Finite dimensional representations of the quantum analog of the enveloping algebra of a complex simple Lie algebra

In this paper, we investigate a conjecture of Dixmier [2] on the structure of basic cycles. Our interest in basic cycles arises primarily from the fact that the irreducible modules of a simple Lie algebra L having a weight space decomposition are completely determined by the irreducible modules of the cycle subalgebra of L. The basic cycles form a generating set for the cycle subalgebra.First some notation: F denotes an algebraically closed field of characteristic 0, L a finite dimensional simple Lie algebra of rank n over F, H a fixed Cartan subalgebra, U(L) the universal enveloping algebra of L, C(L) the centralizer of H in U(L), Φ the set of nonzero roots in H*, the dual space of H, Δ = {α1, …, αn} a base of Φ, and Φ+ = {β1, …, βm} the positive roots corresponding to Δ.

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CONSTRUCTIVE NONCOMMMUTATIVE INVARIANT THEORY

Transformation Groups ◽

10.1007/s00031-021-09643-2 ◽

2021 ◽

Author(s):

MÁTYÁS DOMOKOS ◽

VESSELIN DRENSKY

Keyword(s):

Lie Algebra ◽

Associative Algebra ◽

Invariant Theory ◽

Reductive Group ◽

Symmetric Tensor ◽

Free Associative Algebra ◽

Tensor Algebra ◽

Enveloping Algebra ◽

Finite Dimensional ◽

Degree Bounds

AbstractThe problem of finding generators of the subalgebra of invariants under the action of a group of automorphisms of a finite-dimensional Lie algebra on its universal enveloping algebra is reduced to finding homogeneous generators of the same group acting on the symmetric tensor algebra of the Lie algebra. This process is applied to prove a constructive Hilbert–Nagata Theorem (including degree bounds) for the algebra of invariants in a Lie nilpotent relatively free associative algebra endowed with an action induced by a representation of a reductive group.

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PERIODIC AUTOMORPHISMS, COMPATIBLE POISSON BRACKETS, AND GAUDIN SUBALGEBRAS

Transformation Groups ◽

10.1007/s00031-021-09650-3 ◽

2021 ◽

Author(s):

DMITRI I. PANYUSHEV ◽

OKSANA S. YAKIMOVA

Keyword(s):

Poisson Bracket ◽

Lie Algebra ◽

Invariant Theory ◽

Cyclic Permutation ◽

Poisson Brackets ◽

Enveloping Algebra ◽

Order Automorphism ◽

Finite Dimensional ◽

Compatible Poisson Brackets ◽

Commutative Subalgebras

AbstractLet 𝔮 be a finite-dimensional Lie algebra. The symmetric algebra (𝔮) is equipped with the standard Lie–Poisson bracket. In this paper, we elaborate on a surprising observation that one naturally associates the second compatible Poisson bracket on (𝔮) to any finite order automorphism ϑ of 𝔮. We study related Poisson-commutative subalgebras (𝔮; ϑ) of 𝒮(𝔮) and associated Lie algebra contractions of 𝔮. To obtain substantial results, we have to assume that 𝔮 = 𝔤 is semisimple. Then we can use Vinberg’s theory of ϑ-groups and the machinery of Invariant Theory.If 𝔤 = 𝔥⊕⋯⊕𝔥 (sum of k copies), where 𝔥 is simple, and ϑ is the cyclic permutation, then we prove that the corresponding Poisson-commutative subalgebra (𝔮; ϑ) is polynomial and maximal. Furthermore, we quantise this (𝔤; ϑ) using a Gaudin subalgebra in the enveloping algebra 𝒰(𝔤).

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AUTOMORPHISMS OF CERTAIN NILPOTENT LIE ALGEBRAS OVER COMMUTATIVE RINGS

International Journal of Algebra and Computation ◽

10.1142/s021819670700372x ◽

2007 ◽

Vol 17 (03) ◽

pp. 527-555 ◽

Cited By ~ 5

Author(s):

YOU'AN CAO ◽

DEZHI JIANG ◽

JUNYING WANG

Keyword(s):

Automorphism Group ◽

Commutative Ring ◽

Lie Algebra ◽

Lie Algebras ◽

Commutative Rings ◽

Nilpotent Lie Algebras ◽

Simple Lie Algebra ◽

Finite Dimensional ◽

Positive Roots ◽

Nilpotent Subalgebra

Let L be a finite-dimensional complex simple Lie algebra, Lℤ be the ℤ-span of a Chevalley basis of L and LR = R⊗ℤLℤ be a Chevalley algebra of type L over a commutative ring R. Let [Formula: see text] be the nilpotent subalgebra of LR spanned by the root vectors associated with positive roots. The aim of this paper is to determine the automorphism group of [Formula: see text].

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Weyl modules and Weyl functors for hyper-map algebras

Journal of Algebra and Its Applications ◽

10.1142/s0219498821400077 ◽

2020 ◽

pp. 2140007

Author(s):

Angelo Bianchi ◽

Samuel Chamberlin

Keyword(s):

Lie Algebra ◽

Finitely Generated ◽

Weyl Modules ◽

Simple Lie Algebra ◽

Finite Dimensional ◽

Universal Properties ◽

Definition Of ◽

Unitary Algebra

We investigate the representations of the hyperalgebras associated to the map algebras [Formula: see text], where [Formula: see text] is any finite-dimensional complex simple Lie algebra and [Formula: see text] is any associative commutative unitary algebra with a multiplicatively closed basis. We consider the natural definition of the local and global Weyl modules, and the Weyl functor for these algebras. Under certain conditions, we prove that these modules satisfy certain universal properties, and we also give conditions for the local or global Weyl modules to be finite-dimensional or finitely generated, respectively.

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A note on the zeroth products of Frenkel–Jing operators

Journal of Algebra and Its Applications ◽

10.1142/s0219498817500530 ◽

2017 ◽

Vol 16 (03) ◽

pp. 1750053 ◽

Cited By ~ 2

Author(s):

Slaven Kožić

Keyword(s):

Lie Algebra ◽

Vertex Operator ◽

Vertex Operator Algebra ◽

Vertex Algebra ◽

Infinite Dimensional ◽

Enveloping Algebra ◽

Highest Weight ◽

Finite Dimensional ◽

Quantum Vertex ◽

Algebra Theory

Let [Formula: see text] be an untwisted affine Kac–Moody Lie algebra. The top of every irreducible highest weight integrable [Formula: see text]-module is the finite-dimensional irreducible [Formula: see text]-module, where the action of the simple Lie algebra [Formula: see text] is given by zeroth products arising from the underlying vertex operator algebra theory. Motivated by this fact, we consider zeroth products of level [Formula: see text] Frenkel–Jing operators corresponding to Drinfeld realization of the quantum affine algebra [Formula: see text]. By applying these products, which originate from the quantum vertex algebra theory developed by Li, on the extension of Koyama vertex operator [Formula: see text], we obtain an infinite-dimensional vector space [Formula: see text]. Next, we introduce an associative algebra [Formula: see text], a certain quantum analogue of the universal enveloping algebra [Formula: see text], and construct some infinite-dimensional [Formula: see text]-modules [Formula: see text] corresponding to the finite-dimensional irreducible [Formula: see text]-modules [Formula: see text]. We show that the space [Formula: see text] carries a structure of an [Formula: see text]-module and, furthermore, we prove that the [Formula: see text]-module [Formula: see text] is isomorphic to the [Formula: see text]-module [Formula: see text].

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Hom-structures on semi-simple Lie algebras

Open Mathematics ◽

10.1515/math-2015-0059 ◽

2015 ◽

Vol 13 (1) ◽

Cited By ~ 5

Author(s):

Wenjuan Xie ◽

Quanqin Jin ◽

Wende Liu

Keyword(s):

Lie Algebra ◽

Lie Algebras ◽

Jacobi Identity ◽

Algebra Homomorphism ◽

Closed Field ◽

Simple Lie Algebras ◽

3 Dimensional ◽

Simple Lie Algebra ◽

Finite Dimensional ◽

Reduction Methods

AbstractA Hom-structure on a Lie algebra (g,[,]) is a linear map σ W g σ g which satisfies the Hom-Jacobi identity: [σ(x), [y,z]] + [σ(y), [z,x]] + [σ(z),[x,y]] = 0 for all x; y; z ∈ g. A Hom-structure is referred to as multiplicative if it is also a Lie algebra homomorphism. This paper aims to determine explicitly all the Homstructures on the finite-dimensional semi-simple Lie algebras over an algebraically closed field of characteristic zero. As a Hom-structure on a Lie algebra is not necessarily a Lie algebra homomorphism, the method developed for multiplicative Hom-structures by Jin and Li in [J. Algebra 319 (2008): 1398–1408] does not work again in our case. The critical technique used in this paper, which is completely different from that in [J. Algebra 319 (2008): 1398– 1408], is that we characterize the Hom-structures on a semi-simple Lie algebra g by introducing certain reduction methods and using the software GAP. The results not only improve the earlier ones in [J. Algebra 319 (2008): 1398– 1408], but also correct an error in the conclusion for the 3-dimensional simple Lie algebra sl2. In particular, we find an interesting fact that all the Hom-structures on sl2 constitute a 6-dimensional Jordan algebra in the usual way.

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A combinatorial identity for the derivative of a theta series of a finite type root lattice

Nagoya Mathematical Journal ◽

10.1017/s002776300000862x ◽

2003 ◽

Vol 172 ◽

pp. 1-30

Author(s):

Satoshi Naito

Keyword(s):

Representation Theory ◽

Lie Algebra ◽

Finite Type ◽

Cartan Subalgebra ◽

Theta Series ◽

Combinatorial Identity ◽

Root Lattice ◽

Simple Lie Algebra ◽

Finite Dimensional ◽

Affine Lie Algebra

AbstractLet be a (not necessarily simply laced) finite-dimensional complex simple Lie algebra with the Cartan subalgebra and Q ⊂ * the root lattice. Denote by ΘQ(q) the theta series of the root lattice Q of . We prove a curious “combinatorial” identity for the derivative of ΘQ(q), i.e. for by using the representation theory of an affine Lie algebra.

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Canonical bases and standard monomials

Proceedings of the Edinburgh Mathematical Society ◽

10.1017/s0013091500019921 ◽

1998 ◽

Vol 41 (3) ◽

pp. 611-623

Author(s):

R. J. Marsh

Keyword(s):

Lie Algebra ◽

Canonical Basis ◽

Monomial Basis ◽

Fundamental Weight ◽

Enveloping Algebra ◽

Highest Weight ◽

Finite Dimensional ◽

Standard Monomials ◽

Standard Monomial ◽

Quantized Enveloping Algebra

Let U be the quantized enveloping algebra associated to a simple Lie algebra g by Drinfel'd and Jimbo. Let λ be a classical fundamental weight for g, and ⋯(λ) the irreducible, finite-dimensional type 1 highest weight U-module with highest weight λ. We show that the canonical basis for ⋯(λ) (see Kashiwara [6, §0] and Lusztig [18, 14.4.12]) and the standard monomial basis (see [11, §§2.4 and 2.5]) for ⋯(λ) coincide.

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Normality in Elementary Subgroups of Chevalley Groups Over Rings

Canadian Journal of Mathematics ◽

10.4153/cjm-1976-042-2 ◽

1976 ◽

Vol 28 (2) ◽

pp. 420-428 ◽

Cited By ~ 1

Author(s):

James F. Hurley

Keyword(s):

Normal Subgroup ◽

Commutative Ring ◽

Lie Algebra ◽

Chevalley Group ◽

Complex Field ◽

Normal Subgroups ◽

Chevalley Groups ◽

Simple Lie Algebra ◽

Elementary Subgroup ◽

Finite Dimensional

In [6] we have constructed certain normal subgroups G7 of the elementary subgroup GR of the Chevalley group G(L, R) over R corresponding to a finite dimensional simple Lie algebra L over the complex field, where R is a commutative ring with identity. The method employed was to augment somewhat the generators of the elementary subgroup EI of G corresponding to an ideal I of the underlying Chevalley algebra LR;EI is thus the group generated by all xr(t) in G having the property that ter ⊂ I. In [6, § 5] we noted that in general EI actually had to be enlarged for a normal subgroup of GR to be obtained.

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