Local duality for the singularity category of a finite dimensional Gorenstein algebra
Dave Benson, Srikanth B. Iyengar, Henning Krause, and Julia Pevtsova

TL;DR
This paper establishes a duality theorem for the singularity category of finite dimensional Gorenstein algebras, extending existing dualities and revealing new structural properties related to Serre duality and Auslander-Reiten triangles.
Contribution
It introduces a novel duality for the singularity category that complements Happel's duality on perfect complexes, with implications for local and torsion subcategories.
Findings
Proves a duality theorem for the singularity category.
Establishes an analogue of Serre duality.
Shows existence of Auslander-Reiten triangles in specific subcategories.
Abstract
A duality theorem for the singularity category of a finite dimensional Gorenstein algebra is proved. It complements a duality on the category of perfect complexes, discovered by Happel. One of its consequences is an analogue of Serre duality, and the existence of Auslander-Reiten triangles for the -local and -torsion subcategories of the derived category, for each homogeneous prime ideal arising from the action of a commutative ring via Hochschild cohomology.
Peer Reviews
No public reviews on file for this paper yet. If you reviewed it on a platform where reviews are public (OpenReview, ICLR, NeurIPS, ICML), you can paste yours below so the community can read it here.
Videos
No videos yet. Explain this paper in a talk, walkthrough, or lecture? Add one.
Local duality for the singularity category of a
finite dimensional Gorenstein algebra
Dave Benson, Srikanth B. Iyengar, Henning Krause
and Julia Pevtsova
Dave Benson
Institute of Mathematics
University of Aberdeen
King’s College
Aberdeen AB24 3UE
Scotland U.K.
Srikanth B. Iyengar
Department of Mathematics
University of Utah
Salt Lake City, UT 84112
U.S.A.
Henning Krause
Fakultät für Mathematik
Universität Bielefeld
33501 Bielefeld
Germany.
Julia Pevtsova
Department of Mathematics
University of Washington
Seattle, WA 98195
U.S.A.
Abstract.
A duality theorem for the singularity category of a finite dimensional Gorenstein algebra is proved. It complements a duality on the category of perfect complexes, discovered by Happel. One of its consequences is an analogue of Serre duality, and the existence of Auslander-Reiten triangles for the -local and -torsion subcategories of the derived category, for each homogeneous prime ideal arising from the action of a commutative ring via Hochschild cohomology.
Key words and phrases:
Gorenstein algebra, local duality, maximal Cohen-Macaulay module, Serre duality, singulartity category
2010 Mathematics Subject Classification:
16G10 (primary); 16G50, 16E65, 16E35
SBI was partly supported by NSF grants DMS-1503044 and DMS-1700985, and JP was partly supported by NSF grants DMS-0953011 and DMS-1501146. The authors are grateful to the American Institute of Mathematics in San Jose, California for supporting this project by their “Research in Squares” program.
1. Introduction
This work concerns duality phenomena in various triangulated categories of modules over Gorenstein algebras. By a Gorenstein algebra we mean here an algebra , finite dimensional over a field , with the property that has finite injective dimension both as a left module and a right module over itself. For such an the derived Nakayama functor is an equivalence:
[TABLE]
Happel [17] proved that for perfect complexes there is a natural isomorphism
[TABLE]
where . In other words, the Nakayama functor on restricts to a Serre functor, in the sense of Bondal and Kapranov [11], on the full subcategory of perfect complexes.
In this work we discover that Happel’s result is only the tip of an iceberg: It is a special case of a duality on , analogous to Grothendieck’s local duality for commutative Gorenstein algebras. The duality on also involves a (graded-)commutative algebra, namely, , the Hochschild cohomology, of over that acts on via canonical homomorphisms of -algebras
[TABLE]
In this way acquires a structure of an -linear category.
In the remainder of the introduction we fix a homogeneous -subalgebra of that is finitely generated as a -algebra. For simplicity of exposition we assume that . This is not a great loss of generality for given any as above, we can drop down to the subring without sacrificing the finite generation. A natural choice for is but, for example, when is a Hopf algebra, like the group algebra of a finite group, or group scheme, it is more natural to take , the cohomology ring of , for this is functorial in the ring argument, whilst the Hochschild cohomology is not.
Fix a homogeneous prime ideal of . Let be the triangulated category obtained from by localising the graded morphisms at and then taking the full triangulated subcategory of objects such that the graded endomorphisms are -torsion. By construction is an -linear category, where denotes the homogenous localisation of at . The Nakayama functor induces an equivalence
[TABLE]
Let denote the homogenous prime ideals in not containing , the unique maximal homogenous ideal of . For the injective hull of the graded -module is denoted . Our local Serre duality statement reads:
Theorem 1.1**.**
Let be in and let be the Krull dimension of . Then is a Serre functor for , in that, for all in there are natural isomorphisms
[TABLE]
This result is proved towards the end of Section 5 from a more general statement concerning the category of (possibly infinite dimensional) Gorenstein projective modules. These are -modules with the property that for and projective -module . The connection to is through its subcategory, , consisting of finitely dimensional modules. These are precisely the maximal Cohen-Macaulay -modules, in the terminology of Buchweitz [13].
The stable category, , of is a compactly generated triangulated category, with compact objects equivalent to , the stabilisation of . Buchweitz [13] proved that there is a equivalence of triangulated categories
[TABLE]
where is the singularity category, also known as the stable derived category, of . There is a natural -action on and the equivalence above is compatible with the induced -actions. For each prime ideal in the canonical functors induce equivalences of triangulated categories
[TABLE]
compatible with -actions, by Lemma 5.5. Thus to prove Theorem 1.1 it suffices to prove the corresponding statement for ; equivalently, for the singularity category of . This also explains the title of this paper.
To that end we consider the subcategory of consisting of the -local -torsion modules. These are the Gorenstein projective -modules with the property that for each finite dimensional -module , every element of , the graded -module of morphisms in , is annihilated by some power of , and the natural map is bijective. Then is also a compactly generated triangulated category and the full subcategory of compact objects is equivalent, up to direct summands, to . There is an idempotent functor with image the -local -torsion modules; see Section 3 for details. The central result of this work is a local duality theorem for this category:
Theorem 1.2**.**
Let be in and let be the Krull dimension of . Let be Gorenstein projective -modules and suppose that is finite dimensional. Then there is a natural isomorphism
[TABLE]
Here is the Gorenstein projective approximation functor; see Section 2 for details. The theorem above is contained in Theorem 5.1.
Theorems 1.1 and 1.2 are formulated in terms of an arbitrary (but fixed) subalgebra of the Hochschild cohomology of . It is thus natural to ask how these results are related as we vary . This point is addressed in Remark 5.8. Another issue is what transpires in Theorem 1.1 if we set . When the ring is such that, in addition to being noetherian, the -module is finitely generated for each , the subcategory is precisely the subcategory of perfect complexes and the analogue of Theorem 1.1 is Happel’s duality; see Remark 5.6.
The duality statements above are modeled on, and extensions of, analogous results for representation of modules over finite group schemes established in [10]. In that context, the stable category of (finite dimensional) Gorenstein projectives is the stable category of (finite dimensional) representations. We refer to that work for antecedents of these results and for applications, notably, the existence of AR triangles in . The proof of the results in op. cit. exploited the tensor structure on the module categories in question, but in fact the arguments can be readily adapted to deal with the general case, as we do here. In doing so, it became clear that local duality is a feature of Gorenstein algebras in general.
2. Gorenstein algebras
Throughout this work will be a field and a finite dimensional -algebra that is Gorenstein (also known as Iwanaga-Gorenstein): the injective dimension of as a left -module and as a right -module is finite. In this case, the injective dimensions are the same; this was proved by Zaks [25]. Evidently when is Gorenstein so is , the opposite algebra of .
In this section we recall basic notions and results from the homological theory of Gorenstein algebras, mainly pertaining to duality. To begin with we note that the Gorenstein condition on is equivalent to: An -module has finite projective dimension if and only if it has finite injective dimension; see, for example, [13, Lemma 5.1.1]. This will be used often in the sequel.
Let be the category all (left) -modules and its full subcategory consisting of finitely generated -modules. The full subcategory of consisting of projective -modules is denoted . The injective analogue is denoted . In what follows for -modules we set
[TABLE]
When and are finitely generated, it suffices to consider maps that factor through and , respectively.
In the sequel a duality between categories will mean a contravariant equivalence.
Vector space duality
For any -module we set
[TABLE]
viewed as an -module. The assignment induces a duality
[TABLE]
which restricts to a duality . The functor also extends to a duality between the corresponding bounded derived categories:
[TABLE]
Let denote the bounded derived category of . We identify it with the subcategory of consisting of perfect complexes. The duality above restricts to , since is Gorenstein.
The singularity category
Buchweitz [13] introduced the stable derived category of as the Verdier quotient
[TABLE]
This category was rediscovered by Orlov [21], who called it the singularity category of , and our notation reflects this terminology. When the global dimension of is finite one has , so the singularity category is one measure of the deviation of from finite global dimension.
The duality (2.1) induces a duality
[TABLE]
The singularity category can be realized (in more than one way) as a stabilisation of a subcategory of . This is described next.
Gorenstein projective and Gorenstein injective modules
An -module is Gorenstein projective if
[TABLE]
We write for the category of Gorenstein projective -modules and set
[TABLE]
These are the maximal Cohen-Macaulay -modules, in Buchweitz’s terminology.
Standard arguments (following, for example, [17, Section 9]) yield that is a Frobenius exact category, with the projective -modules the projective and injective objects in this category; this requires the hypothesis that is Gorenstein. We write for the corresponding stable category; it is a triangulated category. Its thick subcategory consisting of the finitely generated modules is denoted , for it can be realised as a stabilisation of .
On the syzygy functor has an inverse, denoted , that is well-defined up to projective summands. This is the translation on .
An -module is Gorenstein injective if
[TABLE]
We write for the category of Gorenstein injective modules and set . The stabilisation of is denoted , and the subcategory of finitely generated modules is . These are triangulated categories, where the translation of a is the cokernel of an embedding into an injective -module:
[TABLE]
The duality restricts to dualities
[TABLE]
and hence induces a duality of triangulated categories
[TABLE]
Here is the result on realising the singularity category as a stabilisation.
Proposition 2.1**.**
The inclusions and induce triangle equivalences
[TABLE]
Proof.
The first equivalence is Theorem 4.4.1 from [13], and the second equivalence follows from that statement applied to and dualities (2.4). ∎
Approximations
The following result—see [13, Lemma 5.1.1]—is straightforward to verify.
Lemma 2.2**.**
Let be a Gorenstein projective module.
- (1)
* for any module of finite projective dimension and .* 2. (2)
If an -linear map factors through a module of finite projective dimension, then it factors through a projective module.
The analogous statements for Gorenstein injective modules also hold.∎
This has the following consequence.
Lemma 2.3**.**
If is Gorenstein projective and is Gorenstein injective, then
[TABLE]
Proof.
Given Lemma 2.2, one has to verify that a map factors through a module of finite projective dimension if and only if it factors through a module of finite injective dimension. This is a tautology as these categories coincide. ∎
The following result is due to Auslander and Buchweitz, and is the cornerstone of their theory of maximal Cohen-Macaulay approximations. There is an analogous statement involving Gorenstein injectives.
Proposition 2.4**.**
Every finite dimensional -module fits into exact sequences
[TABLE]
where are in and have finite projective dimension. For and of finite projective dimension, these sequences induce bijections
[TABLE]
Proof.
This is part of [13, Theorems 5.1.2, 5.1.4]; see also [3, Theorems 1.8, 2.8]. ∎
We write for the Gorenstein projective approximation of . It follows from the preceding result that is well-defined in .
Lemma 2.5**.**
The Gorenstein projective approximation induces a triangle equivalence satisfying , where are the functors in Proposition 2.1.
Proof.
Since for any -module of finite projective dimension, Proposition 2.4 implies for any Gorenstein injective module . This yields also that is a triangle equivalence, since are triangle equivalences. ∎
Remark 2.6*.*
When is self-injective the projective and injective -modules coincide and hence . Conversely, when the (projective) module is Gorenstein injective, is self-injective: Consider an exact sequence
[TABLE]
where is injective. If is Gorenstein injective, then so is , and hence the sequence above splits, as the injective dimension of is finite. Thus is injective.
Example 6.3 describes a Gorenstein algebra that is not self-injective, and identifies modules that are Gorenstein projective but not Gorenstein injective.
The Nakayama functor
This is the functor that assigns to each in the -module
[TABLE]
This functor is an equivalence if is self-injective but not in general. However the Gorenstein property of implies that the derived Nakayama functor, for which we use the same notation, is an equivalence:
[TABLE]
From this it is not hard to verify that restricts to equivalences
[TABLE]
Therefore one gets an induced equivalence .
On the other hand, since the complexes of finite projective dimension are the same as those of finite injective dimension (because is Gorenstein), is in the thick subcategory of generated by , and hence, by duality is in the thick subcategory of generated by , that is to say, by . It follows that the derived Nakayama functor satisfies
[TABLE]
This is the essence of Happel duality. It induces an equivalence on the singularity category that makes the following square commutative
[TABLE]
The vertical equivalences are from Proposition 2.1.
The Auslander transpose
Let be a finite dimensional Gorenstein projective -module. Any projective presentation
[TABLE]
induces an exact sequence of -modules.
[TABLE]
The -module is the Auslander transpose of , and it depends only on up to projective summands. It is a Gorenstein projective -module since it identifies with . Applying yields an exact sequence of -modules
[TABLE]
Since is Gorenstein projective over , the -module is Gorenstein injective and the exact sequence above implies that there is an isomorphism
[TABLE]
in .
Auslander-Reiten Duality
We are ready to state the main results of this section. For similar statements we refer to [1, 5].
Proposition 2.7**.**
Let be a Gorenstein algebra, and Gorenstein projective -modules. When is finite dimensional, there is a natural isomorphism
[TABLE]
Proof.
The exact sequence with projective, induces the first of the following isomorphisms
[TABLE]
The second isomorphism is Auslander-Reiten duality [2, Proposition I.3.4], whilst the third isomorphism is from Lemma 2.3, since is Gorenstein projective and is Gorenstein injective. The fourth isomorphism follows from Proposition 2.4, and the final one is clear since is an equivalence on . ∎
As in Bondal and Kapranov [11, §3], a Serre functor on a -linear, Hom-finite, additive category is an equivalence along with natural isomorphisms
[TABLE]
for all objects in .
Theorem 2.8**.**
Let be a Gorenstein algebra. Then
[TABLE]
are Serre functors.
Proof.
For any Gorenstein projective -module , one has a sequence of isomorphisms in , where the first and the last one are by construction:
[TABLE]
The second and the fourth isomorphisms hold because is a triangle functor, and the third one is by (2.6). Thus Proposition 2.7 yields that is a Serre functor on , as claimed. The description of the Serre functor on is then a consequence of Lemma 2.5 and (2.5). ∎
Compact generation
So far the results have mostly dealt with the categories and consisting of finite dimensional modules. To prove the local duality theorem announced in the introduction we need to work in larger categories, and . To this end we recall the following result, which is well-known at least for self-injective algebras.
Proposition 2.9**.**
The stable categories and are compactly generated triangulated categories, and the full subcategories of compact objects identify with and , respectively.
Proof.
The Nakayama functor induces a triangle equivalence , identifying with ; the quasi-inverse is given by . It thus suffices to verify the assertions about .
It follows from [18, §5] that is compactly generated; it remains to identify the compact objects. If is a finite dimensional module, then preserves direct sums. Thus every module in is compact in .
On the other hand, for any nonzero module in there exists a finite dimensional module such that ; this is because is not injective. Choose a Gorenstein injective approximation , using the analogue of Proposition 2.4 for Gorenstein injective modules. Then
[TABLE]
which implies that is all the compact objects of . ∎
3. Cohomology and localisation
In this section we recall basic notions and constructions concerning certain localisation functors on triangulated categories with ring actions. The material is needed to state and prove the results in Section 4 and 5. The main triangulated category of interest is the stable category of Gorenstein projective modules. Primary references for the material presented here are [6, 7].
Triangulated categories with central action
Let be a triangulated category with suspension . Given objects and in , consider the graded abelian groups
[TABLE]
Composition makes a graded ring and a left- right- module.
Let be a graded-commutative ring. We say the triangulated category is -linear if for each in there is a homomorphism of graded rings such that the induced left and right actions of on are compatible in the following sense: For any and , one has
[TABLE]
An exact functor between -linear triangulated categories is -linear if the induced map
[TABLE]
of graded abelian groups is -linear for all objects in .
In what follows, we fix a compactly generated -linear triangulated category and write for its full subcategory of compact objects.
Graded modules
In the remainder of this section will be a graded commutative noetherian ring. We will only be concerned with homogeneous elements and ideals in . In this spirit, ‘localisation’ will mean homogeneous localisation, and will denote the set of homogeneous prime ideals in .
Given graded -modules and , we denote by the -linear maps such that for all , and
[TABLE]
where for all .
Localisation
Fix an ideal in . An -module is -torsion if for all in with . Analogously, an object in is -torsion if the -module is -torsion for all . The full subcategory of -torsion objects
[TABLE]
is localising and the inclusion admits a right adjoint, denoted .
Fix a in . An -module is -local if the localisation map is invertible, and an object in is -local if the -module is -local for all . Consider the full subcategory of of -local objects
[TABLE]
and the full subcategory of -local and -torsion objects
[TABLE]
Note that are localising subcategories. The inclusion admits a left adjoint while the inclusion admits a right adjoint. We denote by the composition of those adjoints; it is the local cohomology functor with respect to ; see [6, 7] for explained notions and details.
The functor commutes with exact functors preserving coproducts.
Lemma 3.1**.**
Let be an exact functor between -linear compactly generated triangulated categories such that is -linear and preserves coproducts. Suppose that the action of on factors through a homomorphism of graded commutative rings. For any ideal of there is a natural isomorphism
[TABLE]
of functors , where denotes the ideal of that is generated by .
Proof.
The statement follows from an explicit description of in terms of homotopy colimits; see [7, Proposition 2.9]. ∎
The following observation is clear.
Lemma 3.2**.**
For any element in , say of degree , and -local object , the natural map is an isomorphism. ∎
Koszul objects
Fix objects in . Any element in induces a morphism and let denote its mapping cone. This gives a morphism . For a sequence of elements in set where
[TABLE]
It is easy to check that for there is an isomorphism
[TABLE]
Injective cohomology objects
Given an object in and an injective -module , Brown representability yields an object in such that
[TABLE]
This yields a functor
[TABLE]
For each in , we write for the injective hull of and set
[TABLE]
viewed as a functor . For objects and in , applying (3.2) twice one gets a natural -linear isomorphism
[TABLE]
4. Hochschild and Tate cohomology
Let be a field and a finite dimensional Gorenstein -algebra. The enveloping algebra of is the -algebra ; it is also Gorenstein, by Proposition 6.1, but this observation does not play a role in the sequel. The Hochschild cohomology of the -algebra is
[TABLE]
This is a graded-commutative -algebra.
When and are Gorenstein projective -modules, we set
[TABLE]
This is the Tate cohomology of . There is a canonical homomorphism
[TABLE]
of graded abelian groups, induced from the canonical morphism from a complete projective resolution to a projective resolution of ; see [13, 6.2]. In particular, this map is surjective in degree [math] and bijective in positive degrees.
Action on
For any -module there is a canonical map
[TABLE]
that is a morphism of graded -algebras. When is Gorenstein projective, composing the map above with the one in (4.1) one gets a homomorphism of -algebras
[TABLE]
and this induces a linear action of on , in the sense of Section 3.
Assumption 4.1**.**
We fix a homogenous -subalgebra of such that
- (1)
is connected, that is to say, ; 2. (2)
is finitely generated as a -algebra.
Connectedness implies that is the unique maximal ideal of , which allows us to import the results from [10]. This is not a serious restriction. Indeed decomposes as a direct product of connected algebras, and for a connected algebra the ring , being the center of , is a finite dimensional local ring, so the inclusion induces a bijection on the spectra.
As usual denotes the set of prime ideals that do not contain .
Condition (2) is equivalent to the condition that the ring is noetherian; see [12, Proposition 1.5.4]. Since the -action on restricts to an -action, the noetherian property of allows one to invoke the constructions and results presented in Section 3.
Base change
Let be an extension of fields and set
[TABLE]
This is a finite dimensional Gorenstein -algebra, and extension of scalars
[TABLE]
and restriction
[TABLE]
form an adjoint pair of exact functors.
Lemma 4.2**.**
For -modules and , the canonical -linear map
[TABLE]
is a isomorphism when is finite dimensional over .∎
Lemma 4.3**.**
Extension and restriction preserve projectivity and injectivity. Thus is Gorenstein if and only if is Gorenstein. In that case extension and restriction preserve Gorenstein projectivity.∎
There are isomorphisms of -algebras
[TABLE]
Thus extension of scalars yields a ring homomorphism , and setting one gets a ring homomorphism
[TABLE]
Observe that is connected and a noetherian -subalgebra of .
Next we recall a construction from [9] of a field extension and a closed point in lying over a given a point in .
Construction 4.4**.**
Let be a finitely generated, graded, connected, -algebra. Fix a point in , and let be the Krull dimension of .
Choose elements in of the same degree such that their image in is algebraically independent over and is finitely generated as a module over the subalgebra . Set , the field of rational functions in indeterminates and
[TABLE]
viewed as elements in . Let denote the extension of to , and set
[TABLE]
The following statements hold:
- (1)
is a closed point in with the property that ; 2. (2)
the induced extension of fields is an isomorphism.
The first part is contained in [9, Theorem 7.7]. The second one holds by construction; see [9, Lemma 7.6, and (7.2)].
Fix an object in . The sequence of elements in yields a morphism , where . Composing its restriction to with the canonical morphism gives in a morphism
[TABLE]
Since the are not in , when is -local Lemma 3.2 yields a natural isomorphism
[TABLE]
in .
The result below extends [10, Theorem 3.4] that concerns modules over finite group schemes, but the argument is essentially the same.
Theorem 4.5**.**
For any Gorenstein projective -module , the morphism induces a natural isomorphism
[TABLE]
in . When is -torsion, this induces a natural isomorphism
[TABLE]
Proof.
Given the second isomorphism, the first one can be checked as follows: Let be a Gorenstein projective -module and the ideal in Construction 4.4. Since is -torsion, one gets the second isomorphism below:
[TABLE]
The third one is by Lemma 3.1, applied to the functor from to . The next one is standard while the penultimate one holds because is -torsion.
It remains to verify the second isomorphism in the statement. The modules satisfying this isomorphism form a localising subcategory of . Moreover, by [7, Proposition 2.7], the -torsion modules form a localising subcategory of generated by the modules , for . It thus suffices to verify the desired isomorphism for such modules. Since is -torsion, the natural map
[TABLE]
is an isomorphism. Thus the task reduces to verifying that is an isomorphism for each . This is proved in [9, Theorem 8.8] for the case of finite group schemes and , the trivial representation. However the argument only uses [9, Proposition 6.2(2)] which in turn is a formal consequence of Lemma 3.1, and thus carries over to the present context. ∎
5. The Gorenstein property
Let be the Serre functor from Theorem 2.8, given by
[TABLE]
Given the description of , the result below contains Theorem 1.2. It extends [10, Theorem 5.1], which deals with the case is the group algebra of a finite group scheme and , its cohomology ring.
Theorem 5.1**.**
Let be a field, a finite dimensional, Gorenstein, -algebra and as in 4.1. Fix , and let be the Krull dimension of . On there is a natural isomorphism of functors
[TABLE]
Thus for any object in there is a natural isomorphism
[TABLE]
This result is proved further below, following some preparatory remarks.
Remark 5.2*.*
Let be Gorenstein projective -modules. The natural map
[TABLE]
is compatible with action of , and hence of . The map is surjective in degree zero, with kernel , the maps from to that factor through a projective -module. Since it is bijective in positive degrees one gets an exact sequence of graded -modules
[TABLE]
with for . For degree reasons, the -modules and are -torsion so for in the induced localised map is an isomorphism:
[TABLE]
It follows from Lemma 4.3 that the functor is compatible with base change.
Lemma 5.3**.**
Let be a field extension and the corresponding Serre functor. For in there is a natural isomorphism . ∎
The argument below is direct adaptation of the one for [10, Theorem 5.1].
Proof of Theorem 5.1.
The proof uses the following observation: For any -modules that are -local and -torsion, there is an isomorphism in if and only if there is a natural isomorphism
[TABLE]
for -local and -torsion -modules . This follows from Yoneda’s lemma.
In anticipation of using the preceding remark, we note that and are -local and -torsion. This is clear for and follows for from the fact that is a -local and -torsion -module. Another observation is that, by (5.2), for any -local -module , there is an isomorphism
[TABLE]
Consequently, one can rephrase the defining isomorphism (3.2) for the object as a natural isomorphism
[TABLE]
Our task is to verify that, on , there is an isomorphism of functors
[TABLE]
We verify this when is closed and then use a reduction to closed points.
Claim*.*
The desired isomorphism holds when is a closed point in .
The injective hull, , of the -module is the same as that of the -module , viewed as an -module via restriction of scalars along the localisation map . Let be a Gorenstein projective -module that is -local and -torsion. The claim is a consequence of the following computation:
[TABLE]
The first isomorphism holds because is -torsion; the second is Serre duality, Proposition 2.7, and the next one is by [10, Lemma A.2], which applies because is -local and -torsion as an -module.
Let be a point in that is not closed, and let , , and be as in Construction 4.4. Recall that is a closed point in lying over .
Claim*.*
In there is an isomorphism of -modules
[TABLE]
where is the Krull dimension of .
Let be an -module that is -local and -torsion. Then we have the following:
[TABLE]
The first and fifth isomorphisms are by adjunction. The second one is a direct computation using (3.1) and (4.2). The next one is by definition and the fourth isomorphism is by [10, Lemma A.3], applied to the homomorphism ; it applies as the -module is -torsion. The sixth isomorphism is by Theorem 4.5, and the last one by definition. This justifies the claim.
Consider now the chain of isomorphisms:
[TABLE]
The first isomorphism is by Theorem 4.5, the second by Lemma 5.3, the third is clear, the fourth follows from the first claim, since is a closed point for , and the last one follows from the second claim.
This completes the proof that the functors and are isomorphic. Given this and the alternative description of above, the last isomorphism in the statement follows. ∎
Next we record a corollary of Theorem 5.1 concerning , the -torsion objects in the -localisation of ; see [10, §7] and the references therein for details of this construction. The -linear triangle equivalences
[TABLE]
induce -linear triangle equivalences
[TABLE]
compatible with the localisation functor; see [10, Remark 7.1]. The result below can be interpreted as the statement that the category , and hence also , has a Serre functor.
Corollary 5.4**.**
For in , there is a natural isomorphism
[TABLE]
Proof.
Up to direct summands, the categories and are equivalent, and the compact objects in are of the form , for some that is -torsion; see [10, Remark 7.2]. We obtain the desired isomorphism by reinterpreting the isomorphisms in Theorem 5.1, as follows.
Fix -torsion objects in . One has the first isomorphism below because is finite dimensional:
[TABLE]
The second one is by (5.2), and the last one is by adjunction.
On the other hand, since is -torsion, so is and hence one has the first isomorphism below:
[TABLE]
The second one is by the definition of and the third one follows by the discussion around (5.4). Applying to the composition yields the first isomorphism below, whilst the second one holds as the covariant argument is -local:
[TABLE]
The isomorphisms above and Theorem 5.1, applied with and , yield the desired result. ∎
Lemma 5.5**.**
For any the quotient functor induces equivalences
[TABLE]
compatible with the actions.
Proof.
The quotient functor is essentially surjective and hence so is its -localisation . The latter is also fully faithful, by (5.2), and so is an equivalence of categories. It is also -linear, by construction. Given this, it is immediate from the definition that the -torsion subcategories are equivalent. ∎
Proof of Theorem 1.1.
The hypotheses is that is a finite dimensional Gorenstein algebra and is a finitely generated, homogenous, -subalgebra of with . Also, . We fix a homogeneous prime ideal in . We want to verify that for all in there are natural isomorphisms
[TABLE]
with the Krull dimension of . Lemma 5.5 gives the second equivalence below:
[TABLE]
whereas the first one is induced by Proposition 2.1, and both these are compatible with the actions. It remains to recall Corollary 5.4. ∎
The (Fg) condition
As in (4.1), let be a connected, noetherian -subalgebra. Assume in addition that for each the -module is finitely generated. Said otherwise, the algebra satisfies the (Fg) condition with respect to , introduced in [15]. As noted in [24, Proposition 5.7], this condition implies that the Hochschild cohomology algebra is finitely generated. The (Fg) condition holds for several interesting classes of finite dimensional Hopf algebras, including group algebras of finite groups (or group schemes), small quantum groups, and also for finite dimensional commutative complete intersection rings; see [15, 16, 20, 24].
When satisfies the (Fg) condition, it follows from Corollary 5.4 that the triangulated category , and hence also anything equivalent to it, has AR-triangles. This is explained in [10, Section 7], for which we refer the reader also for other consequences of Serre duality.
Remark 5.6*.*
Assume that the algebra satisfies the (Fg) condition with respect to and set , the homogenous maximal ideal of . Set .
Claim*.*
The triangulated category is equivalent to .
Indeed, by definition, consists of complexes for which is -torsion as an -module; equivalently, is -torsion for each . In particular, is -torsion, where is the Jacobson radical of . Since the -module is finitely generated, by the (Fg) condition, this last property is equivalent to for , that is to say, is perfect.
Given this claim, one can extend Theorem 1.1 even to : For perfect complexes from [17] we get the second isomorphism below:
[TABLE]
The first one is by adjunction as ; see [10, Lemma A.2]. This is the stated Serre duality on , for the Krull dimension of is [math] and .
Remark 5.7*.*
Concerning the claim in Remark 5.6: Even when does not satisfy the (Fg) condition with respect to , the subcategory contains the perfect complexes, but it is possible that it contains more. To see what is at stake, consider the special case that is self-injective. Let be a module containing as a direct summand and satisfying for all . It is easy to verify that is in . However, it is still unknown, and a conjecture of Auslander and Reiten [4], whether such an has finite projective dimension, equivalently that is projective.
Remark 5.8*.*
With and as before, let be connected, finitely generated, -subalgebras of the Hochschild cohomology algebra . Theorem 5.1, and so also its corollaries, applies to the action of , and also of , on . In reconciling the two, one can replace by the -subalgebra of generated by and and assume . Then one has an induced map defined by the assignment .
Given in , it is clear that there is an inclusion
[TABLE]
So the version of Theorem 5.1 for the action of may be seen as a refinement of the one for the action of . Indeed, in the extremal case , one has for any in and .
A more interesting situation occurs when is finite as an -module. Then there are only finitely many primes in lying over a given , and [8, Corollary 7.10] yields a direct sum decomposition
[TABLE]
This decomposition thus reflects the ramification, in the sense of commutative algebra, of the inclusion .
6. Examples
In this section we describe some examples of Gorenstein algebras. Throughout will be a field. The injective dimension of a finite dimensional -algebra is the injective dimension of viewed as a (left) module over itself; we denote it . This is also the projective dimension of the -module .
Proposition 6.1**.**
Let and be finite dimensional -algebras. The finite dimensional -algebra satisfies
[TABLE]
In particular is Gorenstein if, and only if, both and are Gorenstein.
Proof.
Set and . Let , be minimal projective resolutions of , respectively. Then is a minimal projective resolution of by the lemma below. It remains to observe that the latter is isomorphic to , as modules over . ∎
Lemma 6.2**.**
Let , be minimal projective resolutions of modules , over finite dimensional algebras , respectively. Then is a minimal projective resolution of the -module .
Proof.
With denoting the Jacobson radical, is a nilpotent two-sided ideal in , and therefore it is contained in . So for any projective -module and projective -module , we have
[TABLE]
as -modules. The lemma now follows from the fact that a projective resolution is minimal if and only if the image of each differential lands in the radical of the next module. ∎
Using the result above, one can construct Gorenstein algebras of any given injective dimension, as long as we find one whose injective dimension is one. The next example describes such an algebra. In particular its class of Gorenstein projective modules is not the same as the class of Gorenstein injective modules; confer Remark 2.6. Another noteworthy feature of the algebra is that it is not of finite global dimension.
Example 6.3**.**
Let be a field, the -algebra of dual numbers, and set
[TABLE]
The -algebra has injective dimension one over itself, and can be realised as the path algebra of the quiver
[TABLE]
modulo the relations
[TABLE]
The algebra is representation finite and has precisely nine indecomposable modules. There are two simple modules corresponding to the vertices and . The following diagram shows the Auslander-Reiten quiver. The vertices represent the indecomposables via their composition series. There is a solid arrow if there is an irreducible morphism, and a dotted arrow when .
[TABLE]
The Gorenstein projectives have a bold frame, the Gorenstein injectives are shaded, and the modules of finite projective and injective dimension have rectangular shape. A module belongs to all three classes if and only if it is projective and injective; there is a unique indecomposable with this property.
One way to justify these computations is via [23, Theorem 2] due to Ringel and Zhang that sets up a bijection between indecomposable non-projective Gorenstein projective modules over and the indecomposable -modules, for any quiver .
The reference list from the paper itself. Each links out to its DOI / PubMed record.
- 1[1] C. Amiot, Sur les petites catégories triangulées , Ph D thesis, U. Paris 7, 2008.
- 2[2] M. Auslander, Functors and morphisms determined by objects , Representation theory of algebras (Proc. Conf., Temple Univ., Philadelphia, Pa., 1976), 1–244. Lecture Notes in Pure Appl. Math., 37, Dekker, New York, 1978.
- 3[3] M. Auslander and R.-O. Buchweitz, The homological theory of maximal Cohen-Macaulay approximations , Mém. Soc. Math. France (N.S.) No. 38 (1989), 5–37.
- 4[4] M. Auslander and I. Reiten, On a generalized version of the Nakayama conjecture , Proc. Amer. Math. Soc. 52 (1975), 69–74.
- 5[5] M. Auslander and I. Reiten, Cohen-Macaulay and Gorenstein Artin algebras , Representation theory of finite groups and finite-dimensional algebras (Bielefeld, 1991), 221–245, Progr. Math., 95, Birkhäuser, Basel, 1991.
- 6[6] D. J. Benson, S. B. Iyengar, and H. Krause, Local cohomology and support for triangulated categories , Ann. Scient. Éc. Norm. Sup. (4) 41 (2008), 575–621.
- 7[7] D. J. Benson, S. B. Iyengar, and H. Krause, Stratifying triangulated categories , J. Topology 4 (2011), 641–666.
- 8[8] D. J. Benson, S. B. Iyengar, and H. Krause, Colocalising subcategories and cosupport , J. Reine Angew. Math. 673 (2012), 161–207.
