$ . Hence, fixing $V_{5}=V_{5}(X)$ , our setup is as follows: there is a hyperplane $W\subset \wedge ^{2}V_{5}$ and a rank  $6$ quadric $Q\subset \mathbf{P}(W)$ such that

$$\begin{eqnarray}X=\mathbf{G}\cap Q\quad \text{and}\quad Y=\mathbf{G}^{\vee }\cap Q^{\vee },\end{eqnarray}$$

where $Q^{\vee }\subset \mathbf{P}(\wedge ^{2}V_{5}^{\vee })$ is the projectively dual quadric to $Q\subset \mathbf{P}(\wedge ^{2}V_{5})$ , and

$$\begin{eqnarray}\mathbf{G}^{\vee }=\operatorname{Gr}(2,V_{5}^{\vee })\subset \mathbf{P}(\wedge ^{2}V_{5}^{\vee })\end{eqnarray}$$

is the dual Grassmannian.

From this starting point, the main steps of the proof are as follows. First, by considering families of maximal linear subspaces of $Q$ and $Q^{\vee }$ , we find $\mathbf{P}^{1}$ -bundles $\widehat{X}\rightarrow X$ and $\widehat{Y}\rightarrow Y$ , together with morphisms $\widehat{X}\rightarrow \mathbf{P}^{3}$ and $\widehat{Y}\rightarrow \mathbf{P}^{3}$ realizing $\widehat{X}$ and $\widehat{Y}$ as families of mutually orthogonal linear sections of $\mathbf{G}$ and $\mathbf{G}^{\vee }$ . This allows us to apply homological projective duality to obtain a semiorthogonal decomposition of $\text{D}^{\text{b}}(\widehat{X})$ with $\text{D}^{\text{b}}(\widehat{Y})$ as a component. By comparing this (via mutation functors) with the decomposition of $\text{D}^{\text{b}}(\widehat{X})$ coming from its  $\mathbf{P}^{1}$ -bundle structure over $X$ , we show $\text{D}^{\text{b}}(\widehat{Y})$ has a decomposition into two copies of ${\mathcal{A}}_{X}$ . On the other hand, as $\widehat{Y}\rightarrow Y$ is a $\mathbf{P}^{1}$ -bundle, $\text{D}^{\text{b}}(\widehat{Y})$ also decomposes into two copies of $\text{D}^{\text{b}}(Y)$ . We show these two decompositions of $\text{D}^{\text{b}}(\widehat{Y})$ coincide, and hence ${\mathcal{A}}_{X}\simeq \text{D}^{\text{b}}(Y)$ . Our proof gives an explicit functor inducing this equivalence, see (4.15).

4.3 Maximal linear subspaces of the quadrics

We start by discussing a geometric relation between $Q$ and $Q^{\vee }$ . Let $K\subset W$ be the kernel of  $Q$ , regarded as a symmetric linear map $W\rightarrow W^{\vee }$ . Since $\dim W=9$ and $\text{rank}(Q)=6$ , we have $\dim K=3$ . The filtration

$$\begin{eqnarray}0\subset K\subset W\subset \wedge ^{2}V_{5}\end{eqnarray}$$

induces a filtration

$$\begin{eqnarray}0\subset W^{\bot }\subset K^{\bot }\subset \wedge ^{2}V_{5}^{\vee },\end{eqnarray}$$

where $K^{\bot }$ and $W^{\bot }$ are the annihilators of $K$ and $W$ , so that $\dim K^{\bot }=7$ and $\dim W^{\bot }=1$ . The pairing between the dual spaces $\wedge ^{2}V_{5}$ and $\wedge ^{2}V_{5}^{\vee }$ induces a non-degenerate pairing between  $W/K$ and $K^{\bot }/W^{\bot }$ , and hence an isomorphism

$$\begin{eqnarray}K^{\bot }/W^{\bot }\cong (W/K)^{\vee }.\end{eqnarray}$$

The quadric $Q$ induces a smooth quadric $\bar{Q}$ in the 5-dimensional projective space $\mathbf{P}(W/K)$ . The quadric $\bar{Q}$ can be identified with the Grassmannian $\operatorname{Gr}(2,4)$ ; more precisely, we can find an isomorphism

$$\begin{eqnarray}W/K\cong \wedge ^{2}S\end{eqnarray}$$

for a 4-dimensional vector space $S$ , with an identification

$$\begin{eqnarray}\bar{Q}=\operatorname{Gr}(2,S)\subset \mathbf{P}(\wedge ^{2}S).\end{eqnarray}$$

The projective dual of $\bar{Q}$ is then the dual Grassmannian

$$\begin{eqnarray}\bar{Q}^{\vee }=\operatorname{Gr}(2,S^{\vee })\subset \mathbf{P}(\wedge ^{2}S^{\vee })=\mathbf{P}((W/K)^{\vee })=\mathbf{P}(K^{\bot }/W^{\bot }).\end{eqnarray}$$

It follows that the projective dual of

(4.1) $$\begin{eqnarray}Q=\operatorname{Cone}_{\mathbf{P}(K)}\bar{Q}\subset \mathbf{P}(\wedge ^{2}V_{5})\end{eqnarray}$$

is given by

(4.2) $$\begin{eqnarray}Q^{\vee }=\operatorname{Cone}_{\boldsymbol{ P}(W^{\bot })}\bar{Q}^{\vee }\subset \mathbf{P}(\wedge ^{2}V_{5}^{\vee }).\end{eqnarray}$$

Projective 3-space $\mathbf{P}(S)$ is (a connected component of) the space of maximal linear subspaces of the quadric $\bar{Q}=\operatorname{Gr}(2,S)$ . The universal family is the flag variety $\operatorname{Fl}(1,2;S)\rightarrow \mathbf{P}(S)$ , with fiber over a point $s\in \mathbf{P}(S)$ the plane $\mathbf{P}(s\wedge S)\subset \mathbf{P}(\wedge ^{2}S)$ . Analogously, the same flag variety $\operatorname{Fl}(2,3;S^{\vee })\cong \operatorname{Fl}(1,2;S)$ is (a connected component of) the space of maximal linear subspaces of $\bar{Q}^{\vee }=\operatorname{Gr}(2,S^{\vee })$ , this time with fiber over a point $s\in \mathbf{P}(S)$ being the plane $\mathbf{P}(\wedge ^{2}s^{\bot })\subset \mathbf{P}(\wedge ^{2}S^{\vee })$ . Note that the fibers of these two correspondences over a point $s\in \mathbf{P}(S)$ are mutually orthogonal with respect to the pairing between $\wedge ^{2}S$ and $\wedge ^{2}S^{\vee }$ . We summarize this discussion by the diagram

(4.3)

with the inner arrows being $\mathbf{P}^{2}$ -bundles with mutually orthogonal fibers (as linear subspaces of  $\mathbf{P}(\wedge ^{2}S)$ and $\mathbf{P}(\wedge ^{2}S^{\vee })$ ), and the outer arrows being $\mathbf{P}^{1}$ -bundles.

By (4.1) every maximal isotropic subspace of $\bar{Q}$ gives a maximal isotropic subspace of $Q$ by taking its preimage under the projection $W\rightarrow W/K=\wedge ^{2}S$ . Analogously, by (4.2) every maximal isotropic subspace of $\bar{Q}^{\vee }$ gives a maximal isotropic subspace of $Q^{\vee }$ by taking its preimage under the projection $K^{\bot }\rightarrow K^{\bot }/W^{\bot }=\wedge ^{2}S^{\vee }$ . Note that for the pairing between  $W$ and $K^{\bot }$ induced by the pairing between $\wedge ^{2}V_{5}$ and $\wedge ^{2}V_{5}^{\vee }$ , the subspace $K\subset W$ is the left kernel, and the subspace $W^{\bot }\subset K^{\bot }$ is the right kernel. Hence any $s\in \mathbf{P}(S)$ gives mutually orthogonal maximal isotropic spaces ${\mathcal{I}}_{s}$ and ${\mathcal{I}}_{s}^{\bot }$ of $Q$ and $Q^{\vee }$ respectively. These spaces form the fibers of vector bundles ${\mathcal{I}}$ and  ${\mathcal{I}}^{\bot }$ over $\mathbf{P}(S)$ of ranks $6$ and $4$ , which are mutually orthogonal subbundles of $\wedge ^{2}V_{5}\otimes {\mathcal{O}}_{\mathbf{P}(S)}$ and $\wedge ^{2}V_{5}^{\vee }\otimes {\mathcal{O}}_{\mathbf{P}(S)}$ . We can summarize this discussion by the following diagram.

(4.4)

Here the inner arrows are $\mathbf{P}^{5}$ - and $\mathbf{P}^{3}$ -bundles with mutually orthogonal fibers, and the outer arrows are $\mathbf{P}^{1}$ -bundles (induced by the $\mathbf{P}^{1}$ -bundles of diagram (4.3)) away from the vertices $\mathbf{P}(K)$ and $\mathbf{P}(W^{\bot })$ of the quadrics (over which the fibers are isomorphic to $\mathbf{P}(S)\cong \mathbf{P}^{3}$ ).

4.4 Families of linear sections of the Grassmannians

Now define

(4.5) $$\begin{eqnarray}\widehat{X}:=\mathbf{G}\times _{\mathbf{P}(\wedge ^{2}V_{5})}\mathbf{P}_{\mathbf{P}(S)}({\mathcal{I}})\quad \text{and}\quad \widehat{Y}:=\mathbf{G}^{\vee }\times _{\boldsymbol{ P}(\wedge ^{2}V_{5}^{\vee })}\mathbf{P}_{\mathbf{P}(S)}({\mathcal{I}}^{\bot })\end{eqnarray}$$

to be the induced families of linear sections of $\mathbf{G}$ and $\mathbf{G}^{\vee }$ . They fit into a diagram

(4.6)

with the maps induced by those in (4.4) (remember that $X=\mathbf{G}\cap Q$ and $Y=\mathbf{G}^{\vee }\cap Q^{\vee }$ ).

We will denote by $H,H^{\prime }$ , and $h$ the ample generators of $\operatorname{Pic}(\mathbf{G})$ , $\operatorname{Pic}(\mathbf{G}^{\vee })$ , and $\mathbf{P}(S)$ .

Lemma 4.5. There are rank $2$ vector bundles ${\mathcal{S}}_{X}$ and ${\mathcal{S}}_{Y}$ on $X$ and $Y$ with $\operatorname{c}_{1}({\mathcal{S}}_{X})=-H$ and $\operatorname{c}_{1}({\mathcal{S}}_{Y})=-H^{\prime }$ , and isomorphisms

$$\begin{eqnarray}\widehat{X}\cong \mathbf{P}_{X}({\mathcal{S}}_{X})\quad \text{and}\quad \widehat{Y}\cong \mathbf{P}_{Y}({\mathcal{S}}_{Y}),\end{eqnarray}$$

such that ${\mathcal{O}}_{\mathbf{P}_{X}({\mathcal{S}}_{X})}(1)=\unicode[STIX]{x1D70B}_{X}^{\ast }{\mathcal{O}}_{\mathbf{P}(S)}(h)$ and ${\mathcal{O}}_{\mathbf{P}_{Y}({\mathcal{S}}_{Y})}(1)=\unicode[STIX]{x1D70B}_{Y}^{\ast }{\mathcal{O}}_{\mathbf{P}(S)}(h)$ . In particular, $\widehat{X}$ is a smooth fivefold, $\widehat{Y}$ is a smooth threefold, and

(4.7) $$\begin{eqnarray}K_{\widehat{X}}=-H-2h\quad \text{and}\quad K_{\widehat{Y}}=H^{\prime }-2h.\end{eqnarray}$$

Proof. Since $X$ and $Y$ are smooth, they do not intersect the vertices $\mathbf{P}(K)$ and $\mathbf{P}(W^{\bot })$ of the quadrics $Q$ and $Q^{\vee }$ , hence the maps $p_{X}$ and $p_{Y}$ are $\mathbf{P}^{1}$ -fibrations induced by those in diagram (4.4). In other words, we have fiber product squares

The map $p_{\bar{Q}}$ is the projectivization of the tautological subbundle of $S\otimes {\mathcal{O}}$ on $\bar{Q}=\operatorname{Gr}(2,S)$ , and $p_{\bar{Q}^{\vee }}$ is the projectivization of the annihilator of the tautological subbundle of $S^{\vee }\otimes {\mathcal{O}}$ on the dual Grassmannian $\bar{Q}^{\vee }=\operatorname{Gr}(2,S^{\vee })$ . So we can take ${\mathcal{S}}_{X}$ and ${\mathcal{S}}_{Y}$ to be the pullbacks to $X$ and $Y$ of these bundles.

To compute the canonical classes, note that the determinant of the tautological bundle (and of its annihilator) on $\operatorname{Gr}(2,S)$ is ${\mathcal{O}}_{\operatorname{Gr}(2,S)}(-1)$ , hence $\operatorname{c}_{1}({\mathcal{S}}_{X})=-H$ and $\operatorname{c}_{1}({\mathcal{S}}_{Y})=-H^{\prime }$ . Now apply the standard formula for the canonical bundle of the projectivization of a vector bundle, taking into account that $K_{X}=-2H$ and $K_{Y}=0$ by (2.2).◻

Lemma 4.6. The map $\unicode[STIX]{x1D70B}_{X}:\widehat{X}\rightarrow \mathbf{P}(S)$ is flat with general fiber a smooth quintic del Pezzo surface. The map $\unicode[STIX]{x1D70B}_{Y}:\widehat{Y}\rightarrow \mathbf{P}(S)$ is generically finite of degree $5$ .

Proof. The fiber of $\unicode[STIX]{x1D70B}_{X}$ over a point $s\in \mathbf{P}(S)$ is the intersection $\mathbf{G}\cap \mathbf{P}({\mathcal{I}}_{s})$ , where the subspace $\mathbf{P}({\mathcal{I}}_{s})\subset \mathbf{P}(\wedge ^{2}V_{5})$ has codimension $4$ . Thus the dimension of $\unicode[STIX]{x1D70B}_{X}^{-1}(s)$ is at least 2. If the dimension were greater than 2, this fiber would give a divisor in $X$ of degree at most $5$ , but by (2.3) and (2.2) every divisor in $X$ has degree divisible by $10$ . Thus every fiber is a dimensionally transverse intersection, and flatness follows.

Furthermore, since $\widehat{X}$ is smooth, the general fiber of $\unicode[STIX]{x1D70B}_{X}$ is a smooth quintic del Pezzo surface. Then by [Reference Debarre and KuznetsovDK18a, Proposition 2.24] the general fiber of $\unicode[STIX]{x1D70B}_{Y}$ is a dimensionally transverse and smooth linear section of $\mathbf{G}^{\vee }$ of codimension 6, hence is just 5 reduced points.◻

As a byproduct of the above, we obtain the following.

Lemma 4.7. The variety $X$ is rational.

Proof. The same argument as in [Reference Debarre and KuznetsovDK18a, Proposition 4.2] works. Let $\widetilde{X}\subset \widehat{X}$ be the preimage under the map  $\unicode[STIX]{x1D70B}_{X}$ of a general hyperplane $\mathbf{P}^{2}\subset \mathbf{P}(S)$ . By Lemma 4.6, the general fiber of the morphism $\widetilde{X}\rightarrow \mathbf{P}^{2}$ is a smooth quintic del Pezzo surface. Hence by a theorem of Enriques [Reference Shepherd-BarronShe92], $\widetilde{X}$ is rational over  $\mathbf{P}^{2}$ , and so over  $\mathbf{k}$ as well. On the other hand, the map $\widetilde{X}\rightarrow X$ is birational (in fact, it is a blowup of a quintic del Pezzo surface), so $X$ is rational too.◻

4.5 Homological projective duality

Homological projective duality (HPD) is a key tool in the proof of Theorem 4.1. Very roughly, HPD relates the derived categories of linear sections of a given variety to those of orthogonal linear sections of an ‘HPD variety’. We refer to [Reference KuznetsovKuz07] for the details of this theory, and to [Reference KuznetsovKuz14] or [Reference ThomasTho17] for an overview. For us, the relevant point is that the dual Grassmannian $\mathbf{G}^{\vee }$ is HPD to $\mathbf{G}$ . We spell out the precise consequence of this that we need below.

Recall that by Lemma 2.2 there is a semiorthogonal decomposition

$$\begin{eqnarray}\text{D}^{\text{b}}(\mathbf{G})=\langle {\mathcal{B}},{\mathcal{B}}(H),{\mathcal{B}}(2H),{\mathcal{B}}(3H),{\mathcal{B}}(4H)\rangle .\end{eqnarray}$$

Let

$$\begin{eqnarray}i:\mathbf{H}(\mathbf{G},\mathbf{G}^{\vee }){\hookrightarrow}\mathbf{G}\times \mathbf{G}^{\vee }\subset \mathbf{P}(\wedge ^{2}V_{5})\times \mathbf{P}(\wedge ^{2}V_{5}^{\vee })\end{eqnarray}$$

be the incidence divisor defined by the canonical section of ${\mathcal{O}}(H+H^{\prime })$ . Recall that ${\mathcal{U}}$ denotes the tautological rank $2$ bundle on $\mathbf{G}$ , and let ${\mathcal{V}}$ denote the tautological rank $2$ bundle on $\mathbf{G}^{\vee }$ . The following was proved in [Reference KuznetsovKuz06, § 6.1]. See [Reference KuznetsovKuz07, Definition 6.1] for the definition of HPD.

Theorem 4.8. The Grassmannian $\mathbf{G}^{\vee }\rightarrow \mathbf{P}(\wedge ^{2}V_{5}^{\vee })$ is HPD to $\mathbf{G}\rightarrow \mathbf{P}(\wedge ^{2}V_{5})$ with respect to the above semiorthogonal decomposition. Moreover, the duality is implemented by a sheaf  ${\mathcal{E}}$ on  $\mathbf{H}(\mathbf{G},\mathbf{G}^{\vee })$ whose pushforward to $\mathbf{G}\times \mathbf{G}^{\vee }$ fits into an exact sequence

$$\begin{eqnarray}0\rightarrow {\mathcal{O}}_{\mathbf{G}}\boxtimes {\mathcal{V}}\rightarrow {\mathcal{U}}^{\vee }\boxtimes {\mathcal{O}}_{\boldsymbol{ G}^{\vee }}\rightarrow i_{\ast }{\mathcal{E}}\rightarrow 0.\end{eqnarray}$$

In fact, we shall only need a consequence of HPD, which we formulate below as Corollary 4.9. Note that the natural map

$$\begin{eqnarray}\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}\rightarrow X\times Y\rightarrow \mathbf{G}\times \mathbf{G}^{\vee }\end{eqnarray}$$

factors through $\mathbf{H}(\mathbf{G},\mathbf{G}^{\vee })$ . Indeed, the fiber of $\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}$ over any point $s\in \mathbf{P}(S)$ is

$$\begin{eqnarray}(\mathbf{P}({\mathcal{I}}_{s})\times \mathbf{P}({\mathcal{I}}_{s}^{\bot }))\cap (\mathbf{G}\times \mathbf{G}^{\vee })\subset \mathbf{H}(\mathbf{G},\mathbf{G}^{\vee }).\end{eqnarray}$$

Note also that

(4.8) $$\begin{eqnarray}\dim (\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y})=5,\end{eqnarray}$$

since the map $\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}\rightarrow \widehat{Y}$ is flat of relative dimension 2 by Lemma 4.6, and $\dim (\widehat{Y})=3$ by Lemma 4.5.

Denote by $\widehat{{\mathcal{E}}}$ the pullback of the HPD object ${\mathcal{E}}$ to $\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}$ and by $\widehat{\unicode[STIX]{x1D6F7}}:\text{D}^{\text{b}}(\widehat{Y})\rightarrow \text{D}^{\text{b}}(\widehat{X})$ the corresponding Fourier–Mukai functor. Note that $\widehat{\unicode[STIX]{x1D6F7}}$ is $\mathbf{P}(S)$ -linear (since $\widehat{{\mathcal{E}}}$ is supported on the fiber product $\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}$ ), i.e.

$$\begin{eqnarray}\widehat{\unicode[STIX]{x1D6F7}}({\mathcal{F}}\otimes \unicode[STIX]{x1D70B}_{Y}^{\ast }{\mathcal{G}})\cong \widehat{\unicode[STIX]{x1D6F7}}({\mathcal{F}})\otimes \unicode[STIX]{x1D70B}_{X}^{\ast }{\mathcal{G}}\end{eqnarray}$$

for all ${\mathcal{F}}\in \text{D}^{\text{b}}(\widehat{Y})$ and ${\mathcal{G}}\in \text{D}^{\text{b}}(\mathbf{P}(S))$ . By Lemma 4.5 and (4.8), the families $\widehat{X}$ and $\widehat{Y}$ of linear sections of $\mathbf{G}$ and $\mathbf{G}^{\vee }$ satisfy the dimension assumptions of [Reference KuznetsovKuz07, Theorem 6.27]. Hence we obtain the following.

Corollary 4.9. The functor $\widehat{\unicode[STIX]{x1D6F7}}:\text{D}^{\text{b}}(\widehat{Y})\rightarrow \text{D}^{\text{b}}(\widehat{X})$ is fully faithful, and there is a semiorthogonal decomposition

(4.9) $$\begin{eqnarray}\text{D}^{\text{b}}(\widehat{X})=\langle \widehat{\unicode[STIX]{x1D6F7}}(\text{D}^{\text{b}}(\widehat{Y})),{\mathcal{B}}_{X}(H)\boxtimes \text{D}^{\text{b}}(\mathbf{P}(S))\rangle ,\end{eqnarray}$$

where ${\mathcal{B}}_{X}(H)\,\boxtimes \,\text{D}^{\text{b}}(\mathbf{P}(S))$ denotes the triangulated subcategory generated by objects of the form $p_{X}^{\ast }({\mathcal{F}})\otimes \unicode[STIX]{x1D70B}_{X}^{\ast }({\mathcal{G}})$ for ${\mathcal{F}}\in {\mathcal{B}}_{X}(H)$ and ${\mathcal{G}}\in \text{D}^{\text{b}}(\mathbf{P}(S))$ .

4.6 Mutations

Since $p_{X}:\widehat{X}\rightarrow X$ is a $\mathbf{P}^{1}$ -bundle (Lemma 4.5), we also have a semiorthogonal decomposition

$$\begin{eqnarray}\text{D}^{\text{b}}(\widehat{X})=\langle p_{X}^{\ast }\text{D}^{\text{b}}(X),p_{X}^{\ast }\text{D}^{\text{b}}(X)(h)\rangle .\end{eqnarray}$$

Inserting the decomposition (2.10) of $\text{D}^{\text{b}}(X)$ , we obtain

(4.10) $$\begin{eqnarray}\text{D}^{\text{b}}(\widehat{X})=\langle {\mathcal{A}}_{\widehat{X}},{\mathcal{B}},{\mathcal{B}}(H),{\mathcal{A}}_{\widehat{X}}(h),{\mathcal{B}}(h),{\mathcal{B}}(H+h)\rangle ,\end{eqnarray}$$

where to ease notation we write ${\mathcal{A}}_{\widehat{X}}$ for $p_{X}^{\ast }{\mathcal{A}}_{X}$ and simply ${\mathcal{B}}$ for $p_{X}^{\ast }{\mathcal{B}}_{X}$ . We find a sequence of mutations bringing this decomposition into the form of (4.9). In doing so we will use several times $K_{X}=-2H$ , which holds by (2.2), and $K_{\widehat{X}}=-H-2h$ , which holds by (4.7). For a brief review of mutation functors and references, see the discussion in § 2.8.

Step 1. Mutate ${\mathcal{B}}(H)$ to the left of ${\mathcal{A}}_{\widehat{X}}$ in (4.10). Since this is a mutation in $p_{X}^{\ast }\text{D}^{\text{b}}(X)$ and $K_{X}=-2H$ , by (2.19) we get

$$\begin{eqnarray}\text{D}^{\text{b}}(\widehat{X})=\langle {\mathcal{B}}(-H),{\mathcal{A}}_{\widehat{X}},{\mathcal{B}},{\mathcal{A}}_{\widehat{X}}(h),{\mathcal{B}}(h),{\mathcal{B}}(H+h)\rangle .\end{eqnarray}$$

Step 2. Mutate ${\mathcal{B}}(H+h)$ to the far left. Since $K_{\widehat{X}}=-H-2h$ , by (2.19) we get

$$\begin{eqnarray}\text{D}^{\text{b}}(\widehat{X})=\langle {\mathcal{B}}(-h),{\mathcal{B}}(-H),{\mathcal{A}}_{\widehat{X}},{\mathcal{B}},{\mathcal{A}}_{\widehat{X}}(h),{\mathcal{B}}(h)\rangle .\end{eqnarray}$$

Step 3. Mutate ${\mathcal{B}}(-H)$ to the left of ${\mathcal{B}}(-h)$ . Since these two subcategories are completely orthogonal (see the lemma below), we get

$$\begin{eqnarray}\text{D}^{\text{b}}(\widehat{X})=\langle {\mathcal{B}}(-H),{\mathcal{B}}(-h),{\mathcal{A}}_{\widehat{X}},{\mathcal{B}},{\mathcal{A}}_{\widehat{X}}(h),{\mathcal{B}}(h)\rangle .\end{eqnarray}$$

Lemma 4.10. The categories ${\mathcal{B}}(-H)$ and ${\mathcal{B}}(-h)$ in $\text{D}^{\text{b}}(\widehat{X})$ are completely orthogonal.

Proof. By Step 2, the pair $({\mathcal{B}}(-h),{\mathcal{B}}(-H))$ is semiorthogonal. On the other hand, by Serre duality and (4.7), semiorthogonality of $({\mathcal{B}}(-H),{\mathcal{B}}(-h))$ is equivalent to that of $({\mathcal{B}}(-h),{\mathcal{B}}(2h))$ , which follows from (4.9) as $({\mathcal{O}}(-h),{\mathcal{O}}(2h))$ is semiorthogonal in $\text{D}^{\text{b}}(\mathbf{P}(S))$ .◻

Step 4. Mutate ${\mathcal{B}}(-H)$ to the far right. Again by (2.19), we get

$$\begin{eqnarray}\text{D}^{\text{b}}(\widehat{X})=\langle {\mathcal{B}}(-h),{\mathcal{A}}_{\widehat{X}},{\mathcal{B}},{\mathcal{A}}_{\widehat{X}}(h),{\mathcal{B}}(h),{\mathcal{B}}(2h)\rangle .\end{eqnarray}$$

Step 5. Mutate ${\mathcal{A}}_{\widehat{X}}$ and ${\mathcal{A}}_{\widehat{X}}(h)$ to the far left. We get

$$\begin{eqnarray}\displaystyle \text{D}^{\text{b}}(\widehat{X}) & = & \displaystyle \langle \text{L}_{{\mathcal{B}}(-h)}({\mathcal{A}}_{\widehat{X}}),\text{L}_{\langle {\mathcal{B}}(-h),{\mathcal{B}}\rangle }({\mathcal{A}}_{\widehat{X}}(h)),{\mathcal{B}}(-h),{\mathcal{B}},{\mathcal{B}}(h),{\mathcal{B}}(2h)\rangle \nonumber\\ \displaystyle & = & \displaystyle \langle \text{L}_{{\mathcal{B}}(-h)}({\mathcal{A}}_{\widehat{X}}),\text{L}_{\langle {\mathcal{B}}(-h),{\mathcal{B}}\rangle }({\mathcal{A}}_{\widehat{X}}(h)),{\mathcal{B}}_{X}\boxtimes \text{D}^{\text{b}}(\mathbf{P}(S))\rangle ,\nonumber\end{eqnarray}$$

where we used the standard decomposition $\text{D}^{\text{b}}(\mathbf{P}(S))=\langle {\mathcal{O}}(-h),{\mathcal{O}},{\mathcal{O}}(h),{\mathcal{O}}(2h)\rangle$ .

Step 6. Twist the decomposition by ${\mathcal{O}}(H)$ . We get

(4.11) $$\begin{eqnarray}\text{D}^{\text{b}}(\widehat{X})=\langle \text{L}_{{\mathcal{B}}(H-h)}({\mathcal{A}}_{\widehat{X}}(H)),\text{L}_{\langle {\mathcal{B}}(H-h),{\mathcal{B}}(H)\rangle }({\mathcal{A}}_{\widehat{X}}(H+h)),{\mathcal{B}}_{X}(H)\boxtimes \text{D}^{\text{b}}(\mathbf{P}(S))\rangle .\end{eqnarray}$$

To rewrite the first two components here, we used the following general fact: If ${\mathcal{A}}\subset {\mathcal{T}}$ is an admissible subcategory of a triangulated category and $F$ is an autoequivalence of ${\mathcal{T}}$ (in our case  $F$ is the autoequivalence of $\text{D}^{\text{b}}(\widehat{X})$ given by tensoring with ${\mathcal{O}}(H)$ ), then there is an isomorphism of functors

(4.12) $$\begin{eqnarray}F\circ \text{L}_{{\mathcal{A}}}\cong \text{L}_{F({\mathcal{A}})}\circ F.\end{eqnarray}$$

Finally, we obtain the following.

Proposition 4.11. The functor $\widehat{\unicode[STIX]{x1D6F7}}^{\ast }\circ (-\!\otimes {\mathcal{O}}(H)):\text{D}^{\text{b}}(\widehat{X})\rightarrow \text{D}^{\text{b}}(\widehat{Y})$ induces an equivalence

$$\begin{eqnarray}\langle {\mathcal{A}}_{\widehat{X}},{\mathcal{A}}_{\widehat{X}}(h)\rangle \simeq \text{D}^{\text{b}}(\widehat{Y}),\end{eqnarray}$$

where $\widehat{\unicode[STIX]{x1D6F7}}^{\ast }:\text{D}^{\text{b}}(\widehat{X})\rightarrow \text{D}^{\text{b}}(\widehat{Y})$ denotes the left adjoint of $\widehat{\unicode[STIX]{x1D6F7}}$ .

Proof. Comparing the decompositions (4.11) and (4.9), we see that $\widehat{\unicode[STIX]{x1D6F7}}$ induces an equivalence

$$\begin{eqnarray}\widehat{\unicode[STIX]{x1D6F7}}:\text{D}^{\text{b}}(\widehat{Y})\xrightarrow[{}]{~\sim ~}\langle \text{L}_{{\mathcal{B}}(H-h)}({\mathcal{A}}_{\widehat{X}}(H)),\text{L}_{\langle {\mathcal{B}}(H-h),{\mathcal{B}}(H)\rangle }({\mathcal{A}}_{\widehat{X}}(H+h))\rangle .\end{eqnarray}$$

Therefore its left adjoint $\widehat{\unicode[STIX]{x1D6F7}}^{\ast }$ gives an inverse equivalence. On the other hand, by semiorthogonality of (4.9) the functor $\widehat{\unicode[STIX]{x1D6F7}}^{\ast }$ vanishes on ${\mathcal{B}}(H-h)$ and ${\mathcal{B}}(H)$ , hence its composition with the mutation functors through these categories is isomorphic to $\widehat{\unicode[STIX]{x1D6F7}}^{\ast }$ . Thus $\widehat{\unicode[STIX]{x1D6F7}}^{\ast }$ induces an equivalence from the subcategory $\langle {\mathcal{A}}_{\widehat{X}}(H),{\mathcal{A}}_{\widehat{X}}(H+h)\rangle \subset \text{D}^{\text{b}}(\widehat{X})$ to  $\text{D}^{\text{b}}(\widehat{Y})$ . This is equivalent to the claim.◻

4.7 Proof of the theorem

Since $p_{Y}:\widehat{Y}\rightarrow Y$ is a $\mathbf{P}^{1}$ -bundle (Lemma 4.5), we have

(4.13) $$\begin{eqnarray}\text{D}^{\text{b}}(\widehat{Y})=\langle p_{Y}^{\ast }\text{D}^{\text{b}}(Y),p_{Y}^{\ast }\text{D}^{\text{b}}(Y)(h)\rangle .\end{eqnarray}$$

We aim to prove that this semiorthogonal decomposition coincides with the one obtained by applying the fully faithful functor $(-\!\otimes {\mathcal{O}}(-h))\circ \widehat{\unicode[STIX]{x1D6F7}}^{\ast }\circ (-\!\otimes {\mathcal{O}}(H))$ to $\langle {\mathcal{A}}_{\widehat{X}},{\mathcal{A}}_{\widehat{X}}(h)\rangle$ . For this, we consider the composition of functors

(4.14) $$\begin{eqnarray}\text{F}:=p_{Y\ast }\circ (-\!\otimes {\mathcal{O}}(-2h))\circ \widehat{\unicode[STIX]{x1D6F7}}^{\ast }\circ (-\!\otimes {\mathcal{O}}(H))\circ p_{X}^{\ast }:\text{D}^{\text{b}}(X)\rightarrow \text{D}^{\text{b}}(Y).\end{eqnarray}$$

Proposition 4.12. The functor $\text{F}$ vanishes on the subcategory ${\mathcal{A}}_{X}\subset \text{D}^{\text{b}}(X)$ .

Before proving the proposition, let us show how it implies the equivalence  ${\mathcal{A}}_{X}\simeq \text{D}^{\text{b}}(Y)$ .

Proof of Theorem 4.1.

We claim that

(4.15) $$\begin{eqnarray}p_{Y\ast }\circ (-\!\otimes {\mathcal{O}}(-h))\circ \widehat{\unicode[STIX]{x1D6F7}}^{\ast }\circ (-\!\otimes {\mathcal{O}}(H))\circ p_{X}^{\ast }:\text{D}^{\text{b}}(X)\rightarrow \text{D}^{\text{b}}(Y)\end{eqnarray}$$

induces an equivalence ${\mathcal{A}}_{X}\simeq \text{D}^{\text{b}}(Y)$ . Note that the functor $p_{X}^{\ast }$ is fully faithful on ${\mathcal{A}}_{X}$ . So by Proposition 4.11 the functor $(-\!\otimes {\mathcal{O}}(-h))\circ \widehat{\unicode[STIX]{x1D6F7}}^{\ast }\circ (-\!\otimes {\mathcal{O}}(H))\circ p_{X}^{\ast }$ gives a fully faithful embedding ${\mathcal{A}}_{X}{\hookrightarrow}\text{D}^{\text{b}}(\widehat{Y})$ , whose image ${\mathcal{A}}$ satisfies

(4.16) $$\begin{eqnarray}\text{D}^{\text{b}}(Y)=\langle {\mathcal{A}},{\mathcal{A}}(h)\rangle .\end{eqnarray}$$

On the other hand, by Proposition 4.12 the functor $p_{Y\ast }$ annihilates ${\mathcal{A}}(-h)$ . But the kernel of the functor $p_{Y\ast }$ is $p_{Y}^{\ast }\text{D}^{\text{b}}(Y)(-h)$ , so ${\mathcal{A}}(-h)\subset p_{Y}^{\ast }\text{D}^{\text{b}}(Y)(-h)$ , and thus

$$\begin{eqnarray}{\mathcal{A}}\subset p_{Y}^{\ast }\text{D}^{\text{b}}(Y)\quad \text{and}\quad {\mathcal{A}}(h)\subset p_{Y}^{\ast }\text{D}^{\text{b}}(Y)(h).\end{eqnarray}$$

In view of the decompositions (4.16) and (4.13), we see that equality holds in the above inclusions. Since $p_{Y\ast }$ induces an equivalence $p_{Y}^{\ast }\text{D}^{\text{b}}(Y)\simeq \text{D}^{\text{b}}(Y)$ , this finishes the proof.◻

Now we turn to the proof of Proposition 4.12, which takes the rest of the section. Let $f_{X}:X\rightarrow \mathbf{G}$ and $f_{Y}:Y\rightarrow \mathbf{G}^{\vee }$ be the Gushel maps, and let $p_{XY}:\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}\rightarrow X\times Y$ be the natural morphism. Recall from § 4.5 that the composition

$$\begin{eqnarray}\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}\xrightarrow[{}]{~p_{XY}~}X\times Y\xrightarrow[{}]{\,f_{X}\times f_{Y}\,}\mathbf{G}\times \mathbf{G}^{\vee }\end{eqnarray}$$

factors through the incidence divisor $\mathbf{H}(\mathbf{G},\mathbf{G}^{\vee })$ . Hence there is a commutative diagram

(4.17)

where $\mathbf{H}(X,Y)$ is by definition the pullback of $\mathbf{H}(\mathbf{G},\mathbf{G}^{\vee })$ along $f_{X}\times f_{Y}$ , and $p_{XY}=j\circ p$ . We will need the following two lemmas.

Lemma 4.13. There is an isomorphism $p_{\ast }{\mathcal{O}}_{\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}}\cong {\mathcal{O}}_{\mathbf{H}(X,Y)}$ .

Proof. We have a diagram

where the square is Cartesian, and also $\operatorname{Tor}$ -independent as the fiber product has expected dimension by (4.8). To prove the lemma, we must show $(p_{X}\times p_{Y})_{\ast }(\widehat{\unicode[STIX]{x1D6E5}}_{\ast }{\mathcal{O}}_{\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}})\cong {\mathcal{O}}_{\mathbf{H}(X,Y)}$ . By $\operatorname{Tor}$ -independence, we have an isomorphism

$$\begin{eqnarray}\widehat{\unicode[STIX]{x1D6E5}}_{\ast }{\mathcal{O}}_{\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}}\cong (\unicode[STIX]{x1D70B}_{X}\times \unicode[STIX]{x1D70B}_{Y})^{\ast }\unicode[STIX]{x1D6E5}_{\ast }{\mathcal{O}}_{\mathbf{P}(S)}.\end{eqnarray}$$

Pulling back the standard resolution of the diagonal on $\mathbf{P}(S)\times \mathbf{P}(S)$ , we obtain an exact sequence

$$\begin{eqnarray}\displaystyle 0 & \rightarrow & \displaystyle \unicode[STIX]{x1D70B}_{X}^{\ast }{\mathcal{O}}_{\mathbf{P}(S)}(-3h)\boxtimes \unicode[STIX]{x1D70B}_{Y}^{\ast }\unicode[STIX]{x1D6FA}_{\mathbf{P}(S)}^{3}(3h)\rightarrow \unicode[STIX]{x1D70B}_{X}^{\ast }{\mathcal{O}}_{\mathbf{P}(S)}(-2h)\boxtimes \unicode[STIX]{x1D70B}_{Y}^{\ast }\unicode[STIX]{x1D6FA}_{\mathbf{P}(S)}^{2}(2h)\nonumber\\ \displaystyle & \rightarrow & \displaystyle \unicode[STIX]{x1D70B}_{X}^{\ast }{\mathcal{O}}_{\mathbf{P}(S)}(-h)\boxtimes \unicode[STIX]{x1D70B}_{Y}^{\ast }\unicode[STIX]{x1D6FA}_{\mathbf{P}(S)}^{1}(h)\rightarrow {\mathcal{O}}_{\widehat{X}\times \widehat{Y}}\rightarrow \widehat{\unicode[STIX]{x1D6E5}}_{\ast }{\mathcal{O}}_{\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}}\rightarrow 0\nonumber\end{eqnarray}$$

on $\widehat{X}\times \widehat{Y}$ . Using the identifications $p_{X}:\widehat{X}=\mathbf{P}_{X}({\mathcal{S}}_{X})\rightarrow X$ and $p_{Y}:\widehat{Y}=\mathbf{P}_{Y}({\mathcal{S}}_{Y})\rightarrow Y$ of Lemma 4.5, it is easy to compute:

$$\begin{eqnarray}\displaystyle p_{Y\ast }\unicode[STIX]{x1D70B}_{Y}^{\ast }\unicode[STIX]{x1D6FA}_{\mathbf{P}(S)}^{3}(3h) & \cong & \displaystyle p_{Y\ast }\unicode[STIX]{x1D70B}_{Y}^{\ast }{\mathcal{O}}(-h)=0,\nonumber\\ \displaystyle p_{X\ast }\unicode[STIX]{x1D70B}_{X}^{\ast }{\mathcal{O}}_{\mathbf{P}(S)}(-2h) & \cong & \displaystyle \det ({\mathcal{S}}_{X})[-1]\cong {\mathcal{O}}_{X}(-H)[-1],\nonumber\\ \displaystyle p_{Y\ast }\unicode[STIX]{x1D70B}_{Y}^{\ast }\unicode[STIX]{x1D6FA}_{\mathbf{P}(S)}^{2}(2h) & \cong & \displaystyle \det ({\mathcal{S}}_{Y})\cong {\mathcal{O}}_{Y}(-H^{\prime }),\nonumber\\ \displaystyle p_{X\ast }\unicode[STIX]{x1D70B}_{X}^{\ast }{\mathcal{O}}_{\mathbf{P}(S)}(-h) & = & \displaystyle 0,\nonumber\\ \displaystyle (p_{X}\times p_{Y})_{\ast }({\mathcal{O}}_{\widehat{X}\times \widehat{Y}}) & \cong & \displaystyle {\mathcal{O}}_{X\times Y}.\nonumber\end{eqnarray}$$

It follows that in the spectral sequence computing $(p_{X}\times p_{Y})_{\ast }(\widehat{\unicode[STIX]{x1D6E5}}_{\ast }{\mathcal{O}}_{\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}})$ from the above resolution, the only non-trivial terms are

$$\begin{eqnarray}\displaystyle \text{R}^{1}(p_{X}\times p_{Y})_{\ast }(\unicode[STIX]{x1D70B}_{X}^{\ast }{\mathcal{O}}(-2h)\boxtimes \unicode[STIX]{x1D70B}_{Y}^{\ast }\unicode[STIX]{x1D6FA}_{\mathbf{P}(S)}^{2}(2h)) & \cong & \displaystyle {\mathcal{O}}_{X\times Y}(-H-H^{\prime }),\nonumber\\ \displaystyle \text{R}^{0}(p_{X}\times p_{Y})_{\ast }({\mathcal{O}}_{\widehat{X}\times \widehat{Y}}) & \cong & \displaystyle {\mathcal{O}}_{X\times Y},\nonumber\end{eqnarray}$$

and we get an exact sequence

$$\begin{eqnarray}0\rightarrow {\mathcal{O}}_{X\times Y}(-H-H^{\prime })\rightarrow {\mathcal{O}}_{X\times Y}\rightarrow (p_{X}\times p_{Y})_{\ast }(\widehat{\unicode[STIX]{x1D6E5}}_{\ast }{\mathcal{O}}_{\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}})\rightarrow 0,\end{eqnarray}$$

which gives the required isomorphism $(p_{X}\times p_{Y})_{\ast }(\widehat{\unicode[STIX]{x1D6E5}}_{\ast }{\mathcal{O}}_{\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}})\cong {\mathcal{O}}_{\mathbf{H}(X,Y)}$ .◻

Lemma 4.14. The functor $\text{F}[-2]$ is given by a Fourier–Mukai kernel ${\mathcal{K}}\in \text{D}^{\text{b}}(X\times Y)$ , which fits into a distinguished triangle

$$\begin{eqnarray}{\mathcal{U}}_{X}(-H)\boxtimes {\mathcal{O}}_{Y}(-H^{\prime })\rightarrow {\mathcal{O}}_{X}(-H)\boxtimes {\mathcal{V}}_{Y}^{\vee }(-H^{\prime })\rightarrow {\mathcal{K}}.\end{eqnarray}$$

Proof. The main term in the definition (4.14) of $\text{F}$ is the left adjoint $\widehat{\unicode[STIX]{x1D6F7}}^{\ast }$ of $\widehat{\unicode[STIX]{x1D6F7}}$ . By definition $\widehat{\unicode[STIX]{x1D6F7}}$ is given by the Fourier–Mukai kernel $\widehat{{\mathcal{E}}}\in \text{D}^{\text{b}}(\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y})$ , so by Grothendieck duality we find that  $\widehat{\unicode[STIX]{x1D6F7}}^{\ast }$ is given by the kernel

$$\begin{eqnarray}\widehat{{\mathcal{E}}}^{\vee }\otimes \unicode[STIX]{x1D714}_{\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}/\widehat{Y}}[2]=\widehat{{\mathcal{E}}}^{\vee }(2h-H)[2]\in \text{D}^{\text{b}}(\widehat{X}\times _{\boldsymbol{ P}(S)}\widehat{Y}),\end{eqnarray}$$

where $\widehat{{\mathcal{E}}}^{\vee }=\text{R}{\mathcal{H}}\mathit{om}(\widehat{{\mathcal{E}}},{\mathcal{O}})$ is the derived dual of $\widehat{{\mathcal{E}}}$ on $\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}$ . Using this, it follows easily from the definition of $\text{F}$ that $\text{F}[-2]$ is given by the kernel

$$\begin{eqnarray}{\mathcal{K}}:=p_{XY\ast }(\widehat{{\mathcal{E}}}^{\vee })\in \text{D}^{\text{b}}(X\times Y).\end{eqnarray}$$

Using the diagram (4.17) and the definition of $\widehat{{\mathcal{E}}}$ , we can rewrite this as

$$\begin{eqnarray}\displaystyle {\mathcal{K}} & \cong & \displaystyle j_{\ast }p_{\ast }\text{R}{\mathcal{H}}\mathit{om}(p^{\ast }g^{\ast }{\mathcal{E}},{\mathcal{O}}_{\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}})\nonumber\\ \displaystyle & \cong & \displaystyle j_{\ast }\text{R}{\mathcal{H}}\mathit{om}(g^{\ast }{\mathcal{E}},p_{\ast }{\mathcal{O}}_{\widehat{X}\times _{\mathbf{P}(S)}\widehat{Y}})\nonumber\\ \displaystyle & \cong & \displaystyle j_{\ast }\text{R}{\mathcal{H}}\mathit{om}(g^{\ast }{\mathcal{E}},{\mathcal{O}}_{\mathbf{H}(X,Y)}),\nonumber\end{eqnarray}$$

where the second line holds by the local adjunction between $p^{\ast }$ and $p_{\ast }$ , and the third by Lemma 4.13. Now Grothendieck duality for the inclusion $j:\mathbf{H}(X,Y)\rightarrow X\times Y$ of the incidence divisor (which has class $H+H^{\prime }$ ) gives

$$\begin{eqnarray}{\mathcal{K}}\cong j_{\ast }\text{R}{\mathcal{H}}\mathit{om}(g^{\ast }{\mathcal{E}},j^{!}{\mathcal{O}}_{X\times Y}(-H-H^{\prime })[1])\cong \text{R}{\mathcal{H}}\mathit{om}(j_{\ast }g^{\ast }{\mathcal{E}},{\mathcal{O}}_{X\times Y}(-H-H^{\prime })[1]).\end{eqnarray}$$

On the other hand, the fiber square in diagram (4.17) is $\operatorname{Tor}$ -independent because $\mathbf{H}(X,Y)$ has expected dimension. Hence we have an isomorphism

$$\begin{eqnarray}j_{\ast }g^{\ast }{\mathcal{E}}\cong (f_{X}\times f_{Y})^{\ast }i_{\ast }{\mathcal{E}},\end{eqnarray}$$

and so, by the explicit resolution of $i_{\ast }{\mathcal{E}}$ from Theorem 4.8, a distinguished triangle

$$\begin{eqnarray}{\mathcal{O}}_{X}\boxtimes {\mathcal{V}}_{Y}\rightarrow {\mathcal{U}}_{X}^{\vee }\boxtimes {\mathcal{O}}_{Y}\rightarrow j_{\ast }g^{\ast }{\mathcal{E}}.\end{eqnarray}$$

Dualizing, twisting by ${\mathcal{O}}_{X\times Y}(-H-H^{\prime })$ , and rotating this triangle, we obtain a distinguished triangle

$$\begin{eqnarray}{\mathcal{U}}_{X}(-H)\boxtimes {\mathcal{O}}_{Y}(-H^{\prime })\rightarrow {\mathcal{O}}_{X}(-H)\boxtimes {\mathcal{V}}_{Y}^{\vee }(-H^{\prime })\rightarrow \text{R}{\mathcal{H}}\mathit{om}(j_{\ast }g^{\ast }{\mathcal{E}},{\mathcal{O}}_{X\times Y}(-H-H^{\prime })[1]),\end{eqnarray}$$

which combined with the above expression for ${\mathcal{K}}$ finishes the proof.◻

Finally, we prove Proposition 4.12.

Proof of Proposition 4.12.

By Lemma 4.14, it suffices to show the Fourier–Mukai functors with kernels

$$\begin{eqnarray}{\mathcal{U}}_{X}(-H)\boxtimes {\mathcal{O}}_{Y}(-H^{\prime })\quad \text{and}\quad {\mathcal{O}}_{X}(-H)\boxtimes {\mathcal{V}}_{Y}^{\vee }(-H^{\prime })\end{eqnarray}$$

vanish on ${\mathcal{A}}_{X}$ . This is equivalent to the vanishing

$$\begin{eqnarray}\text{H}^{\bullet }(X,{\mathcal{U}}_{X}(-H)\otimes {\mathcal{F}})=0\quad \text{and}\quad \text{H}^{\bullet }(X,{\mathcal{O}}_{X}(-H)\otimes {\mathcal{F}})=0\end{eqnarray}$$

for all ${\mathcal{F}}\in {\mathcal{A}}_{X}$ , which holds since ${\mathcal{A}}_{X}$ is right orthogonal to ${\mathcal{B}}_{X}(H)=\langle {\mathcal{O}}_{X}(H),{\mathcal{U}}_{X}^{\vee }(H)\rangle$ by definition (see (2.10) and (2.8)).◻

5 Cubic fourfold derived partners

In this section, we show that the K3 categories attached to GM and cubic fourfolds not only behave similarly, but sometimes even coincide. For this, we will consider ordinary GM fourfolds satisfying the following condition: there is a $3$ -dimensional subspace $V_{3}\subset V_{5}(X)$ such that

(5.1) $$\begin{eqnarray}\operatorname{Gr}(2,V_{3})\subset X.\end{eqnarray}$$

Remark 5.1. GM fourfolds that satisfy (5.1) for some $V_{3}$ form a $21$ -dimensional (codimension  $3$ in moduli) family. This can be seen using Theorem 3.1, as follows. Let $V_{6}=V_{6}(X)$ . Then by [Reference Debarre and KuznetsovDK17, Theorem 4.5(c)], for a $3$ -dimensional subspace $V_{3}\subset V_{6}$ condition (5.1) holds if and only if

(5.2) $$\begin{eqnarray}\dim (\mathsf{A}\cap ((\wedge ^{2}V_{3})\wedge V_{6}))\geqslant 4\quad \text{and}\quad \mathbf{p}_{X}\in \mathbf{P}(V_{3}^{\bot })\subset \mathbf{P}(V_{6}^{\vee }).\end{eqnarray}$$

By [Reference Iliev, Kapustka, Kapustka and RanestadIKKR16, Lemma 3.6] Lagrangian subspaces $\mathsf{A}\subset \wedge ^{3}V_{6}$ with no decomposable vectors such that the first part of (5.2) holds for some $V_{3}\subset V_{6}$ form a non-empty divisor in the moduli space of all $\mathsf{A}$ , and hence form a $19$ -dimensional family. Having fixed such an $\mathsf{A}$ there are finitely many points $V_{3}\in \operatorname{Gr}(3,V_{6})$ such that the first part of (5.2) holds (G. Kapustka and M. Kapustka, private communication 2016). By Theorem 3.1, for such a  $V_{3}$ , the ordinary GM fourfolds $X$ such that the second part of (5.2) holds are parameterized by  $\mathsf{Y}_{\mathsf{A}^{\bot }}^{1}\cap \mathbf{P}(V_{3}^{\bot })$ . By [Reference Debarre and KuznetsovDK17, Lemma 2.3] we have $\mathbf{P}(V_{3}^{\bot })\subset \mathsf{Y}_{\mathsf{A}^{\bot }}$ . Further, since  $\mathsf{Y}_{\mathsf{A}^{\bot }}^{{\geqslant}2}$ is an irreducible surface of degree 40, we have $\mathbf{P}(V_{3}^{\bot })\not \subset \mathsf{Y}_{\mathsf{A}^{\bot }}^{{\geqslant}2}$ . Thus $\mathsf{Y}_{\mathsf{A}^{\bot }}^{1}\cap \mathbf{P}(V_{3}^{\bot })$ is a non-empty open subset of the projective plane $\mathbf{P}(V_{3}^{\bot })$ .

From now on we write $V_{5}=V_{5}(X)$ and fix a $3$ -dimensional subspace $V_{3}\subset V_{5}$ such that (5.1) holds. We associate to $X$ a birational cubic fourfold  $X^{\prime }$ following [Reference Debarre, Iliev and ManivelDIM15, § 7.2]. Generically $X^{\prime }$ is smooth, and in this case we prove (Theorem 5.8) there is an equivalence ${\mathcal{A}}_{X}\simeq {\mathcal{A}}_{X^{\prime }}$ where ${\mathcal{A}}_{X^{\prime }}$ is the K3 category of the cubic fourfold defined by (3.1). The cubic $X^{\prime }$ is simply the image of the linear projection from the plane $\operatorname{Gr}(2,V_{3})$ in  $X$ . We begin by studying this projection as a map from the entire Grassmannian  $\mathbf{G}$ .

5.1 A linear projection of the Grassmannian

Set

$$\begin{eqnarray}P=\mathbf{P}(\wedge ^{2}V_{3})=\operatorname{Gr}(2,V_{3})\subset \mathbf{G}.\end{eqnarray}$$

Choose a complement $V_{2}$ to $V_{3}$ in $V_{5}$ , and set

$$\begin{eqnarray}B=\wedge ^{2}V_{5}/\wedge ^{2}V_{3}=\wedge ^{2}V_{2}\oplus (V_{2}\otimes V_{3}).\end{eqnarray}$$

Then the linear projection from $P$ gives a birational isomorphism from $\mathbf{G}$ to $\mathbf{P}(B)$ . Its structure can be described as follows.

Lemma 5.2. Let $p:\widetilde{\mathbf{G}}\rightarrow \mathbf{G}$ be the blowup with center in $P$ . Then the linear projection from $P$ induces a regular map $q:\widetilde{\mathbf{G}}\rightarrow \mathbf{P}(B)$ which identifies $\widetilde{\mathbf{G}}$ with the blowup of $\mathbf{P}(B)$ in the subvariety $\mathbf{P}(V_{2})\times \mathbf{P}(V_{3})\subset \mathbf{P}(V_{2}\otimes V_{3})\subset \mathbf{P}(B)$ . In other words, we have a diagram

(5.3)

where:

  • $E$ is the exceptional divisor of the blowup $p$ , and is mapped birationally by $q$ onto the hyperplane $\mathbf{P}(V_{2}\otimes V_{3})\subset \mathbf{P}(B)$ ;

  • $E^{\prime }$ is the exceptional divisor of the blowup $q$ , and is mapped birationally by $p$ onto the Schubert variety

    $$\begin{eqnarray}\unicode[STIX]{x1D6F4}=\{U\in \mathbf{G}~|~U\cap V_{3}\neq 0\}\subset \mathbf{G}.\end{eqnarray}$$

Proof. Straightforward. ◻

We denote by $H$ and $H^{\prime }$ the ample generators of $\operatorname{Pic}(\mathbf{G})$ and $\operatorname{Pic}(\mathbf{P}(B))$ .

Lemma 5.3. On $\widetilde{\mathbf{G}}$ we have the relations

(5.4) $$\begin{eqnarray}\left\{\begin{array}{@{}l@{}}H^{\prime }=H-E,\\ E^{\prime }=H-2E,\end{array}\right.\quad \text{or equivalently}\quad \left\{\begin{array}{@{}l@{}}H=2H^{\prime }-E^{\prime },\\ E=H^{\prime }-E^{\prime },\end{array}\right.\end{eqnarray}$$

as divisors modulo linear equivalence. Moreover, we have

(5.5) $$\begin{eqnarray}K_{\widetilde{\mathbf{G}}}=-5H+3E=-7H^{\prime }+2E^{\prime }.\end{eqnarray}$$

Proof. The equalities (5.5) follow from the standard formula for the canonical class of a blowup, and the equality $H^{\prime }=H-E$ holds by definition of $p$ . Using these, the other equalities in (5.4) follow directly (note that $\operatorname{Pic}(\widetilde{\mathbf{G}})\cong \mathbf{Z}^{2}$ is torsion free).◻

Later in this section we will need an expression for the vector bundle $p^{\ast }{\mathcal{U}}^{\vee }$ on $\widetilde{\mathbf{G}}$ in terms of the blowup $q$ . For this, we consider the composition

$$\begin{eqnarray}\displaystyle \unicode[STIX]{x1D719}:(V_{2}^{\vee }\oplus V_{3}^{\vee })\otimes {\mathcal{O}}_{\mathbf{P}(B)} & {\hookrightarrow} & \displaystyle V_{2}\otimes V_{2}^{\vee }\otimes (V_{2}^{\vee }\oplus V_{3}^{\vee })\otimes {\mathcal{O}}_{\mathbf{P}(B)}\nonumber\\ \displaystyle & \rightarrow & \displaystyle V_{2}\otimes (\wedge ^{2}V_{2}^{\vee }\oplus (V_{2}^{\vee }\otimes V_{3}^{\vee }))\otimes {\mathcal{O}}_{\mathbf{P}(B)}\rightarrow V_{2}\otimes {\mathcal{O}}_{\mathbf{P}(B)}(H^{\prime }),\nonumber\end{eqnarray}$$

where the first morphism is induced by the map $\mathbf{k}\rightarrow V_{2}\otimes V_{2}^{\vee }$ corresponding to the identity of $V_{2}$ , the second is induced by the map $V_{2}^{\vee }\otimes V_{2}^{\vee }\rightarrow \wedge ^{2}V_{2}^{\vee }$ , and the third is induced by the composition

$$\begin{eqnarray}(\wedge ^{2}V_{2}^{\vee }\oplus (V_{2}^{\vee }\otimes V_{3}^{\vee }))\otimes {\mathcal{O}}_{\boldsymbol{ P}(B)}=B^{\vee }\otimes {\mathcal{O}}_{\boldsymbol{ P}(B)}\rightarrow {\mathcal{O}}_{\mathbf{P}(B)}(H^{\prime }).\end{eqnarray}$$

Lemma 5.4. The cokernel of $\unicode[STIX]{x1D719}$ is the sheaf ${\mathcal{O}}_{\mathbf{P}(V_{2})\times \mathbf{P}(V_{3})}(2,1)$ .

Proof. Write

$$\begin{eqnarray}\displaystyle \unicode[STIX]{x1D719}^{\prime } & : & \displaystyle V_{2}^{\vee }\otimes {\mathcal{O}}_{\mathbf{P}(B)}\rightarrow V_{2}\otimes {\mathcal{O}}_{\mathbf{P}(B)}(H^{\prime }),\nonumber\\ \displaystyle \unicode[STIX]{x1D719}^{\prime \prime } & : & \displaystyle V_{3}^{\vee }\otimes {\mathcal{O}}_{\mathbf{P}(B)}\rightarrow V_{2}\otimes {\mathcal{O}}_{\mathbf{P}(B)}(H^{\prime }),\nonumber\end{eqnarray}$$

for the components of $\unicode[STIX]{x1D719}$ . The first component $\unicode[STIX]{x1D719}^{\prime }$ is an isomorphism away from the hyperplane $\mathbf{P}(V_{2}\otimes V_{3})\subset \mathbf{P}(B)$ , and zero on it. Hence $\text{coker}(\unicode[STIX]{x1D719}^{\prime })=V_{2}\otimes {\mathcal{O}}_{\mathbf{P}(V_{2}\otimes V_{3})}(H^{\prime })$ . It follows that the cokernel of $\unicode[STIX]{x1D719}$ coincides with the cokernel of the morphism

$$\begin{eqnarray}\unicode[STIX]{x1D719}_{|\mathbf{P}(V_{2}\otimes V_{3})}^{\prime \prime }:V_{3}^{\vee }\otimes {\mathcal{O}}_{\boldsymbol{ P}(V_{2}\otimes V_{3})}\rightarrow V_{2}\otimes {\mathcal{O}}_{\mathbf{P}(V_{2}\otimes V_{3})}(H^{\prime }).\end{eqnarray}$$

But the morphism $\unicode[STIX]{x1D719}_{|\mathbf{P}(V_{2}\otimes V_{3})}^{\prime \prime }$ is generically surjective with degeneracy locus the Segre subvariety $\mathbf{P}(V_{2})\times \mathbf{P}(V_{3})\subset \mathbf{P}(V_{2}\otimes V_{3})$ , and its restriction to this locus factors as the composition

$$\begin{eqnarray}V_{3}^{\vee }\otimes {\mathcal{O}}_{\boldsymbol{ P}(V_{2})\times \mathbf{P}(V_{3})}{\twoheadrightarrow}{\mathcal{O}}_{\mathbf{P}(V_{2})\times \mathbf{P}(V_{3})}(0,1){\hookrightarrow}V_{2}\otimes {\mathcal{O}}_{\mathbf{P}(V_{2})\times \mathbf{P}(V_{3})}(1,1)=V_{2}\otimes {\mathcal{O}}_{\mathbf{P}(V_{2})\times \mathbf{P}(V_{3})}(H^{\prime }).\end{eqnarray}$$

It follows that the cokernel of $\unicode[STIX]{x1D719}_{|\mathbf{P}(V_{2}\otimes V_{3})}^{\prime \prime }$ is isomorphic to ${\mathcal{O}}_{\mathbf{P}(V_{2})\times \mathbf{P}(V_{3})}(2,1)$ .◻

Let $F$ denote the class of a fiber of the natural projection $E^{\prime }\rightarrow \mathbf{P}(V_{2})\times \mathbf{P}(V_{3})\rightarrow \mathbf{P}(V_{2})$ .

Proposition 5.5. On $\widetilde{\mathbf{G}}$ there is an exact sequence

(5.6) $$\begin{eqnarray}0\rightarrow p^{\ast }{\mathcal{U}}^{\vee }\rightarrow V_{2}\otimes {\mathcal{O}}_{\widetilde{\mathbf{G}}}(H^{\prime })\rightarrow {\mathcal{O}}_{E^{\prime }}(H^{\prime }+F)\rightarrow 0.\end{eqnarray}$$

Proof. By Lemma 5.4, we have an exact sequence

$$\begin{eqnarray}V_{5}^{\vee }\otimes {\mathcal{O}}_{\boldsymbol{ P}(B)}\xrightarrow[{}]{\,\unicode[STIX]{x1D719}\,}V_{2}\otimes {\mathcal{O}}_{\mathbf{P}(B)}(H^{\prime })\rightarrow {\mathcal{O}}_{\boldsymbol{ P}(V_{2})\times \mathbf{P}(V_{3})}(2,1)\rightarrow 0.\end{eqnarray}$$

Pulling back to $\widetilde{\mathbf{G}}$ , we obtain an exact sequence

$$\begin{eqnarray}V_{5}^{\vee }\otimes {\mathcal{O}}_{\widetilde{\boldsymbol{ G}}}\rightarrow V_{2}\otimes {\mathcal{O}}_{\widetilde{\mathbf{G}}}(H^{\prime })\rightarrow {\mathcal{O}}_{E^{\prime }}(H^{\prime }+F)\rightarrow 0.\end{eqnarray}$$

Since $E^{\prime }$ is a divisor on $\widetilde{\mathbf{G}}$ , the kernel ${\mathcal{K}}$ of the epimorphism $V_{2}\otimes {\mathcal{O}}_{\widetilde{\mathbf{G}}}(H^{\prime })\rightarrow {\mathcal{O}}_{E^{\prime }}(H^{\prime }+F)$ is a rank $2$ vector bundle on  $\widetilde{\mathbf{G}}$ , which by the above exact sequence is a quotient of the trivial bundle $V_{5}^{\vee }\otimes {\mathcal{O}}_{\widetilde{\mathbf{G}}}$ . Hence ${\mathcal{K}}$ induces a morphism $\widetilde{\mathbf{G}}\rightarrow \mathbf{G}$ . This morphism can be checked to agree with the blowdown morphism  $p$ , so ${\mathcal{K}}\cong p^{\ast }{\mathcal{U}}^{\vee }$ .◻

5.2 Setup and statement of the result

Recall that $X$ is an ordinary GM fourfold containing the plane $P=\operatorname{Gr}(2,V_{3})$ . The following proposition describes the structure of the rational map from $X$ to $\mathbf{P}^{5}$ given by projection from  $P$ . We slightly abuse notation by using the same symbols for the exceptional divisors and blowup morphisms as in the above discussion of  $\mathbf{G}$ .

Proposition 5.6. Let $p:\widetilde{X}\rightarrow X$ be the blowup with center in $P$ . Then the linear projection from $P$ induces a regular map $q:\widetilde{X}\rightarrow X^{\prime }$ to a cubic fourfold $X^{\prime }$ containing a smooth cubic surface scroll  $T$ , and identifies $\widetilde{X}$ as the blowup of $X^{\prime }$ in $T$ . In other words, we have a diagram

where $p$ and $q$ are blowups with exceptional divisors $E$ and $E^{\prime }$ . Moreover, the relations (5.4) continue to hold on $\widetilde{X}$ , and

(5.7) $$\begin{eqnarray}K_{\widetilde{X}}=-2H+E=-3H^{\prime }+E^{\prime }.\end{eqnarray}$$

Finally, if $X$ does not contain planes of the form $\mathbf{P}(V_{1}\wedge V_{4})$ where $V_{1}\subset V_{3}\subset V_{4}\subset V_{5}$ , then  $X^{\prime }$ is smooth.

Proof. By § 2.1 there is a hyperplane $\mathbf{P}(W)\subset \mathbf{P}(\wedge ^{2}V_{5})$ and a quadric hypersurface $Q\subset \mathbf{P}(W)$ such that $X=\mathbf{G}\cap Q$ and $P\subset Q$ . Consider the subspace

$$\begin{eqnarray}C=W/\wedge ^{2}V_{3}\subset \wedge ^{2}V_{5}/\wedge ^{2}V_{3}=B,\end{eqnarray}$$

so that $\mathbf{P}(C)\subset \mathbf{P}(B)$ is a hyperplane. We claim that the corresponding hyperplane section

$$\begin{eqnarray}T=(\mathbf{P}(V_{2})\times \mathbf{P}(V_{3}))\cap \mathbf{P}(C)\end{eqnarray}$$

of $\mathbf{P}(V_{2})\,\times \,\mathbf{P}(V_{3})\subset \mathbf{P}(B)$ is a smooth cubic surface scroll. For this it is enough to show that  $\mathbf{P}(C)\,\cap \,\mathbf{P}(V_{2}\otimes V_{3})$ is a hyperplane in $\mathbf{P}(V_{2}\otimes V_{3})$ whose equation, considered as an element in $V_{2}^{\vee }\otimes V_{3}^{\vee }\cong \operatorname{Hom}(V_{3},V_{2}^{\vee })$ , has rank 2. Assume on the contrary that the rank of this equation is at most 1. Then its kernel is a subspace of $V_{3}$ of dimension at least 2, which is contained in the kernel of the skew form $\unicode[STIX]{x1D714}$ on $V_{5}$ defining $W$ . So the rank of $\unicode[STIX]{x1D714}$ is $2$ . But then the Grassmannian hull $M_{X}=\mathbf{G}\cap \mathbf{P}(W)$ of $X$ is singular along $\mathbf{P}^{2}=\operatorname{Gr}(2,\ker (\unicode[STIX]{x1D714}))$ , and  $X$ is singular along $\mathbf{P}^{2}\cap Q$ . This contradiction proves the claim.

The proper transform of the Grassmannian hull $M=M_{X}$ under $p:\widetilde{\mathbf{G}}\rightarrow \mathbf{G}$ coincides with the proper transform of $\mathbf{P}(C)$ under $q:\widetilde{\mathbf{G}}\rightarrow \mathbf{P}(B)$ . Thus if $\widetilde{M}=\operatorname{Bl}_{P}(M)\rightarrow M$ is the blowup in  $P$ , then projection from $P$ gives an identification $\widetilde{M}\cong \operatorname{Bl}_{T}(\mathbf{P}(C))\rightarrow \mathbf{P}(C)$ . Further, the proper transform of $X=M\cap Q$ under $\widetilde{M}\rightarrow M$ is cut out by a section of the line bundle

(5.8) $$\begin{eqnarray}{\mathcal{O}}_{\widetilde{M}}(2H-E)={\mathcal{O}}_{\widetilde{M}}(3H^{\prime }-E^{\prime }),\end{eqnarray}$$

and therefore coincides with the proper transform under the morphism $\widetilde{M}\rightarrow \mathbf{P}(C)$ of a cubic fourfold $X^{\prime }\subset \mathbf{P}(C)$  containing  $T$ . This proves the first part of the lemma.

The relations (5.4) clearly restrict to $\widetilde{X}$ , and the equalities (5.7) follow from the standard formula for the canonical class of a blowup.

It remains to show that $X^{\prime }$ is smooth if $X$ does not contain planes of the form $\mathbf{P}(V_{1}\wedge V_{4})$ where $V_{1}\subset V_{3}\subset V_{4}\subset V_{5}$ . For this, first note that the blowup of $X^{\prime }$ in $T$ is smooth, since it coincides with the blowup of $X$ in $P$ . Therefore, $X^{\prime }$ is smooth away from $T$ . On the other hand, $T$ is also smooth, so it is enough to check that $T\subset X^{\prime }$ is a locally complete intersection, i.e. that its conormal sheaf is locally free. Since $E^{\prime }\rightarrow T$ is the exceptional divisor of the blowup of $X^{\prime }$ in  $T$ , it is enough to check that the map $E^{\prime }\rightarrow T$ is a $\mathbf{P}^{1}$ -bundle. Since by (5.8) $E^{\prime }$ is cut out in the exceptional divisor of (5.3) by fiberwise linear conditions, it is enough to show that there are no points in $T\subset \mathbf{P}(V_{2})\times \mathbf{P}(V_{3})$ over which the fiber of $E^{\prime }$ is isomorphic to $\mathbf{P}^{2}$ . But such a point would correspond to a choice of a $V_{1}\subset V_{3}$ (giving a point in $\mathbf{P}(V_{3})$ ) and $V_{3}\subset V_{4}$ (giving a point of $\mathbf{P}(V_{5}/V_{3})=\mathbf{P}(V_{2})$ ), such that the plane $\mathbf{P}(V_{1}\wedge V_{4})$ is in  $X$ . Since we assumed there are no such planes in  $X$ , we conclude that $X^{\prime }$ is smooth.◻

The condition guaranteeing smoothness of $X^{\prime }$ in the final statement of Proposition 5.6 holds generically.

Lemma 5.7. If $X$ is a general ordinary GM fourfold containing $P=\operatorname{Gr}(2,V_{3})$ for some $V_{3}\subset V_{5}$ , then $X$ does not contain planes of the form $\mathbf{P}(V_{1}\wedge V_{4})$ where $V_{1}\subset V_{3}\subset V_{4}\subset V_{5}$ .

Proof. By Theorem 3.1, an ordinary GM fourfold $X$ corresponds to a pair $(\mathsf{A},\mathbf{p})$ such that  $\mathsf{A}$ has no decomposable vectors and $\mathbf{p}\in \mathsf{Y}_{\mathsf{A}^{\bot }}^{1}$ . By Remark 5.1, $X$ contains the plane $\operatorname{Gr}(2,V_{3})$ if and only if (5.2) holds. Similarly, by [Reference Debarre and KuznetsovDK17, Theorem 4.3(c)], $X$ contains a plane $\mathbf{P}(V_{1}\wedge V_{4})$ if and only if $\mathsf{Y}_{\mathsf{A}}^{3}\cap \mathbf{P}(V_{5})\neq \varnothing$ .

By [Reference Iliev, Kapustka, Kapustka and RanestadIKKR16, Lemma 3.6] Lagrangians $\mathsf{A}\subset \wedge ^{3}V_{6}$ with no decomposable vectors such that there is $V_{3}\subset V_{6}$ for which the first part of (5.2) holds are parameterized by an open subset of a divisor $\unicode[STIX]{x1D6E4}\subset \operatorname{LG}(10,\wedge ^{3}V_{6})$ , and by [Reference Iliev, Kapustka, Kapustka and RanestadIKKR16, Lemma 3.7] this divisor has no common components with the divisor $\unicode[STIX]{x1D6E5}\subset \operatorname{LG}(10,\wedge ^{3}V_{6})$ parameterizing  $\mathsf{A}$ such that $\mathsf{Y}_{\mathsf{A}}^{3}\neq \varnothing$ . Choose any $\mathsf{A}$ with no decomposable vectors such that there is $V_{3}\subset V_{6}$ for which the first part of (5.2) holds, but $\mathsf{Y}_{\mathsf{A}}^{3}=\varnothing$ . Then as explained in Remark 5.1, there is a 2-dimensional family of ordinary GM fourfolds containing $\operatorname{Gr}(2,V_{3})$ ; none of these contain a plane of the form $\mathbf{P}(V_{1}\wedge V_{4})$ since  $\mathsf{Y}_{\mathsf{A}}^{3}=\varnothing$ .◻

Our goal is to prove the following result.

Theorem 5.8. Assume the cubic fourfold $X^{\prime }$ associated to $X$ by Proposition 5.6 is smooth. Then there is an equivalence ${\mathcal{A}}_{X}\simeq {\mathcal{A}}_{X^{\prime }}$ , where ${\mathcal{A}}_{X}$ is the GM category defined by (2.11) and  ${\mathcal{A}}_{X^{\prime }}$ is defined by (3.1).

Remark 5.9. Theorem 5.8 is of an essentially different nature than Theorem 4.1, in that it does not ‘come from’ K3 surfaces. More precisely, for a very general GM fourfold $X$ satisfying (5.1) for some $V_{3}$ , the category ${\mathcal{A}}_{X}$ is not equivalent to the derived category of a K3 surface, or even a twisted K3 surface. Indeed, the construction of Proposition 5.6 dominates the locus of cubic fourfolds containing a smooth cubic surface scroll, so it suffices to prove that given a very general such cubic, its K3 category is not equivalent to the twisted derived category of a K3 surface. Since cubic fourfolds containing a cubic scroll have discriminant $12$ by [Reference HassettHas00, Example 4.1.2], this follows from [Reference HuybrechtsHuy17, Theorem 1.4].

5.3 Strategy of the proof

From now on, we assume the hypothesis of Theorem 5.8 is satisfied. The proof of this theorem occupies the rest of this section. Here is our strategy.

By Orlov’s decomposition of the derived category of a blowup, we have

$$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle p^{\ast }\text{D}^{\text{b}}(X),i_{\ast }p_{E}^{\ast }\text{D}^{\text{b}}(P)\rangle .\end{eqnarray}$$

Inserting (2.11) and the standard decomposition of $\text{D}^{\text{b}}(P)$ into the above decomposition, we obtain

(5.9) $$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle p^{\ast }{\mathcal{A}}_{X},{\mathcal{O}},{\mathcal{U}}^{\vee },{\mathcal{O}}(H),{\mathcal{U}}^{\vee }(H),{\mathcal{O}}_{E},{\mathcal{O}}_{E}(H),{\mathcal{O}}_{E}(2H)\rangle .\end{eqnarray}$$

Here and below, to ease notation we write ${\mathcal{U}}^{\vee }$ for $p^{\ast }{\mathcal{U}}_{X}^{\vee }$ . This decomposition of $\text{D}^{\text{b}}(\widetilde{X})$ consists of a copy of ${\mathcal{A}}_{X}$ and $7$ exceptional objects.

On the other hand, from the expression of $\widetilde{X}$ as a blowup of $X^{\prime }$ , we have

$$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle q^{\ast }\text{D}^{\text{b}}(X^{\prime }),j_{\ast }q_{E^{\prime }}^{\ast }\text{D}^{\text{b}}(T)\rangle .\end{eqnarray}$$

Inserting the decomposition (3.1) for $\text{D}^{\text{b}}(X^{\prime })$ , we obtain

(5.10) $$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle q^{\ast }{\mathcal{A}}_{X^{\prime }},{\mathcal{O}},{\mathcal{O}}(H^{\prime }),{\mathcal{O}}(2H^{\prime }),j_{\ast }q_{E^{\prime }}^{\ast }\text{D}^{\text{b}}(T)\rangle .\end{eqnarray}$$

Note that $\text{D}^{\text{b}}(T)$ has a decomposition consisting of $4$ exceptional objects, hence the decomposition (5.10) consists of one copy of ${\mathcal{A}}_{X^{\prime }}$ and again $7$ exceptional objects.

To prove the equivalence ${\mathcal{A}}_{X}\simeq {\mathcal{A}}_{X^{\prime }}$ , we will find a sequence of mutations transforming the exceptional objects of (5.9) into those of (5.10). In doing so, we will explicitly identify a functor giving the desired equivalence, see (5.15).

5.4 Mutations

We perform a sequence of mutations, starting with (5.9). For a brief review of mutation functors and references, see the discussion in § 2.8.

Step 1. Mutate ${\mathcal{U}}^{\vee }(H)$ to the far left in (5.9). Since this is a mutation in $\text{D}^{\text{b}}(X)$ and since we have $K_{X}=-2H$ , by (2.19) the result is

$$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle {\mathcal{U}}^{\vee }(-H),p^{\ast }{\mathcal{A}}_{X},{\mathcal{O}},{\mathcal{U}}^{\vee },{\mathcal{O}}(H),{\mathcal{O}}_{E},{\mathcal{O}}_{E}(H),{\mathcal{O}}_{E}(2H)\rangle .\end{eqnarray}$$

Step 2. Mutate ${\mathcal{U}}^{\vee }(-H)$ to the far right. Again by (2.19) and (5.7), the result is

$$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle p^{\ast }{\mathcal{A}}_{X},{\mathcal{O}},{\mathcal{U}}^{\vee },{\mathcal{O}}(H),{\mathcal{O}}_{E},{\mathcal{O}}_{E}(H),{\mathcal{O}}_{E}(2H),{\mathcal{U}}^{\vee }(H-E)\rangle .\end{eqnarray}$$

Step 3. Left mutate ${\mathcal{O}}_{E}$ through $\langle {\mathcal{O}},{\mathcal{U}}^{\vee },{\mathcal{O}}(H)\rangle$ . We have

$$\begin{eqnarray}\displaystyle \operatorname{Ext}^{\bullet }({\mathcal{O}}(H),{\mathcal{O}}_{E}) & = & \displaystyle \text{H}^{\bullet }(P,{\mathcal{O}}_{P}(-H))=0,\nonumber\\ \displaystyle \operatorname{Ext}^{\bullet }({\mathcal{U}}^{\vee },{\mathcal{O}}_{E}) & = & \displaystyle \text{H}^{\bullet }(P,{\mathcal{U}}_{P})=0,\nonumber\\ \displaystyle \operatorname{Ext}^{\bullet }({\mathcal{O}},{\mathcal{O}}_{E}) & = & \displaystyle \text{H}^{\bullet }(P,{\mathcal{O}}_{P})=\mathbf{k},\nonumber\end{eqnarray}$$

where in the second line ${\mathcal{U}}_{P}$ is the tautological rank $2$ bundle on $P=\operatorname{Gr}(2,V_{3})$ , i.e. the restriction of ${\mathcal{U}}$ from $\mathbf{G}$ to $P$ . Hence by the definition of the mutation functor

$$\begin{eqnarray}\text{L}_{\langle {\mathcal{O}},{\mathcal{U}}^{\vee },{\mathcal{O}}(H)\rangle }({\mathcal{O}}_{E})=\operatorname{Cone}({\mathcal{O}}\rightarrow {\mathcal{O}}_{E})={\mathcal{O}}(-E)[1],\end{eqnarray}$$

and the resulting decomposition is

$$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle p^{\ast }{\mathcal{A}}_{X},{\mathcal{O}}(-E),{\mathcal{O}},{\mathcal{U}}^{\vee },{\mathcal{O}}(H),{\mathcal{O}}_{E}(H),{\mathcal{O}}_{E}(2H),{\mathcal{U}}^{\vee }(H-E)\rangle .\end{eqnarray}$$

Step 4. Left mutate ${\mathcal{O}}_{E}(2H)$ through $\langle {\mathcal{O}},{\mathcal{U}}^{\vee },{\mathcal{O}}(H),{\mathcal{O}}_{E}(H)\rangle$ .

Lemma 5.10. We have $\text{L}_{\langle {\mathcal{O}},{\mathcal{U}}^{\vee },{\mathcal{O}}(H),{\mathcal{O}}_{E}(H)\rangle }({\mathcal{O}}_{E}(2H))\cong {\mathcal{O}}_{E^{\prime }}(E^{\prime }-F)[2]$ .

Proof. There is an isomorphism of functors

$$\begin{eqnarray}\text{L}_{\langle {\mathcal{O}},{\mathcal{U}}^{\vee },{\mathcal{O}}(H),{\mathcal{O}}_{E}(H)\rangle }\cong \text{L}_{{\mathcal{O}}}\circ \text{L}_{{\mathcal{U}}^{\vee }}\circ \text{L}_{{\mathcal{O}}(H)}\circ \text{L}_{{\mathcal{O}}_{E}(H)}.\end{eqnarray}$$

Hence to prove the result we successively left mutate ${\mathcal{O}}_{E}(2H)$ through ${\mathcal{O}}_{E}(H),{\mathcal{O}}(H),{\mathcal{U}}^{\vee },{\mathcal{O}}$ .

To compute $\text{L}_{{\mathcal{O}}_{E}(H)}({\mathcal{O}}_{E}(2H))$ , we may compute $\text{L}_{{\mathcal{O}}_{P}(H)}({\mathcal{O}}_{P}(2H))$ and pull back the result. We have $\operatorname{Ext}^{\bullet }({\mathcal{O}}_{P}(H),{\mathcal{O}}_{P}(2H))=\text{H}^{\bullet }(P,{\mathcal{O}}_{P}(H))=V_{3}$ , so

$$\begin{eqnarray}\text{L}_{{\mathcal{O}}_{P}(H)}({\mathcal{O}}_{P}(2H))=\operatorname{Cone}({\mathcal{O}}_{P}(H)\otimes V_{3}\rightarrow {\mathcal{O}}_{P}(2H)).\end{eqnarray}$$

The morphism ${\mathcal{O}}_{P}(H)\otimes V_{3}\rightarrow {\mathcal{O}}_{P}(2H)$ is the twist by $H$ of the tautological morphism, hence it is surjective with kernel ${\mathcal{U}}_{P}(H)\cong {\mathcal{U}}_{P}^{\vee }$ . Thus the above cone is ${\mathcal{U}}_{P}^{\vee }[1]$ , and

$$\begin{eqnarray}\text{L}_{{\mathcal{O}}_{E}(H)}({\mathcal{O}}_{E}(2H))={\mathcal{U}}_{E}^{\vee }[1].\end{eqnarray}$$

Next note $\operatorname{Ext}^{\bullet }({\mathcal{O}}(H),{\mathcal{U}}_{E}^{\vee })=\text{H}^{\bullet }(P,{\mathcal{U}}_{P}^{\vee }(-H))=0$ , hence

$$\begin{eqnarray}\text{L}_{{\mathcal{O}}(H)}({\mathcal{U}}_{E}^{\vee })={\mathcal{U}}_{E}^{\vee }.\end{eqnarray}$$

Further, we have $\operatorname{Ext}^{\bullet }({\mathcal{U}}^{\vee },{\mathcal{U}}_{E}^{\vee })=\text{H}^{\bullet }(P,{\mathcal{U}}_{P}\otimes {\mathcal{U}}_{P}^{\vee })=\mathbf{k}$ , hence

$$\begin{eqnarray}\text{L}_{{\mathcal{U}}^{\vee }}({\mathcal{U}}_{E}^{\vee })=\operatorname{Cone}({\mathcal{U}}^{\vee }\rightarrow {\mathcal{U}}_{E}^{\vee })={\mathcal{U}}^{\vee }(-E)[1].\end{eqnarray}$$

Now we are left with the last and most interesting step: the mutation of ${\mathcal{U}}^{\vee }(-E)$ through  ${\mathcal{O}}$ . First, using the exact sequence

$$\begin{eqnarray}0\rightarrow {\mathcal{O}}(-E)\rightarrow {\mathcal{O}}\rightarrow {\mathcal{O}}_{E}\rightarrow 0\end{eqnarray}$$

tensored by ${\mathcal{U}}^{\vee }$ , we find

(5.11) $$\begin{eqnarray}\operatorname{Ext}^{\bullet }({\mathcal{O}},{\mathcal{U}}^{\vee }(-E))=\text{H}^{\bullet }(\widetilde{X},{\mathcal{U}}^{\vee }(-E))=\ker (V_{5}^{\vee }\rightarrow V_{3}^{\vee })=V_{2}^{\vee }.\end{eqnarray}$$

Thus we need to understand the cone of the natural morphism $V_{2}^{\vee }\otimes {\mathcal{O}}\rightarrow {\mathcal{U}}^{\vee }(-E)$ . Restricting (5.6) to $\widetilde{X}$ , dualizing, twisting by $H^{\prime }=H-E$ , and using the isomorphism ${\mathcal{U}}(H)\cong {\mathcal{U}}^{\vee }$ , we obtain a distinguished triangle

$$\begin{eqnarray}V_{2}^{\vee }\otimes {\mathcal{O}}\rightarrow {\mathcal{U}}^{\vee }(-E)\rightarrow {\mathcal{O}}_{E^{\prime }}(E^{\prime }-F).\end{eqnarray}$$

Thus

(5.12) $$\begin{eqnarray}\text{L}_{{\mathcal{O}}}({\mathcal{U}}^{\vee }(-E))={\mathcal{O}}_{E^{\prime }}(E^{\prime }-F),\end{eqnarray}$$

which completes the proof of the lemma. ◻

By the lemma, the result of the above mutation is

$$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle p^{\ast }{\mathcal{A}}_{X},{\mathcal{O}}(-E),{\mathcal{O}}_{E^{\prime }}(E^{\prime }-F),{\mathcal{O}},{\mathcal{U}}^{\vee },{\mathcal{O}}(H),{\mathcal{O}}_{E}(H),{\mathcal{U}}^{\vee }(H-E)\rangle .\end{eqnarray}$$

Step 5. Left mutate ${\mathcal{O}}_{E}(H)$ through ${\mathcal{O}}(H)$ . We have

$$\begin{eqnarray}\text{L}_{{\mathcal{O}}(H)}({\mathcal{O}}_{E}(H))=\operatorname{Cone}({\mathcal{O}}(H)\rightarrow {\mathcal{O}}_{E}(H))={\mathcal{O}}(H-E)[1]={\mathcal{O}}(H^{\prime })[1],\end{eqnarray}$$

so the result is

$$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle p^{\ast }{\mathcal{A}}_{X},{\mathcal{O}}(-E),{\mathcal{O}}_{E^{\prime }}(E^{\prime }-F),{\mathcal{O}},{\mathcal{U}}^{\vee },{\mathcal{O}}(H^{\prime }),{\mathcal{O}}(H),{\mathcal{U}}^{\vee }(H-E)\rangle .\end{eqnarray}$$

Step 6. Right mutate ${\mathcal{U}}^{\vee }$ through ${\mathcal{O}}(H^{\prime })$ . We have

$$\begin{eqnarray}\operatorname{Ext}^{\bullet }({\mathcal{U}}^{\vee },{\mathcal{O}}(H^{\prime }))=\operatorname{Ext}^{\bullet }({\mathcal{O}},{\mathcal{U}}(H-E))=\operatorname{Ext}^{\bullet }({\mathcal{O}},{\mathcal{U}}^{\vee }(-E))=V_{2}^{\vee },\end{eqnarray}$$

where the last equality holds by (5.11). Hence

$$\begin{eqnarray}\text{R}_{{\mathcal{O}}(H^{\prime })}({\mathcal{U}}^{\vee })=\operatorname{Cone}({\mathcal{U}}^{\vee }\rightarrow V_{2}\otimes {\mathcal{O}}(H^{\prime }))[-1].\end{eqnarray}$$

Now restricting (5.6) to $\widetilde{X}$ shows $\text{R}_{{\mathcal{O}}(H^{\prime })}({\mathcal{U}}^{\vee })={\mathcal{O}}_{E^{\prime }}(H^{\prime }\,+\,F)[-1]$ . Thus under the above mutation our decomposition becomes

$$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle p^{\ast }{\mathcal{A}}_{X},{\mathcal{O}}(-E),{\mathcal{O}}_{E^{\prime }}(E^{\prime }-F),{\mathcal{O}},{\mathcal{O}}(H^{\prime }),{\mathcal{O}}_{E^{\prime }}(H^{\prime }+F),{\mathcal{O}}(H),{\mathcal{U}}^{\vee }(H-E)\rangle .\end{eqnarray}$$

Step 7. Left mutate ${\mathcal{U}}^{\vee }(H-E)$ through ${\mathcal{O}}(H)$ . By (5.12) and (4.12) we have

$$\begin{eqnarray}\text{L}_{{\mathcal{O}}(H)}({\mathcal{U}}^{\vee }(H-E))={\mathcal{O}}_{E^{\prime }}(H+E^{\prime }-F)={\mathcal{O}}_{E^{\prime }}(2H^{\prime }-F),\end{eqnarray}$$

so the result is

$$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle p^{\ast }{\mathcal{A}}_{X},{\mathcal{O}}(-E),{\mathcal{O}}_{E^{\prime }}(E^{\prime }-F),{\mathcal{O}},{\mathcal{O}}(H^{\prime }),{\mathcal{O}}_{E^{\prime }}(H^{\prime }+F),{\mathcal{O}}_{E^{\prime }}(2H^{\prime }-F),{\mathcal{O}}(H)\rangle .\end{eqnarray}$$

Step 8. Right mutate $p^{\ast }{\mathcal{A}}_{X}$ through $\langle {\mathcal{O}}(-E),{\mathcal{O}}_{E^{\prime }}(E^{\prime }-F)\rangle$ . The result is

$$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle {\mathcal{O}}(-E),{\mathcal{O}}_{E^{\prime }}(E^{\prime }-F),\unicode[STIX]{x1D6F9}p^{\ast }{\mathcal{A}}_{X},{\mathcal{O}},{\mathcal{O}}(H^{\prime }),{\mathcal{O}}_{E^{\prime }}(H^{\prime }+F),{\mathcal{O}}_{E^{\prime }}(2H^{\prime }-F),{\mathcal{O}}(H)\rangle ,\end{eqnarray}$$

where $\unicode[STIX]{x1D6F9}=\text{R}_{\langle {\mathcal{O}}(-E),{\mathcal{O}}_{E^{\prime }}(E^{\prime }-F)\rangle }$ .

Step 9. Mutate $\langle {\mathcal{O}}(-E),{\mathcal{O}}_{E^{\prime }}(E^{\prime }-F)\rangle$ to the far right. By (2.19), the result is

$$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle \unicode[STIX]{x1D6F9}p^{\ast }{\mathcal{A}}_{X},{\mathcal{O}},{\mathcal{O}}(H^{\prime }),{\mathcal{O}}_{E^{\prime }}(H^{\prime }+F),{\mathcal{O}}_{E^{\prime }}(2H^{\prime }-F),{\mathcal{O}}(H),{\mathcal{O}}(2H^{\prime }),{\mathcal{O}}_{E^{\prime }}(3H^{\prime }-F)\rangle .\end{eqnarray}$$

Step 10. Right mutate ${\mathcal{O}}(H)$ through ${\mathcal{O}}(2H^{\prime })$ . We have

$$\begin{eqnarray}\operatorname{Ext}^{\bullet }({\mathcal{O}}(H),{\mathcal{O}}(2H^{\prime }))=\text{H}^{\bullet }(\widetilde{X},{\mathcal{O}}(E^{\prime }))=\mathbf{k}\end{eqnarray}$$

and hence

$$\begin{eqnarray}\text{R}_{{\mathcal{O}}(2H^{\prime })}({\mathcal{O}}(H))=\operatorname{Cone}({\mathcal{O}}(H)\rightarrow {\mathcal{O}}(2H^{\prime }))[-1].\end{eqnarray}$$

The morphism ${\mathcal{O}}(H)\rightarrow {\mathcal{O}}(2H^{\prime })$ is the twist by $2H^{\prime }$ of ${\mathcal{O}}(-E^{\prime })\rightarrow {\mathcal{O}}$ , hence

$$\begin{eqnarray}\text{R}_{{\mathcal{O}}(2H^{\prime })}({\mathcal{O}}(H))={\mathcal{O}}_{E^{\prime }}(2H^{\prime })[-1].\end{eqnarray}$$

Thus the result of the mutation is a decomposition

$$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle \unicode[STIX]{x1D6F9}p^{\ast }{\mathcal{A}}_{X},{\mathcal{O}},{\mathcal{O}}(H^{\prime }),{\mathcal{O}}_{E^{\prime }}(H^{\prime }+F),{\mathcal{O}}_{E^{\prime }}(2H^{\prime }-F),{\mathcal{O}}(2H^{\prime }),{\mathcal{O}}_{E^{\prime }}(2H^{\prime }),{\mathcal{O}}_{E^{\prime }}(3H^{\prime }-F)\rangle .\end{eqnarray}$$

Step 11. Left mutate ${\mathcal{O}}(2H^{\prime })$ through $\langle {\mathcal{O}}_{E^{\prime }}(H^{\prime }+F),{\mathcal{O}}_{E^{\prime }}(2H^{\prime }-F)\rangle$ . By the semiorthogonality of $q^{\ast }\text{D}^{\text{b}}(X^{\prime })$ and $j_{\ast }q_{E^{\prime }}^{\ast }\text{D}^{\text{b}}(T)$ in $\text{D}^{\text{b}}(\widetilde{X})$ , this mutation is just a transposition. Thus the result is

$$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle \unicode[STIX]{x1D6F9}p^{\ast }{\mathcal{A}}_{X},{\mathcal{O}},{\mathcal{O}}(H^{\prime }),{\mathcal{O}}(2H^{\prime }),{\mathcal{O}}_{E^{\prime }}(H^{\prime }+F),{\mathcal{O}}_{E^{\prime }}(2H^{\prime }-F),{\mathcal{O}}_{E^{\prime }}(2H^{\prime }),{\mathcal{O}}_{E^{\prime }}(3H^{\prime }-F)\rangle .\end{eqnarray}$$

It is straightforward to check that

$$\begin{eqnarray}\text{D}^{\text{b}}(T)=\langle {\mathcal{O}}_{T}(H^{\prime }+F),{\mathcal{O}}_{T}(2H^{\prime }-F),{\mathcal{O}}_{T}(2H^{\prime }),{\mathcal{O}}_{T}(3H^{\prime }-F)\rangle ,\end{eqnarray}$$

so the above decomposition can be written as

(5.13) $$\begin{eqnarray}\text{D}^{\text{b}}(\widetilde{X})=\langle \unicode[STIX]{x1D6F9}p^{\ast }{\mathcal{A}}_{X},{\mathcal{O}},{\mathcal{O}}(H^{\prime }),{\mathcal{O}}(2H^{\prime }),j_{\ast }q_{E^{\prime }}^{\ast }\text{D}^{\text{b}}(T)\rangle .\end{eqnarray}$$

This completes the proof of Theorem 5.8. Indeed, comparing the decompositions (5.13) and (5.10) shows

(5.14) $$\begin{eqnarray}q_{\ast }\circ \text{R}_{\langle {\mathcal{O}}_{\widetilde{X}}(-E),{\mathcal{O}}_{E^{\prime }}(E^{\prime }-F)\rangle }\circ p^{\ast }:{\mathcal{A}}_{X}\rightarrow {\mathcal{A}}_{X^{\prime }}\end{eqnarray}$$

is an equivalence. ◻

Remark 5.11. The functor (5.14) is in fact isomorphic to

(5.15) $$\begin{eqnarray}q_{\ast }\circ \text{R}_{{\mathcal{O}}_{\widetilde{X}}(-E)}\circ p^{\ast }:{\mathcal{A}}_{X}\rightarrow {\mathcal{A}}_{X^{\prime }}.\end{eqnarray}$$

To see this, observe that $q_{\ast }$ kills ${\mathcal{O}}_{E^{\prime }}(E^{\prime }-F)$ : if $j_{0}:T{\hookrightarrow}X^{\prime }$ denotes the inclusion, then

$$\begin{eqnarray}q_{\ast }({\mathcal{O}}_{E^{\prime }}(E^{\prime }-F))=j_{0\ast }q_{E^{\prime }\ast }({\mathcal{O}}_{E^{\prime }}(E^{\prime }-F))=j_{0\ast }(q_{E^{\prime }\ast }({\mathcal{O}}_{E^{\prime }}(E^{\prime }))\otimes {\mathcal{O}}_{T}(F))=0\end{eqnarray}$$

since $q_{E^{\prime }\ast }({\mathcal{O}}_{E^{\prime }}(E^{\prime }))=0$ . Thus $q_{\ast }\circ \text{R}_{{\mathcal{O}}_{E^{\prime }}(E^{\prime }-F)}\cong q_{\ast }$ , and the claim follows since there is an isomorphism of functors $\text{R}_{\langle {\mathcal{O}}_{\widetilde{X}}(-E),{\mathcal{O}}_{E^{\prime }}(E^{\prime }-F)\rangle }\cong \text{R}_{{\mathcal{O}}_{E^{\prime }}(E^{\prime }-F)}\circ \text{R}_{{\mathcal{O}}_{\widetilde{X}}(-E)}$ .

Acknowledgements

We would like to thank Olivier Debarre, Joe Harris, and Johan de Jong for many useful discussions. We are also grateful to Daniel Huybrechts, Richard Thomas, and Ravi Vakil for comments and questions. Finally, we thank the referee for suggestions about the presentation of the paper.

Appendix A Moduli of GM varieties

Let $(\text{Sch}/\mathbf{k})$ denote the category of $\mathbf{k}$ -schemes.

Definition A.1. For $2\leqslant n\leqslant 6$ , the moduli stack ${\mathcal{M}}_{n}$ of smooth $n$ -dimensional GM varieties is the fibered category over $(\text{Sch}/\mathbf{k})$ whose fiber over a scheme $S\in (\text{Sch}/\mathbf{k})$ is the groupoid of pairs $(\unicode[STIX]{x1D70B}:X\rightarrow S,{\mathcal{L}})$ , where $\unicode[STIX]{x1D70B}:X\rightarrow S$ is a smooth proper morphism of schemes and ${\mathcal{L}}\in \operatorname{Pic}_{X/S}(S)$ , such that for every geometric point $\bar{s}\in S$ the pair $(X_{\bar{s}},{\mathcal{L}}_{\bar{s}})$ is isomorphic to a smooth $n$ -dimensional GM variety with its natural polarization (equivalently, $(X_{\bar{s}},{\mathcal{L}}_{\bar{s}})$ satisfies conditions (2.3) and (2.2) with $H$ the divisor corresponding to ${\mathcal{L}}_{\bar{s}}$ ). Here, $\operatorname{Pic}_{X/S}$ denotes the relative Picard functor of  $X\rightarrow S$ . A morphism from $(\unicode[STIX]{x1D70B}^{\prime }:X^{\prime }\rightarrow S^{\prime },{\mathcal{L}}^{\prime })$ to $(\unicode[STIX]{x1D70B}:X\rightarrow S,{\mathcal{L}})$ is a fiber product diagram

such that $(g^{\prime })^{\ast }({\mathcal{L}})={\mathcal{L}}^{\prime }\in \operatorname{Pic}_{X^{\prime }/S^{\prime }}(S^{\prime })$ .

The following result gives the basic properties of the moduli stack ${\mathcal{M}}_{n}$ . An explicit description of ${\mathcal{M}}_{n}$ will be given in [Reference Debarre and KuznetsovDK18b]. We follow [Sta17] for our conventions on algebraic stacks.

Proposition A.2. The moduli stack ${\mathcal{M}}_{n}$ is a smooth and irreducible Deligne–Mumford stack of finite type over $\mathbf{k}$ . Its dimension is given by $\dim {\mathcal{M}}_{n}=25-(6-n)(5-n)/2$ , i.e.

$$\begin{eqnarray}\dim {\mathcal{M}}_{2}=19,\quad \dim {\mathcal{M}}_{3}=22,\quad \dim {\mathcal{M}}_{4}=24,\quad \dim {\mathcal{M}}_{5}=25,\quad \dim {\mathcal{M}}_{6}=25.\end{eqnarray}$$

We will use the following lemma.

Lemma A.3. Let $X$ be a smooth GM variety of dimension $n\geqslant 3$ . Then:

  1. (1) the automorphism group scheme $\operatorname{Aut}_{\mathbf{k}}(X)$ is finite and reduced;

  2. (2) $\text{H}^{i}(X,\text{T}_{X})=0$ for $i\neq 1$ ;

  3. (3) $\dim \text{H}^{1}(X,\text{T}_{X})=25-(6-n)(5-n)/2$ .

Proof. As our base field $\mathbf{k}$ has characteristic $0$ , $\operatorname{Aut}_{\mathbf{k}}(X)$ is automatically reduced by a theorem of Cartier [Reference MumfordMum66, Lecture 25], and it is finite by [Reference Debarre and KuznetsovDK18a, Proposition 3.21(c)]. Hence $\text{H}^{0}(X,\text{T}_{X})$ , being the tangent space to $\operatorname{Aut}_{\mathbf{k}}(X)$ at the identity, vanishes. Further, $\text{T}_{X}\cong \unicode[STIX]{x1D6FA}_{X}^{n-1}(n-2)$ by (2.2) and hence $\text{H}^{i}(X,\text{T}_{X})=0$ for $i\geqslant 2$ by Kodaira–Akizuki–Nakano vanishing. Finally, the dimension of $\text{H}^{1}(X,\text{T}_{X})$ is straightforward to compute using Riemann–Roch.◻

Proof of Proposition A.2.

First consider the case $n=2$ . Then by (2.3), ${\mathcal{M}}_{2}$ is the Brill–Noether general locus (and hence Zariski open) in the moduli stack of polarized K3 surfaces of degree  $10$ . It is well known that all the properties in the proposition hold for the moduli stack of primitively polarized K3 surfaces of a fixed degree (see [Reference HuybrechtsHuy16, ch. 5]), so they also hold for  ${\mathcal{M}}_{2}$ .

From now on assume $n\geqslant 3$ . A standard Hilbert scheme argument shows that ${\mathcal{M}}_{n}$ is an algebraic stack of finite type over $\mathbf{k}$ , whose diagonal is affine and of finite type. To prove ${\mathcal{M}}_{n}$ is Deligne–Mumford, by [Sta17, Tag 06N3] it suffices to show its diagonal is unramified. As a finite type morphism is unramified if and only if all of its geometric fibers are finite and reduced, we are done by Lemma A.3(1) (note that for a GM variety of dimension $n\geqslant 3$ , all automorphisms preserve the natural polarization).

Next we check smoothness of ${\mathcal{M}}_{n}$ . Let $(X,{\mathcal{L}})$ be a point of ${\mathcal{M}}_{n}$ , i.e. $X$ is a GM $n$ -fold and ${\mathcal{L}}\in \operatorname{Pic}(X)$ is the ample generator. Let $\mathfrak{A}_{{\mathcal{L}}}$ be the Atiyah extension of ${\mathcal{L}}$ , i.e. the extension

$$\begin{eqnarray}0\rightarrow {\mathcal{O}}_{X}\rightarrow \mathfrak{A}_{{\mathcal{L}}}\rightarrow \text{T}_{X}\rightarrow 0\end{eqnarray}$$

given by the Atiyah class of ${\mathcal{L}}$ . Further, recall that $\text{H}^{1}(X,\mathfrak{A}_{{\mathcal{L}}})$ classifies first order deformations of the pair $(X,{\mathcal{L}})$ , and $\text{H}^{2}(X,\mathfrak{A}_{{\mathcal{L}}})$ is the obstruction space for such deformations (see [Reference SernesiSer06, § 3.3.3]). Taking cohomology in the above sequence shows that $\text{H}^{i}(X,\mathfrak{A}_{{\mathcal{L}}})\cong \text{H}^{i}(X,\text{T}_{X})$ for $i\geqslant 1$ . In particular, $\text{H}^{2}(X,\mathfrak{A}_{{\mathcal{L}}})=0$ by Lemma A.3(2), so the formal deformation space of ${\mathcal{M}}_{n}$ at $(X,{\mathcal{L}})$ is smooth of dimension $\dim \text{H}^{1}(X,\mathfrak{A}_{{\mathcal{L}}})=\dim \text{H}^{1}(X,\text{T}_{X})$ . This implies the smoothness of ${\mathcal{M}}_{n}$ and, using Lemma A.3(3), the formula for its dimension.

It remains to show that ${\mathcal{M}}_{n}$ is irreducible. This follows from the defining expression (2.1) of any GM variety. Indeed, let $P_{n}$ be the space of pairs $(W,Q)$ where $W\subset \mathbf{k}\oplus \wedge ^{2}V_{5}$ is an $(n+5)$ -dimensional linear subspace and $Q\subset \mathbf{P}(W)$ is a quadric hypersurface, and let $U_{n}\subset P_{n}$ be the open subset where $\operatorname{Cone}(\mathbf{G})\,\cap \,Q$ is smooth of dimension $n$ . The natural projection $P_{n}\rightarrow \operatorname{Gr}(n+5,\mathbf{k}\oplus \wedge ^{2}V_{5})$ is a projective bundle, hence $P_{n}$ and $U_{n}$ are irreducible. On the other hand, by (2.1), $U_{n}$ maps surjectively onto ${\mathcal{M}}_{n}$ . Hence ${\mathcal{M}}_{n}$ is irreducible as well.◻

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