Group ring

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This page discusses the algebraic group ring of a discrete group; for the case of a topological group see group algebra.

In mathematics, a group ring is a ring R[G] constructed from a ring R and a multiplicative group G. Sometimes the group ring is written simply as RG.

As an R-module, the ring R[G] is the free module over R on the elements G. If R is a field K, the group ring is called a group algebra; it is a vector space over K, with the basis vectors given by the elements of G. The elements of the group ring are finite linear combinations of elements of G with coefficients in R. Multiplication is defined by the group operation in G extended by linearity and distributivity, and the requirement that elements of R commute with elements of G. The identity element of G is the multiplicative identity of the ring R[G].

If R is commutative, then R[G] is an associative algebra over R.

1 Definition
2 Properties
3 The case where G is finite
- 3.1 Representations
- 3.2 Center
4 The case where G is infinite
5 An Example
6 Representations
7 Category theory
8 Generalization
9 References

[edit] Definition

Let G be a group and R a ring. We first define the set RG to be one of the following:

The set of all formal R-linear combinations of elements of G.
The free R-module with basis G.
The set of all functions f: G → R with f(g) = 0 for all but finitely many g in G.

No matter which definition is used, we can write elements of RG in the form $\sum_{g \in G} a_g g$ , with all but finitely many of the a_g being 0, and an addition is defined on RG (by addition of formal linear combinations, addition in the module, or addition of functions, respectively). Multiplication of elements of RG is defined by setting

$(\sum_{g \in G} a_g g )( \sum_{h \in G} b_h h ) \ = \ \sum_{g,h \in G} (a_g b_h ) gh$

If R has a unit element, this is the unique bilinear multiplication for which (1 g)(1 h) = (1 gh). In this case, G is commonly identified with the elements 1 g of RG. The identity element of G then serves as the 1 in R[G].

R is commonly a commutative ring with unit, or even a field.

[edit] Properties

If R and G are both commutative (i.e., R is commutative and G is an abelian group), RG is commutative.

If H is a subgroup of G, then RH is a subring of RG. Similarly, if S is a subring of R, SG is a subring of RG.

[edit] The case where G is finite

If G is finite, and R is the field of complex numbers, RG is a semisimple ring. This result, Maschke's theorem, allows us to understand RG as a ring of matrices with entries in R.

Group algebras occur naturally in in the theory of group representations of finite groups. The group algebra $K [G]$ or $K G$ over a field $K$ is essentially the group ring, with the field $K$ taking the place of the ring. It is a vector space over the field, with the algebra structure on the vector space is defined as

$e_g \cdot e_h = e_{gh}$ .

The vector space is defined so that each basis vector $e g$ is simply in one-to one correspondence with the elements of the group $g\in G$ . That is, a general element of $K [G]$ may be written as

$r=\sum_{h\in G} k_h e_h$

where the $k_h \in K$ are just an arbitrary set of scalars indexed by $h\in G$ . Thus, the group algebra is essentially the regular representation of the group. It is the representation $g\mapsto\rho(g)$ with the action given by $\rho(g)\cdot e_h = e_{gh}$ , or

$\rho(g)\cdot r = \sum_{h\in G} k_h \rho(g)\cdot e_h = \sum_{h\in G} k_h e_{gh}$

The dimension of the vector space $K [G]$ is just equal to the number of elements in the group. The field $K$ is commonly taken to be the complex numbers $\mathbb{C}$ or the reals $\mathbb{R}$ , so that one discusses the group algebras $\mathbb{C}[G]$ or $\mathbb{R}[G]$ .

[edit] Representations

Taking $K [G]$ to be an abstract algebra, one may ask for concrete representations of the algebra over a vector space V. Such a representation $\tilde{\rho}$ is an algebra homomorphism

$\tilde{\rho}:K[G]\rightarrow \mbox{End} (V)$ .

from the group algebra to the set of endomorphisms on V. Taking V to be an abelian group, with group addition given by vector addition, such a representation in fact a left K[G]-module over the abelian group V. That this is so is exhibited below, where each axiom of a module is demonstrated.

Pick $r\in K[G]$ so that $\tilde{\rho}(r)$ is an element of $End(V)$ . Then $\tilde{\rho}(r)$ is a homomorphism of abelian groups, in that

$\tilde{\rho}(r) \cdot (v_1 +v_2) = \tilde{\rho}(r) \cdot v_1 + \tilde{\rho}(r) \cdot v_2$

for any $v_1, v_2\in V$ . Next, one notes that the set of endomorphisms of an abelian group is an endomorphism ring. The representation $\tilde{\rho}$ is a ring homomorphism, in that one has

$\tilde{\rho}(r+s)\cdot v = \tilde{\rho}(r)\cdot v + \tilde{\rho}(s)\cdot v$

for any two $r,s\in K[G]$ and $v\in V$ . Similarly, under multiplication,

$\tilde{\rho}(rs)\cdot v = \tilde{\rho}(r)\cdot \tilde{\rho}(s)\cdot v$

Finally, one has that the unit is mapped to the identity:

$\tilde{\rho}(1)\cdot v = v$

where 1 is the multiplicative unit of $K [G]$ ; that is, 1 is the vector $e e$ corresponding to the identity element e in G.

The last three equations show that $\tilde{\rho}$ is a ring homomorphism from $K [G]$ taken as a group ring, to the endomorphism ring. The first identity showed that individual elements are group homomorphisms. Thus, a representation $\tilde{\rho}$ is a left $K [G]$ -module over the abelian group V.

Note that given a general $K [G]$ -module, a vector-space structure is induced on V, in that one has an additional axiom

$\tilde{\rho}(ar) \cdot v_1 + \tilde{\rho}(br) \cdot v_2 = a \tilde{\rho}(r) \cdot v_1 + b \tilde{\rho}(r) \cdot v_2 = \tilde{\rho}(r) \cdot (av_1 +bv_2)$

for scalar $a,b\in K$

Any group representation $\rho:G\rightarrow \mbox{Aut}(V)$ , with V a vector space over the field $K$ , can be extended linearly to an algebra representation $\tilde{\rho}:K[G]\rightarrow \mbox{End}(V)$ , simply by mapping $\rho(g) \mapsto \tilde{\rho}(e_g)$ . Thus, representations of the group correspond exactly to representations of the algebra, and so, in a certain sense, talking about the one is the same as talking about the other.

[edit] Center

The center of the group algebra is the set of elements that commute with all elements of the group algebra:

$Z(K[G]) := \left\{ z \in K[G] \mid zr = rz \mbox{ for all } r \in K[G]\right\}$

[edit] The case where G is infinite

Much less is known in the case where G is infinite, and this is an area of active research. The case where R is the field of complex numbers is probably the one best studied. In this case, Irving Kaplansky proved that if a and b are elements of CG with ab = 1, then ba = 1. Whether this is true if R is a field of finite characteristic remains unknown.

If G is torsion-free, it is conjectured that CG has no nontrivial idempotents or zero divisors; this has been proven for special cases, such as the ones where G is abelian, elementary amenable, or free

[edit] An Example

Let G = Z₃, the cyclic group of 3 elements with generator a. Then an element of C[G] is

z₁ + z₂a + z₃a²,

where z₁, z₂ and z₃ are in $\mathbb{C}$ , the complex numbers. If we take another element

w₁ + w₂a + w₃a²,

then their sum is

(z₁+w₁) + (z₂+w₂)a + (z₃+w₃)a²

and their multiplication is

(z₁ + z₂a + z₃a²) (w₁ + w₂a + w₃a²)

= (z₁w₁ + z₂w₃ + z₃w₂) + (z₁w₂ + z₂w₁ + z₃w₃)a + (z₁w₃ + z₂w₂ + z₃w₁)a².

In an example where G is a non-commutative group, we have to be careful to make the multiplication of the terms in the right order.

An example of a group ring of an infinite group is the ring of Laurent polynomials: this is exactly the group ring of the infinite cyclic group Z.

[edit] Representations

A module M over R[G] is then the same as a linear representation of G over the field R. There is no particular reason to limit R to be a field here. However, the classical results were obtained first when R is the complex number field and G is a finite group, so this case deserves close attention. It was shown that R[G] is a semisimple ring, under those conditions, with profound implications for the representations of finite groups. More generally, whenever the characteristic of R does not divide the order of the finite group G, then R[G] is semisimple (Maschke's theorem).

When G is a finite abelian group, the group ring is commutative, and its structure easy to express in terms of roots of unity. When R is a field of characteristic p, and the prime number p divides the order of the finite group G, then the group ring is not semisimple: it has a non-zero Jacobson radical, and this gives the corresponding subject of modular representation theory its own, deeper character.

[edit] Category theory

There is an elegant characterization from category theory of the group ring construction with a fixed ring R as the left adjoint to the functor taking an associative R-algebra with one to its group of units.

[edit] Generalization

Group algebras are more general algebras which derive their multiplication from the multiplication in G.

[edit] References

A. A. Bovdi, "Group algebra" SpringerLink Encyclopaedia of Mathematics (2001)
C.W. Curtis, I. Reiner, Representation theory of finite groups and associative algebras , Interscience (1962)
D.S. Passman, The algebraic structure of group rings , Wiley (1977)

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Categories: Pages needing expert attention from Mathematics experts | Ring theory | Representation theory of groups | Harmonic analysis

Group ring

From Wikipedia, the free encyclopedia

Contents

[edit] Definition

[edit] Properties

[edit] The case where G is finite

[edit] Representations

[edit] Center

[edit] The case where G is infinite

[edit] An Example

[edit] Representations

[edit] Category theory

[edit] Generalization

[edit] References

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