User:AndrewReeves/Cellular algebra (draft article)
In algebraic representation theory, a cellular algebra is an algebra which has a basis with certain combinatorial properties. The existence of such a basis leads to a natural characterisation of the simple modules of the algebra. Cellular algebras are often quasi-hereditary, though this is not always the case.
The first definition of a cellular algebra was given in 1996 by J.J. Graham and G. I. Lehrer [1]. Later, S. König and C.C. Xi gave an alternative (but equivalent) definition[2]. In different applications, either one of the two definitions may turn out to be the more useful; the original definition is more combinatorial, the second is stated more in terms of abstract ring theory.
Examples of cellular algebras include the group algebra of the symmetric group, the Brauer algebra, all Hecke algebras of finite type[3], the Temperley-Lieb algebra and the Birman-Murakami-Wenzl algebra.
Definition
[edit]The original definition given by Graham and Lehrer is as follow:.
Let be a commutative ring and let be an -algebra free over . is cellular if there exists a (not necessarily unique) cell datum consisting of
such that the image of is an -basis of , the map extends -linearly to an antiautomorphism of and for any and every there exist such that
where denotes a linear combination of basis elements with
Representation Theory
[edit]Cell Modules
[edit]Suppose that is a cellular -algebra with cell datum (,,). Using the same notation as above, we can define for any a cell module . This is the module with -basis and algebra action defined by
for all and
For any cell module there is an -bilinear form given by . Graham and Lehrer[1] showed that this form is symmetric and invariant under the action of . Based on this they also showed how to extract all the simple modules of from the cell modules.
Simple Modules
[edit]Suppose that is a field and that is finite (which implies that is a finite dimensional algebra).
Define the radical . This is a submodule of the cell module , so the quotient is well-defined. It is trivial only when is identically zero.
Let be the set of all such that is not identically zero. Then a theorem of Graham and Lehrer[1] states that
- is absolutely irreducible for any ;
- is a complete set of representatives of the distinct isomorphism classes of simple -modules;
- The cell module is simple if and only if is non-degenerate on ;
- The following statements are equivalent:
- is a semisimple algebra;
- Every cell module of is absolutely irreducible;
- The forms are non-degenerate for every ;
An Alternative Characterisation
[edit]When Is A Cellular Algebra Quasi-Hereditary?
[edit]Further Reading
[edit]- Deng, B.; Du, J.; Parshall, B; Wang, J. (2008), Finite Dimensional Algebras and Quantum Groups, American Mathematical Society, pp. 699–726, ISBN 978-0821841860
- Mathas, Andrew (1999), Iwahori-Hecke Algebras and Schur Algebras of the Symmetric Group, University Lecture Series, American Mathematical Society, pp. 15–26, ISBN 978-0821819265
References
[edit]- ^ a b c Graham, J.J; Lehrer, G.I. (1996), "Cellular algebras", Inventiones Mathematicae, 123: 1–34
- ^ König, S.; Xi, C.C. (1996), "On the structure of cellular algebras", Algebras and modules II. CMS Conference Proceedings: 365–386
- ^ Geck, Meinolf (2007), "Hecke algebras of finite type are cellular", Inventiones mathematicae, 169: 501–517