Quantization of canonical bases and the quantum symplectic double

AbstractThis paper develops a general theory of canonical bases and how they arise naturally in the context of categorification. As an application, we show that Lusztig’s canonical basis in the whole quantized universal enveloping algebra is given by the classes of the indecomposable 1-morphisms in a categorification when the associated Lie algebra is of finite type and simply laced. We also introduce natural categories whose Grothendieck groups correspond to the tensor products of lowest- and highest-weight integrable representations. This generalizes past work of the author’s in the highest-weight case.

Download Full-text

Canonical bases of modified quantum algebras for type A2

Journal of Algebra and Its Applications ◽

10.1142/s021949881850113x ◽

2018 ◽

Vol 17 (06) ◽

pp. 1850113

Author(s):

Weideng Cui

Keyword(s):

Canonical Basis ◽

Quantum Algebra ◽

Explicit Description ◽

Quantum Algebras ◽

Canonical Bases ◽

Type Formula

The modified quantum algebra [Formula: see text] associated to a quantum algebra [Formula: see text] was introduced by Lusztig. [Formula: see text] has a remarkable basis, which was defined by Lusztig, called the canonical basis. In this paper, we give an explicit description of all elements of the canonical basis of [Formula: see text] for type [Formula: see text].

Download Full-text

ON CANONICAL BASES AND INDUCTION OF -GRAPHS

Nagoya Mathematical Journal ◽

10.1017/nmj.2018.26 ◽

2018 ◽

Vol 239 ◽

pp. 1-41

Author(s):

JOHANNES HAHN

Keyword(s):

Coxeter Groups ◽

Canonical Basis ◽

Hecke Algebras ◽

Free Module ◽

Base Change ◽

Manuscripta Math ◽

Laurent Polynomials ◽

Graph Algebras ◽

Canonical Bases ◽

Change Matrix

A canonical basis in the sense of Lusztig is a basis of a free module over a ring of Laurent polynomials that is invariant under a certain semilinear involution and is obtained from a fixed “standard basis” through a triangular base change matrix with polynomial entries whose constant terms equal the identity matrix. Among the better known examples of canonical bases are the Kazhdan–Lusztig basis of Iwahori–Hecke algebras (see Kazhdan and Lusztig, Representations of Coxeter groups and Hecke algebras, Invent. Math. 53 (1979), 165–184), Lusztig’s canonical basis of quantum groups (see Lusztig, Canonical bases arising from quantized enveloping algebras, J. Amer. Math. Soc. 3(2) (1990), 447–498) and the Howlett–Yin basis of induced $W$-graph modules (see Howlett and Yin, Inducing W-graphs I, Math. Z. 244(2) (2003), 415–431; Inducing W-graphs II, Manuscripta Math. 115(4) (2004), 495–511). This paper has two major theoretical goals: first to show that having bases is superfluous in the sense that canonicalization can be generalized to nonfree modules. This construction is functorial in the appropriate sense. The second goal is to show that Howlett–Yin induction of $W$-graphs is well-behaved a functor between module categories of $W$-graph algebras that satisfies various properties one hopes for when a functor is called “induction,” for example transitivity and a Mackey theorem.

Download Full-text

The Integral Quantum Loop Algebra of $\mathfrak {gl}_{n}$

International Mathematics Research Notices ◽

10.1093/imrn/rnx300 ◽

2018 ◽

Vol 2019 (20) ◽

pp. 6179-6215 ◽

Cited By ~ 2

Author(s):

Jie Du ◽

Qiang Fu

Keyword(s):

Canonical Basis ◽

Alternative Algebra ◽

Integral Form ◽

Loop Algebra ◽

Algebra Structure ◽

Schur Algebras ◽

Canonical Bases ◽

Weyl Duality ◽

Integral Quantum

Abstract We will construct the Lusztig form for the quantum loop algebra of $\mathfrak {gl}_{n}$ by proving the conjecture [4, 3.8.6] and establish partially the Schur–Weyl duality at the integral level in this case. We will also investigate the integral form of the modified quantum affine $\mathfrak {gl}_{n}$ by introducing an affine stabilisation property and will lift the canonical bases from affine quantum Schur algebras to a canonical basis for this integral form. As an application of our theory, we will also discuss the integral form of the modified extended quantum affine $\mathfrak {sl}_{n}$ and construct its canonical basis to provide an alternative algebra structure related to a conjecture of Lusztig in [29, §9.3], which has been already proved in [34].

Download Full-text

Positivity of Canonical Bases Under Comultiplication

International Mathematics Research Notices ◽

10.1093/imrn/rnz047 ◽

2019 ◽

Author(s):

Zhaobing Fan ◽

Yiqiang Li

Keyword(s):

Canonical Basis ◽

Canonical Bases

Abstract We show the positivity of the canonical basis for a modified quantum affine $\mathfrak{sl}_n$ under the comultiplication. Moreover, we establish the positivity of the i-canonical basis in [21] with respect to the coideal subalgebra structure.

Download Full-text

Canonical Bases of Borcherds-Cartan Type

Nagoya Mathematical Journal ◽

10.1017/s0027763000009661 ◽

2009 ◽

Vol 194 ◽

pp. 169-193 ◽

Cited By ~ 3

Author(s):

Yiqiang Li ◽

Zongzhu Lin

Keyword(s):

Canonical Basis ◽

Cartan Matrix ◽

Moody Algebra ◽

Negative Part ◽

Canonical Bases ◽

Cartan Type

AbstractWe study the canonical basis for the negative part U- of the quantum generalized Kac-Moody algebra associated to a symmetric Borcherds-Cartan matrix. The algebras U- associated to two different matrices satisfying certain conditions may coincide (6.3). We show that the canonical bases coincide provided that the algebras U- coincide (Theorem 6.3.5). We also answer partially a question by Lusztig in [L3] (Theorem 7.1.1).

Download Full-text

Multiplication Formulas and Canonical Bases for Quantum Affine gln

Canadian Journal of Mathematics ◽

10.4153/cjm-2017-009-4 ◽

2018 ◽

Vol 70 (4) ◽

pp. 773-803 ◽

Cited By ~ 1

Author(s):

Jie Du ◽

Zhonghua Zhao

Keyword(s):

Quantum Group ◽

Canonical Basis ◽

Recursive Formula ◽

Loop Algebra ◽

Hall Algebra ◽

Monomial Basis ◽

Multiplication Formula ◽

Canonical Bases ◽

Theoretic Proof ◽

Cyclic Quiver

AbstractWe will give a representation-theoretic proof for the multiplication formula in the Ringel-Hall algebra of a cyclic quiver Δ(n). As a first application, we see immediately the existence of Hall polynomials for cyclic quivers, a fact established by J. Y. Guo and C. M. Ringel, and derive a recursive formula to compute them. We will further use the formula and the construction of a monomial basis for given by Deng, Du, and Xiao together with the double Ringel-Hall algebra realisation of the quantum loop algebra given by Deng, Du, and Fu to develop some algorithms and to compute the canonical basis for . As examples, we will show explicitly the part of the canonical basis associated with modules of Lowey length at most 2 for the quantum group .

Download Full-text

Hilbert space methods in the theory of Jordan algebras. II

Mathematical Proceedings of the Cambridge Philosophical Society ◽

10.1017/s0305004100052300 ◽

1976 ◽

Vol 79 (2) ◽

pp. 307-319 ◽

Cited By ~ 5

Author(s):

C. Viola Devapakkiam ◽

P. S. Rema

Keyword(s):

Hilbert Space ◽

Jordan Algebra ◽

Canonical Basis ◽

Classification Problem ◽

Jordan Algebras ◽

Type I ◽

Type Ii ◽

Canonical Bases ◽

Finite Dimensional ◽

Jordan Isomorphism

In this paper we consider the classification problem for separable special simple J*-algebras (cf. (8)). We show, using a result of Ancochea, that if is the (finite-dimensional) Jordan algebra of all complex n × n matrices and ø a Jordan isomorphism of onto a special J*-algebra J then An can be given the structure of an H*-algebra such that ø is a *-preserving isomorphism of the J*-algebra onto J. This result enables us to construct explicitly a canonical basis for a finite-dimensional simple special J*-algebra isomorphic to a Jordan algebra of type I from which we also obtain canonical bases for special simple finite-dimensional J*-algebras isomorphic to Jordan algebras of type II and III.

Download Full-text

The cluster basis $\mathbb{Z}[x_{1,1},…,x_{3,3}]

Discrete Mathematics & Theoretical Computer Science ◽

10.46298/dmtcs.3598 ◽

2008 ◽

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

Author(s):

Mark Skandera

Keyword(s):

Cluster Algebra ◽

Canonical Basis ◽

Transition Matrices ◽

Canonical Bases ◽

Basis Element ◽

Dual Canonical Basis ◽

Nous Montrons ◽

International Audience

International audience We show that the set of cluster monomials for the cluster algebra of type $D_4$ contains a basis of the $\mathbb{Z}$-module $\mathbb{Z}[x_{1,1},\ldots ,x_{3,3}]$. We also show that the transition matrices relating this cluster basis to the natural and the dual canonical bases are unitriangular and nonnegative. These results support a conjecture of Fomin and Zelevinsky on the equality of the cluster and dual canonical bases. In the event that this conjectured equality is true, our results also imply an explicit factorization of each dual canonical basis element as a product of cluster variables. Nous montrons que l'ensemble des monômes de l'algebre "cluster'' $D_4$ contient une base-$\mathbb{Z}$ pour le module $\mathbb{Z}[x_{1,1},\ldots ,x_{3,3}]$. Nous montrons aussi que les matrices transitoires qui relient cette base à la base canonique duale sont unitriangulaires. Ces résultats renforcent une conjecture de Fomin et de Zelevinsky sur l'égalité de ces deux bases. Si cette égalité s'avérait être vraie, notre résultat donnerait aussi une factorisation des éléments de la base canonique duale.

Download Full-text

An Algorithm to Compute the Canonical Basis of an Irreducible Module Over a Quantized Enveloping Algebra

LMS Journal of Computation and Mathematics ◽

10.1112/s1461157000000401 ◽

2003 ◽

Vol 6 ◽

pp. 105-118 ◽

Cited By ~ 1

Author(s):

Willem A. de Graaf

Keyword(s):

Tensor Product ◽

Lie Algebra ◽

Canonical Basis ◽

Irreducible Module ◽

Semisimple Lie Algebra ◽

Canonical Bases ◽

Enveloping Algebra ◽

Finite Dimensional ◽

Quantized Enveloping Algebra

AbstractThe paper describes an algorithm to compute the canonical basis of an irreducible module over a quantized enveloping algebra of a finite-dimensional semisimple Lie algebra. The algorithm works for any module that is constructed as a submodule of a tensor product of modules with known canonical bases.

Download Full-text