The invariant form, Weyl group and root system

AbstractLet $$\varGamma $$ Γ be the graph on the roots of the $$E_8$$ E 8 root system, where any two distinct vertices e and f are connected by an edge with color equal to the inner product of e and f. For any set c of colors, let $$\varGamma _c$$ Γ c be the subgraph of $$\varGamma $$ Γ consisting of all the 240 vertices, and all the edges whose color lies in c. We consider cliques, i.e., complete subgraphs, of $$\varGamma $$ Γ that are either monochromatic, or of size at most 3, or a maximal clique in $$\varGamma _c$$ Γ c for some color set c, or whose vertices are the vertices of a face of the $$E_8$$ E 8 root polytope. We prove that, apart from two exceptions, two such cliques are conjugate under the automorphism group of $$\varGamma $$ Γ if and only if they are isomorphic as colored graphs. Moreover, for an isomorphism f from one such clique K to another, we give necessary and sufficient conditions for f to extend to an automorphism of $$\varGamma $$ Γ , in terms of the restrictions of f to certain special subgraphs of K of size at most 7.

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On Closed Subsets of Root Systems

Canadian Mathematical Bulletin ◽

10.4153/cmb-1994-050-4 ◽

1994 ◽

Vol 37 (3) ◽

pp. 338-345 ◽

Cited By ~ 6

Author(s):

D. Ž. Doković ◽

P. Check ◽

J.-Y. Hée

Keyword(s):

Weyl Group ◽

Root System ◽

Irreducible Component ◽

Product Space ◽

Root Systems ◽

Inner Product Space ◽

Inner Product ◽

Closed Sets ◽

Finite Dimensional ◽

Real Inner Product Space

AbstractLet R be a root system (in the sense of Bourbaki) in a finite dimensional real inner product space V. A subset P ⊂ R is closed if α, β ∊ P and α + β ∊ R imply that α + β ∊ P. In this paper we shall classify, up to conjugacy by the Weyl group W of R, all closed sets P ⊂ R such that R\P is also closed. We also show that if θ:R —> R′ is a bijection between two root systems such that both θ and θ-1 preserve closed sets, and if R has at most one irreducible component of type A1, then θ is an isomorphism of root systems.

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Young Diagrams and Intersection Numbers for Toric Manifolds associated with Weyl Chambers

The Electronic Journal of Combinatorics ◽

10.37236/4307 ◽

2015 ◽

Vol 22 (2) ◽

Cited By ~ 3

Author(s):

Hiraku Abe

Keyword(s):

Weyl Group ◽

Root System ◽

Ring Structure ◽

Classical Type ◽

Toric Manifold ◽

Combinatorial Formula ◽

Young Diagrams ◽

Intersection Numbers ◽

Toric Manifolds

We study intersection numbers of invariant divisors in the toric manifold associated with the fan determined by the collection of Weyl chambers for each root system of classical type and of exceptional type $G_2$. We give a combinatorial formula for intersection numbers of certain subvarieties which are naturally indexed by elements of the Weyl group. These numbers describe the ring structure of the cohomology of the toric manifold.

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Admissible Sequences for Twisted Involutions in Weyl Groups

Canadian Mathematical Bulletin ◽

10.4153/cmb-2011-075-1 ◽

2011 ◽

Vol 54 (4) ◽

pp. 663-675 ◽

Cited By ~ 3

Author(s):

Ruth Haas ◽

Aloysius G. Helminck

Keyword(s):

Weyl Group ◽

Root System ◽

Weyl Groups ◽

One To One ◽

Admissible Sequences

AbstractLetW be a Weyl group, Σ a set of simple reflections inW related to a basis Δ for the root system Φ associated with W and θ an involution such that θ(Δ) = Δ. We show that the set of θ- twisted involutions in W, = {w ∈ W | θ(w) = w–1} is in one to one correspondence with the set of regular involutions . The elements of are characterized by sequences in Σ which induce an ordering called the Richardson–Springer Poset. In particular, for Φ irreducible, the ascending Richardson–Springer Poset of , for nontrivial θ is identical to the descending Richardson–Springer Poset of .

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Affine Lie algebras: the normalized invariant bilinear form, the root system and the Weyl group

Infinite Dimensional Lie Algebras ◽

10.1007/978-1-4757-1382-4_6 ◽

1983 ◽

pp. 63-72

Author(s):

Victor G. Kac

Keyword(s):

Weyl Group ◽

Root System ◽

Lie Algebras ◽

Bilinear Form ◽

Affine Lie Algebras ◽

Invariant Bilinear Form

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The freeness of ideal subarrangements of Weyl arrangements

Discrete Mathematics & Theoretical Computer Science ◽

10.46298/dmtcs.2418 ◽

2014 ◽

Vol DMTCS Proceedings vol. AT,... (Proceedings) ◽

Author(s):

Takuro Abe ◽

Mohamed Barakat ◽

Michael Cuntz ◽

Torsten Hoge ◽

Hiroaki Terao

Keyword(s):

Weyl Group ◽

Root System ◽

Height Distribution ◽

Free Arrangement ◽

Positive Roots ◽

International Audience

International audience A Weyl arrangement is the arrangement defined by the root system of a finite Weyl group. When a set of positive roots is an ideal in the root poset, we call the corresponding arrangement an ideal subarrangement. Our main theorem asserts that any ideal subarrangement is a free arrangement and that its exponents are given by the dual partition of the height distribution, which was conjectured by Sommers-Tymoczko. In particular, when an ideal subarrangement is equal to the entire Weyl arrangement, our main theorem yields the celebrated formula by Shapiro, Steinberg, Kostant, and Macdonald. The proof of the main theorem is classification-free. It heavily depends on the theory of free arrangements and thus greatly differs from the earlier proofs of the formula. Un arrangement de Weyl est défini par l’arrangement d’hyperplans du système de racines d’un groupe de Weyl fini. Quand un ensemble de racines positives est un idéal dans le poset de racines, nous appelons l’arrangement correspondant un sous-arrangement idéal. Notre théorème principal affirme que tout sous-arrangement idéal est un arrangement libre et que ses exposants sont donnés par la partition duale de la distribution des hauteurs, ce qui avait été conjecturé par Sommers-Tymoczko. En particulier, quand le sous-arrangement idéal est égal à l’arrangement de Weyl, notre théorème principal donne la célèbre formule par Shapiro, Steinberg, Kostant et Macdonald. La démonstration du théorème principal n’utilise pas de classification. Elle dépend fortement de la théorie des arrangements libres et diffère ainsi grandement des démonstrations précédentes de la formule.

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The Weak Order on Weyl Posets

Canadian Journal of Mathematics ◽

10.4153/s0008414x19000063 ◽

2019 ◽

Vol 72 (4) ◽

pp. 867-899

Author(s):

Joël Gay ◽

Vincent Pilaud

Keyword(s):

Weyl Group ◽

Root System ◽

Coxeter Group ◽

Lattice Structure ◽

Root Systems ◽

Weak Order ◽

Generalized Associahedra

AbstractWe define a natural lattice structure on all subsets of a finite root system that extends the weak order on the elements of the corresponding Coxeter group. For crystallographic root systems, we show that the subposet of this lattice induced by antisymmetric closed subsets of roots is again a lattice. We then study further subposets of this lattice that naturally correspond to the elements, the intervals, and the faces of the permutahedron and the generalized associahedra of the corresponding Weyl group. These results extend to arbitrary finite crystallographic root systems the recent results of G. Chatel, V. Pilaud, and V. Pons on the weak order on posets and its induced subposets.

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Root System Chip-Firing II: Central-Firing

International Mathematics Research Notices ◽

10.1093/imrn/rnz112 ◽

2019 ◽

Cited By ~ 1

Author(s):

Pavel Galashin ◽

Sam Hopkins ◽

Thomas McConville ◽

Alexander Postnikov

Keyword(s):

Weyl Group ◽

Root System ◽

Dynkin Diagram ◽

Positive Root ◽

Root Systems ◽

Initial Weight ◽

Fundamental Weight ◽

Chip Firing ◽

Number Game

Abstract Jim Propp recently proposed a labeled version of chip-firing on a line and conjectured that this process is confluent from some initial configurations. This was proved by Hopkins–McConville–Propp. We reinterpret Propp’s labeled chip-firing moves in terms of root systems; a “central-firing” move consists of replacing a weight $\lambda$ by $\lambda +\alpha$ for any positive root $\alpha$ that is orthogonal to $\lambda$. We show that central-firing is always confluent from any initial weight after modding out by the Weyl group, giving a generalization of unlabeled chip-firing on a line to other types. For simply-laced root systems we describe this unlabeled chip-firing as a number game on the Dynkin diagram. We also offer a conjectural classification of when central-firing is confluent from the origin or a fundamental weight.

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A LINEAR SYSTEM ON NARUKI'S MODULI SPACE OF MARKED CUBIC SURFACES

International Journal of Mathematics ◽

10.1142/s0129167x0200123x ◽

2002 ◽

Vol 13 (02) ◽

pp. 183-208 ◽

Cited By ~ 4

Author(s):

BERT VAN GEEMEN

Keyword(s):

Linear System ◽

Projective Space ◽

Weyl Group ◽

Root System ◽

Moduli Space ◽

Automorphic Forms ◽

Cubic Surfaces ◽

Ball Quotients ◽

Dimensional Projective Space

Allcock and Freitag recently showed that the moduli space of marked cubic surfaces is a subvariety of a nine dimensional projective space which is defined by cubic equations. They used the theory of automorphic forms on ball quotients to obtain these results. Here we describe the same embedding using Naruki's toric model of the moduli space. We also give an explicit parametrization of the tritangent divisors, we discuss another way to find equations for the image and we show that the moduli space maps, with degree at least ten, onto the unique quintic hypersurface in a five dimensional projective space which is invariant under the action of the Weyl group of the root system E6.

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