A McKay correspondence for reflection groups

Buchweitz, Ragnar-Olaf; Faber, Eleonore; Ingalls, Colin

doi:10.1215/00127094-2019-0069

Cited by 10 publications

(25 citation statements)

References 57 publications

(59 reference statements)

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“…We are interested in complex reflection groups, since in [16] the first three authors established a McKay correspondence for true reflection groups, i.e., groups generated by complex reflections of order 2: the nontrivial irreducible representations of such a group G were shown to correspond to maximal Cohen-Macaulay modules over the discriminant of the reflection group, in particular, they correspond to the isotypical components of the hyperplane arrangement, viewed as a module over the coordinate ring of the discriminant, see [16,Thm. 4.17].…”

Section: ) Let ([α] δ) and ([β] δ ) Be Two Vertices Of (G) Then There Is An Arrow With Source ([α] δ) And Target ([β] δ ) Whenever [β]mentioning

confidence: 99%

“…Finally a comment on how this paper came into being: In the first preprint version on the arXiv of [16] we had already determined the McKay quivers of G(1, 1, n), and Section 3 of the current paper appeared originally there. However, it made sense to combine it with the results of M. Lewis' thesis about the McKay quivers of the general G(r, p, n) [36], that now make up Sections 4 and 5 of the current paper.…”

Section: ) Let ([α] δ) and ([β] δ ) Be Two Vertices Of (G) Then There Is An Arrow With Source ([α] δ) And Target ([β] δ ) Whenever [β]mentioning

confidence: 99%

“…This is in particular in the literature on representation theory, see e.g. [3,4,8,35,53], because (G) op for G ⊆ GL(2, K) then coincides with the Auslander-Reiten quiver of G. Our convention is used in the geometric context, see [16,21,25].…”

Section: Remark 22mentioning

confidence: 99%

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McKay Quivers and Lusztig Algebras of Some Finite Groups

Buchweitz

Faber

Ingalls

et al. 2021

Algebr Represent Theor

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We are interested in the McKay quiver Γ(G) and skew group rings A ∗G, where G is a finite subgroup of GL(V ), where V is a finite dimensional vector space over a field K, and A is a K −G-algebra. These skew group rings appear in Auslander’s version of the McKay correspondence. In the first part of this paper we consider complex reflection groups $\mathsf {G} \subseteq \text {GL}(V)$ G ⊆ GL ( V ) and find a combinatorial method, making use of Young diagrams, to construct the McKay quivers for the groups G(r,p,n). We first look at the case G(1,1,n), which is isomorphic to the symmetric group Sn, followed by G(r,1,n) for r > 1. Then, using Clifford theory, we can determine the McKay quiver for any G(r,p,n) and thus for all finite irreducible complex reflection groups up to finitely many exceptions. In the second part of the paper we consider a more conceptual approach to McKay quivers of arbitrary finite groups: we define the Lusztig algebra $\widetilde {A}(\mathsf {G})$ A ~ ( G ) of a finite group $\mathsf {G} \subseteq \text {GL}(V)$ G ⊆ GL ( V ) , which is Morita equivalent to the skew group ring A ∗G. This description gives us an embedding of the basic algebra Morita equivalent to A ∗ G into a matrix algebra over A.

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Section: ) Let ([α] δ) and ([β] δ ) Be Two Vertices Of (G) Then There Is An Arrow With Source ([α] δ) And Target ([β] δ ) Whenever [β]mentioning

confidence: 99%

Section: ) Let ([α] δ) and ([β] δ ) Be Two Vertices Of (G) Then There Is An Arrow With Source ([α] δ) And Target ([β] δ ) Whenever [β]mentioning

confidence: 99%

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McKay Quivers and Lusztig Algebras of Some Finite Groups

Buchweitz

Faber

Ingalls

et al. 2021

Algebr Represent Theor

Self Cite

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“…Theorem 1.1 is an extension of [BFI20] where, for a complex reflection group generated by reflections of order 2, it is shown that End R/∆ S/(z) is a NCR for R/(∆). The groups G(2k, k, 2) are generated by order 2 reflections.…”

Section: Introductionmentioning

confidence: 99%

Non-commutative resolutions for the discriminant of the complex reflection group $G(m,p,2)$

May¹

2021

Preprint

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We show that for the family of complex reflection groups G = G(m, p,2) appearing in the Shephard-Todd classification, the endomorphism ring of the reduced hyperplane arrangement A(G) is a non-commutative resolution for the coordinate ring of the discriminant ∆ of G. This furthers the work of Buchweitz, Faber and Ingalls who showed that this result holds for any true reflection group. In particular, we construct a matrix factorization for ∆ from A(G) and decompose it using data from the irreducible representations of G. For G(m, p,2) we give a full decomposition of this matrix factorization, including for each irreducible representation a corresponding a maximal Cohen-Macaulay module. The decomposition concludes that the endomorphism ring of the reduced hyperplane arrangement A(G) will be a non-commutative resolution.

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“…On the other hand, we give a short introduction to discriminants of finite reflection groups and our construction of their noncommutative desingularizations. The details of our new results will be published elsewhere [BFI16].…”

Section: Introductionmentioning

confidence: 99%