Geometry of Hessenberg varieties with applications to Newton–Okounkov bodies

Abe, Hiraku; DeDieu, Lauren; Galetto, Federico; Harada, Megumi

doi:10.1007/s00029-018-0405-3

Cited by 26 publications

(49 citation statements)

References 39 publications

(76 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…which contains 6 elements. From Proposition 3.3 we obtain the formulas Vol(F (1, 1, 1)) = α (3,0,0) + α (2,1,0) + α (2,0,1) + α (1,2,0) + α (1,1,1) Vol(F (2, 1, 1)) = α (2,1,0) + 2α (1,2,0) + α (1,1,1) + 2α (0,3,0) + α (0,2,1)…”

Section: A Decomposition Of the Permutohedron Into Cubesmentioning

confidence: 97%

See 1 more Smart Citation

The Volume Polynomial of Regular Semisimple Hessenberg Varieties and the Gelfand—Zetlin Polytope

Harada

Horiguchi

Masuda

et al. 2019

Proc. Steklov Inst. Math.

Self Cite

View full text Add to dashboard Cite

Regular semisimple Hessenberg varieties are subvarieties of the flag variety Flag(C n ) arising naturally in the intersection of geometry, representation theory, and combinatorics. Recent results of Abe-Horiguchi-Masuda-Murai-Sato and Abe-DeDieu-Galetto-Harada relate the volume polynomials of regular semisimple Hessenberg varieties to the volume polynomial of the Gelfand-Zetlin polytope GZ(λ) for λ = (λ 1 , λ 2 , . . . , λn). The main results of this manuscript use and generalize tools developed by Anderson-Tymoczko, Kiritchenko-Smirnov-Timorin, and Postnikov, in order to derive an explicit formula for the volume polynomials of regular semisimple Hessenberg varieties in terms of the volumes of certain faces of the Gelfand-Zetlin polytope, and also exhibit a manifestly positive, combinatorial formula for their coefficients with respect to the basis of monomials in the α i := λ i − λ i+1 . In addition, motivated by these considerations, we carefully analyze the special case of the permutohedral variety, which is also known as the toric variety associated to Weyl chambers. In this case, we obtain an explicit decomposition of the permutohedron (the moment map image of the permutohedral variety) into combinatorial (n − 1)-cubes, and also give a geometric interpretation of this decomposition by expressing the cohomology class of the permutohedral variety in Flag(C n ) as a sum of the cohomology classes of a certain set of Richardson varieties.

show abstract

Section: A Decomposition Of the Permutohedron Into Cubesmentioning

confidence: 97%

“…Vol(F (1, 2, 1)) = α (2,0,1) + α (1,1,1) + α (1,0,2) Vol(F (3, 1, 1)) = α (2,0,1) + α (1,1,1) + α (1,0,2) Vol(F (2, 2, 1)) = α (1,2,0) + α (1,1,1) + 2α (0,3,0) + 2α (0,2,1) + α (0,1,2)…”

Section: A Decomposition Of the Permutohedron Into Cubesmentioning

confidence: 99%

The Volume Polynomial of Regular Semisimple Hessenberg Varieties and the Gelfand—Zetlin Polytope

Harada

Horiguchi

Masuda

et al. 2019

Proc. Steklov Inst. Math.

Self Cite

View full text Add to dashboard Cite

show abstract

“…, λ n } associated to the word i and the multiplicity list m by setting In this special case we will use the notation (3.9) L i,m := L i (m 1 β1 , · · · , m n βn ). 1 The Killing form is naturally defined on the Lie algebra of G but its restriction to the Lie algebra h of H is positive-definite, so we may identify…”

Section: Newton-okounkov Bodies Of Bott-samelson Varietiesmentioning

confidence: 99%

“…Finally, recent work of e.g. Abe, Horiguchi, Murai, Masuda, Sato [3] and others [1,2] suggest that there are interesting relationships between: the cohomology rings of Hessenberg varieties (which are certain subvarieties of the flag variety) and their associated volume polynomials, on the one hand, and string polytopes and (the volumes of unions of) their faces, on the other hand. Moreover, as in the Schubert calculus considerations of e.g.…”

Section: Introductionmentioning

confidence: 96%

Singular string polytopes and functorial resolutions from Newton–Okounkov bodies

Harada¹,

Yang²

2018

Illinois J. Math.

Self Cite

View full text Add to dashboard Cite

The main result of this note is that the toric degenerations of flag varieties associated to string polytopes and certain Bott-Samelson resolutions of flag varieties fit into a commutative diagram which gives a resolution of singularities of singular toric varieties corresponding to string polytopes. Our main tool is a result of Anderson which shows that the toric degenerations arising from Newton-Okounkov bodies are functorial in an appropriate sense. We also use results of Fujita which show that Newton-Okounkov bodies of Bott-Samelson varieties with respect to a certain valuation νmax coincide with generalized string polytopes, as well as previous results by the authors which explicitly describe the Newton-Okounkov bodies of Bott-Samelson varieties with respect to a different valuation ν min in terms of Grossberg-Karshon twisted cubes. A key step in our argument is that, under a technical condition, these Newton-Okounkov bodies coincide.

show abstract

“…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

Self Cite

View full text Add to dashboard Cite

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.

show abstract

Geometry of Hessenberg varieties with applications to Newton–Okounkov bodies

Cited by 26 publications

References 39 publications

The Volume Polynomial of Regular Semisimple Hessenberg Varieties and the Gelfand—Zetlin Polytope

The Volume Polynomial of Regular Semisimple Hessenberg Varieties and the Gelfand—Zetlin Polytope

Singular string polytopes and functorial resolutions from Newton–Okounkov bodies

Geometry of Regular Hessenberg Varieties

Contact Info

Product

Resources

About