The Cohomology Rings of Regular Nilpotent Hessenberg Varieties in Lie Type A

Abe, Hiraku; Harada, Megumi; Horiguchi, Tatsuya; Masuda, Mikiya

doi:10.1093/imrn/rnx275

Cited by 47 publications

(142 citation statements)

References 44 publications

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“…The Shareshian-Wachs conjecture was proved in 2015 by Brosnan and Chow [3] (also independently by Guay-Paquet [10]) by showing a remarkable relationship between the Betti numbers of different Hessenberg varieties. (Direct computations of cohomology rings of certain Hessenberg varieties also yield partial proofs of the Shareshian-Wachs conjecture; see [1,2].) It then follows that, in order to prove the graded Stanley-Stembridge conjecture, it suffices to prove that the cohomology H 2i (Hess(S, h)) for each i is a non-negative combination of the tabloid representations M λ [6, Part II, Section 7.2] of S n for λ a partition of n. In other words, given the decomposition (1.1) H 2i (Hess(S, h)) = λ⊢n c λ,i M λ in the representation ring Rep(S n ) of S n , the coefficients c λ,i are non-negative.…”

Section: Introductionmentioning

confidence: 99%

The cohomology of abelian Hessenberg varieties and the Stanley–Stembridge conjecture

Harada¹,

Precup²

2019

Algebraic Combinatorics

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We define a subclass of Hessenberg varieties called abelian Hessenberg varieties, inspired by the theory of abelian ideals in a Lie algebra developed by Kostant and Peterson. We give an inductive formula for the Sn-representation on the cohomology of an abelian regular semisimple Hessenberg variety with respect to the action defined by Tymoczko. Our result implies that a graded version of the Stanley-Stembridge conjecture holds in the abelian case, and generalizes results obtained by Shareshian-Wachs and Teff. Our proof uses previous work of Stanley, Gasharov, Shareshian-Wachs, and Brosnan-Chow, as well as results of the second author on the geometry and combinatorics of Hessenberg varieties. As part of our arguments, we obtain inductive formulas for the Poincaré polynomials of regular abelian Hessenberg varieties. THE SETUP AND BACKGROUNDLet n be a positive integer. We denote by [n] the set of positive integers {1, 2, . . . , n}. We work in type A throughout, so GL(n, C) is the group of invertible n × n complex matrices and gl(n, C) is the Lie algebra of GL(n, C) consisting of all n × n complex matrices.2.1. Hessenberg varieties. Hessenberg varieties in Lie type A are subvarieties of the (full) flag variety Fℓags(C n ), which is the collection of sequences of nested linear subspaces of C n :Fℓags(C n ) := {V • = ({0} ⊂ V 1 ⊂ V 2 ⊂ · · · V n−1 ⊂ V n = C n ) | dim C (V i ) = i for all i = 1, . . . , n}.

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Section: Introductionmentioning

confidence: 99%

The cohomology of abelian Hessenberg varieties and the Stanley–Stembridge conjecture

Harada¹,

Precup²

2019

Algebraic Combinatorics

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“…Note also that T * X carries a canonical symplectic form, with respect to which the cotangent lift action is Hamiltonian. One can define a moment map µ : T * X → g * by the property (5) (µ(x, γ))(z) = γ(z(x)), x ∈ X, γ ∈ T * x X, z ∈ g. Our discussion now turns to Poisson-geometric considerations, for which we let X be a smooth algebraic variety with structure sheaf O X . One calls X a Poisson variety if O X has been enriched to a sheaf of Poisson algebras, (O X , {·, ·}).…”

Section: Symplectic and Poisson Varietiesmentioning

confidence: 99%

“…It follows that the cotangent lifts of (32a) and (32b) are commuting Hamiltonian actions of G on T * G. We shall let µ L : T * G → g and µ R : T * G → g denote the moment maps for these respective cotangent lifts (see (5)).…”

Section: 2mentioning

confidence: 99%

Hessenberg varieties, Slodowy slices, and integrable systems

Abe

Crooks

2019

Math. Z.

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This work is intended to contextualize and enhance certain well-studied relationships between Hessenberg varieties and the Toda lattice, thereby building on the results of Kostant, Peterson, and others. One such relationship is the fact that every Lagrangian leaf in the Toda lattice is compactified by a suitable choice of Hessenberg variety. It is then natural to imagine the Toda lattice as extending to an appropriate union of Hessenberg varieties.We fix a simply-connected complex semisimple linear algebraic group G and restrict our attention to a particular family of Hessenberg varieties, a family that includes the Peterson variety and all Toda leaf compactifications. The total space of this family, X(H0), is shown to be a Poisson variety with a completely integrable system defined in terms of Mishchenko-Fomenko polynomials. This leads to a natural embedding of completely integrable systems from the Toda lattice to X(H0). We also show X(H0) to have an open dense symplectic leaf isomorphic to G/Z × Sreg, where Z is the centre of G and Sreg is a regular Slodowy slice in the Lie algebra of G. This allows us to invoke results about integrable systems on G × Sreg, as developed by Rayan and the second author. Lastly, we witness some implications of our work for the geometry of regular Hessenberg varieties. 10 3.2. The B-orbit stratification of V Toda 11 3.3. The Toda lattice 13 4. Symplectic geometry on G/Z × Sreg 14 4.

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“…A regular Hessenberg variety is the one defined by a regular element x in g, namely an element x ∈ g whose Lie algebra centralizer Z g (x) has the minimum possible dimension. There are two cases of regular Hessenberg varieties that are well-studied: (1) if s ∈ g is a regular semisimple element, then X(s, H) is called a regular semisimple Hessenberg variety; (2) if N 0 ∈ g is a regular nilpotent element, then X(N 0 , H) is called a regular nilpotent Hessenberg variety. For example, one can choose a Hessenberg space H so that X(s, H) is a toric variety and X(N 0 , H) is the Peterson variety (see Section 2.1 for details).…”

Section: Introductionmentioning

confidence: 99%

Geometry of Regular Hessenberg Varieties

Abe

Fujita

2020

Transformation Groups

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Let g be a complex semisimple Lie algebra. For a regular element x in g and a Hessenberg space H ⊆ g, we consider a regular Hessenberg variety X(x, H) in the flag variety associated with g. We take a Hessenberg space so that X(x, H) is irreducible, and show that the higher cohomology groups of the structure sheaf of X(x, H) vanish. We also study the flat family of regular Hessenberg varieties, and prove that the scheme-theoretic fibers over the closed points are reduced. We include applications of these results as well.

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The Cohomology Rings of Regular Nilpotent Hessenberg Varieties in Lie Type A

Cited by 47 publications

References 44 publications

The cohomology of abelian Hessenberg varieties and the Stanley–Stembridge conjecture

The cohomology of abelian Hessenberg varieties and the Stanley–Stembridge conjecture

Hessenberg varieties, Slodowy slices, and integrable systems

Geometry of Regular Hessenberg Varieties

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