Cellular algebra
In abstract algebra, a cellular algebra is a finite-dimensional associative algebra A with a distinguished cellular basis which is particularly well-adapted to studying the representation theory of A.
History
[edit]The cellular algebras discussed in this article were introduced in a 1996 paper of Graham and Lehrer.[1] However, the terminology had previously been used by Weisfeiler and Lehman in the Soviet Union in the 1960s, to describe what are also known as coherent algebras. [2][3][4]
Definitions
[edit]Let be a fixed commutative ring with unit. In most applications this is a field, but this is not needed for the definitions. Let also be an -algebra.
The concrete definition
[edit]A cell datum for is a tuple consisting of
- A finite partially ordered set .
- A -linear anti-automorphism with .
- For every a non-empty finite set of indices.
- An injective map
- The images under this map are notated with an upper index and two lower indices so that the typical element of the image is written as .
- and satisfying the following conditions:
- The image of is a -basis of .
- for all elements of the basis.
- For every , and every the equation
- with coefficients depending only on , and but not on . Here denotes the -span of all basis elements with upper index strictly smaller than .
This definition was originally given by Graham and Lehrer who invented cellular algebras.[1]
The more abstract definition
[edit]Let be an anti-automorphism of -algebras with (just called "involution" from now on).
A cell ideal of w.r.t. is a two-sided ideal such that the following conditions hold:
- .
- There is a left ideal that is free as a -module and an isomorphism
- of --bimodules such that and are compatible in the sense that
A cell chain for w.r.t. is defined as a direct decomposition
into free -submodules such that
- is a two-sided ideal of
- is a cell ideal of w.r.t. to the induced involution.
Now is called a cellular algebra if it has a cell chain. One can show that the two definitions are equivalent.[5] Every basis gives rise to cell chains (one for each topological ordering of ) and choosing a basis of every left ideal one can construct a corresponding cell basis for .
Examples
[edit]Polynomial examples
[edit]is cellular. A cell datum is given by and
- with the reverse of the natural ordering.
A cell-chain in the sense of the second, abstract definition is given by
Matrix examples
[edit]is cellular. A cell datum is given by and
- For the basis one chooses the standard matrix units, i.e. is the matrix with all entries equal to zero except the (s,t)-th entry which is equal to 1.
A cell-chain (and in fact the only cell chain) is given by
In some sense all cellular algebras "interpolate" between these two extremes by arranging matrix-algebra-like pieces according to the poset .
Further examples
[edit]Modulo minor technicalities all Iwahori–Hecke algebras of finite type are cellular w.r.t. to the involution that maps the standard basis as .[6] This includes for example the integral group algebra of the symmetric groups as well as all other finite Weyl groups.
A basic Brauer tree algebra over a field is cellular if and only if the Brauer tree is a straight line (with arbitrary number of exceptional vertices).[5]
Further examples include q-Schur algebras, the Brauer algebra, the Temperley–Lieb algebra, the Birman–Murakami–Wenzl algebra, the blocks of the Bernstein–Gelfand–Gelfand category of a semisimple Lie algebra.[5]
Representations
[edit]Cell modules and the invariant bilinear form
[edit]Assume is cellular and is a cell datum for . Then one defines the cell module as the free -module with basis and multiplication
where the coefficients are the same as above. Then becomes an -left module.
These modules generalize the Specht modules for the symmetric group and the Hecke-algebras of type A.
There is a canonical bilinear form which satisfies
for all indices .
One can check that is symmetric in the sense that
for all and also -invariant in the sense that
for all ,.
Simple modules
[edit]Assume for the rest of this section that the ring is a field. With the information contained in the invariant bilinear forms one can easily list all simple -modules:
Let and define for all . Then all are absolute simple -modules and every simple -module is one of these.
These theorems appear already in the original paper by Graham and Lehrer.[1]
Properties of cellular algebras
[edit]Persistence properties
[edit]- Tensor products of finitely many cellular -algebras are cellular.
- A -algebra is cellular if and only if its opposite algebra is.
- If is cellular with cell-datum and is an ideal (a downward closed subset) of the poset then (where the sum runs over and ) is a two-sided, -invariant ideal of and the quotient is cellular with cell datum (where i denotes the induced involution and M, C denote the restricted mappings).
- If is a cellular -algebra and is a unitary homomorphism of commutative rings, then the extension of scalars is a cellular -algebra.
- Direct products of finitely many cellular -algebras are cellular.
If is an integral domain then there is a converse to this last point:
- If is a finite-dimensional -algebra with an involution and a decomposition in two-sided, -invariant ideals, then the following are equivalent:
- is cellular.
- and are cellular.
- Since in particular all blocks of are -invariant if is cellular, an immediate corollary is that a finite-dimensional -algebra is cellular w.r.t. if and only if all blocks are -invariant and cellular w.r.t. .
- Tits' deformation theorem for cellular algebras: Let be a cellular -algebra. Also let be a unitary homomorphism into a field and the quotient field of . Then the following holds: If is semisimple, then is also semisimple.
If one further assumes to be a local domain, then additionally the following holds:
- If is cellular w.r.t. and is an idempotent such that , then the algebra is cellular.
Other properties
[edit]Assuming that is a field (though a lot of this can be generalized to arbitrary rings, integral domains, local rings or at least discrete valuation rings) and is cellular w.r.t. to the involution . Then the following hold
- is split, i.e. all simple modules are absolutely irreducible.
- The following are equivalent:[1]
- is semisimple.
- is split semisimple.
- is simple.
- is nondegenerate.
- The Cartan matrix of is symmetric and positive definite.
- The following are equivalent:[7]
- is quasi-hereditary (i.e. its module category is a highest-weight category).
- .
- All cell chains of have the same length.
- All cell chains of have the same length where is an arbitrary involution w.r.t. which is cellular.
- .
- If is Morita equivalent to and the characteristic of is not two, then is also cellular w.r.t. a suitable involution. In particular is cellular (to some involution) if and only if its basic algebra is.[8]
- Every idempotent is equivalent to , i.e. . If then in fact every equivalence class contains an -invariant idempotent.[5]
References
[edit]- ^ a b c d Graham, J.J; Lehrer, G.I. (1996), "Cellular algebras", Inventiones Mathematicae, 123: 1–34, Bibcode:1996InMat.123....1G, doi:10.1007/bf01232365, S2CID 189831103
- ^ Weisfeiler, B. Yu.; A. A., Lehman (1968). "Reduction of a graph to a canonical form and an algebra which appears in this process". Scientific-Technological Investigations. 2 (in Russian). 9: 12–16.
- ^ Higman, Donald G. (August 1987). "Coherent algebras". Linear Algebra and Its Applications. 93: 209-239. doi:10.1016/S0024-3795(87)90326-0. hdl:2027.42/26620.
- ^ Cameron, Peter J. (1999). Permutation Groups. London Mathematical Society Student Texts (45). Cambridge University Press. ISBN 978-0-521-65378-7.
- ^ a b c d 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 (3): 501–517, arXiv:math/0611941, Bibcode:2007InMat.169..501G, doi:10.1007/s00222-007-0053-2, S2CID 8111018
- ^ König, S.; Xi, C.C. (1999-06-24), "Cellular algebras and quasi-hereditary algebras: A comparison", Electronic Research Announcements of the American Mathematical Society, 5 (10): 71–75, doi:10.1090/S1079-6762-99-00063-3
- ^ König, S.; Xi, C.C. (1999), "Cellular algebras: inflations and Morita equivalences", Journal of the London Mathematical Society, 60 (3): 700–722, CiteSeerX 10.1.1.598.3299, doi:10.1112/s0024610799008212, S2CID 1664006