Character (mathematics)

Last updated November 28, 2022

In mathematics, a character is (most commonly) a special kind of function from a group to a field (such as the complex numbers). There are at least two distinct, but overlapping meanings.^[1] Other uses of the word "character" are almost always qualified.

Multiplicative character

A multiplicative character (or linear character, or simply character) on a group G is a group homomorphism from G to the multiplicative group of a field ( Artin 1966 ), usually the field of complex numbers. If G is any group, then the set Ch(G) of these morphisms forms an abelian group under pointwise multiplication.

This group is referred to as the character group of G. Sometimes only unitary characters are considered (thus the image is in the unit circle); other such homomorphisms are then called quasi-characters. Dirichlet characters can be seen as a special case of this definition.

Multiplicative characters are linearly independent, i.e. if $\chi _{1},\chi _{2},\ldots ,\chi _{n}$ are different characters on a group G then from $a_{1}\chi _{1}+a_{2}\chi _{2}+\dots +a_{n}\chi _{n}=0$ it follows that $a_{1}=a_{2}=\cdots =a_{n}=0$ .

Character of a representation

The character $\chi :G\to F$ of a representation $\phi \colon G\to \mathrm {GL} (V)$ of a group G on a finite-dimensional vector space V over a field F is the trace of the representation $\phi$ ( Serre 1977 ), i.e.

\chi _{\phi }(g)=\operatorname {Tr} (\phi (g))

for

g\in G

In general, the trace is not a group homomorphism, nor does the set of traces form a group. The characters of one-dimensional representations are identical to one-dimensional representations, so the above notion of multiplicative character can be seen as a special case of higher-dimensional characters. The study of representations using characters is called "character theory" and one-dimensional characters are also called "linear characters" within this context.

Alternative definition

If restricted to finite abelian group with $1\times 1$ representation in $\mathbb {C}$ (i.e. $\mathrm {GL} (V)=\mathrm {GL} (1,\mathbb {C} )$ ), the following alternative definition would be equivalent to the above (For abelian groups, every matrix representation decomposes into a direct sum of $1\times 1$ representations. For non-abelian groups, the original definition would be more general than this one):

A character $\chi$ of group $(G,\cdot )$ is a group homomorphism $\chi :G\rightarrow \mathbb {C} ^{*}$ i.e. $\chi (x\cdot y)=\chi (x)\chi (y)$ for all $x,y\in G.$

If $G$ is a finite abelian group, the characters play the role of harmonics. For infinite abelian groups, the above would be replaced by $\chi :G\to \mathbb {T}$ where $\mathbb {T}$ is the circle group.

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<span class="mw-page-title-main">Lie algebra</span> Vector space with a binary operation satisfying the Jacobi identity

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<span class="mw-page-title-main">Lie group</span> Group that is also a differentiable manifold with group operations that are smooth

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<span class="mw-page-title-main">Adjoint representation</span>

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In mathematics, the Grothendieck group, or group of differences, of a commutative monoid $M$ is a certain abelian group. This abelian group is constructed from $M$ in the most universal way, in the sense that any abelian group containing a homomorphic image of $M$ will also contain a homomorphic image of the Grothendieck group of $M$ . The Grothendieck group construction takes its name from a specific case in category theory, introduced by Alexander Grothendieck in his proof of the Grothendieck–Riemann–Roch theorem, which resulted in the development of K-theory. This specific case is the monoid of isomorphism classes of objects of an abelian category, with the direct sum as its operation.

<span class="mw-page-title-main">Classical group</span>

In mathematics, the classical groups are defined as the special linear groups over the reals $R$ , the complex numbers $C$ and the quaternions $H$ together with special automorphism groups of symmetric or skew-symmetric bilinear forms and Hermitian or skew-Hermitian sesquilinear forms defined on real, complex and quaternionic finite-dimensional vector spaces. Of these, the complex classical Lie groups are four infinite families of Lie groups that together with the exceptional groups exhaust the classification of simple Lie groups. The compact classical groups are compact real forms of the complex classical groups. The finite analogues of the classical groups are the classical groups of Lie type. The term "classical group" was coined by Hermann Weyl, it being the title of his 1939 monograph The Classical Groups.

Representation theory is a branch of mathematics that studies abstract algebraic structures by representing their elements as linear transformations of vector spaces, and studies modules over these abstract algebraic structures. In essence, a representation makes an abstract algebraic object more concrete by describing its elements by matrices and their algebraic operations. The theory of matrices and linear operators is well-understood, so representations of more abstract objects in terms of familiar linear algebra objects helps glean properties and sometimes simplify calculations on more abstract theories.

<span class="mw-page-title-main">Complexification (Lie group)</span> Universal construction of a complex Lie group from a real Lie group

In mathematics, the complexification or universal complexification of a real Lie group is given by a continuous homomorphism of the group into a complex Lie group with the universal property that every continuous homomorphism of the original group into another complex Lie group extends compatibly to a complex analytic homomorphism between the complex Lie groups. The complexification, which always exists, is unique up to unique isomorphism. Its Lie algebra is a quotient of the complexification of the Lie algebra of the original group. They are isomorphic if the original group has a quotient by a discrete normal subgroup which is linear.

In mathematics, Lie group–Lie algebra correspondence allows one to correspond a Lie group to a Lie algebra or vice versa, and study the conditions for such a relationship. Lie groups that are isomorphic to each other have Lie algebras that are isomorphic to each other, but the converse is not necessarily true. One obvious counterexample is $and which are non-isomorphic to each other as Lie groups but their Lie algebras are isomorphic to each other. However, by restricting our attention to the simply connected Lie groups, the Lie group-Lie algebra correspondence will be one-to-one.$

This is a glossary of representation theory in mathematics.

<span class="mw-page-title-main">Glossary of Lie groups and Lie algebras</span>

This is a glossary for the terminology applied in the mathematical theories of Lie groups and Lie algebras. For the topics in the representation theory of Lie groups and Lie algebras, see Glossary of representation theory. Because of the lack of other options, the glossary also includes some generalizations such as quantum group.

References

↑ "character in nLab". ncatlab.org. Retrieved 2017-10-31.

Artin, Emil (1966), Galois Theory, Notre Dame Mathematical Lectures, number 2, Arthur Norton Milgram (Reprinted Dover Publications, 1997), ISBN 978-0-486-62342-9 Lectures Delivered at the University of Notre Dame
Serre, Jean-Pierre (1977), Linear Representations of Finite Groups , Graduate Texts in Mathematics, vol. 42, Translated from the second French edition by Leonard L. Scott, New York-Heidelberg: Springer-Verlag, doi:10.1007/978-1-4684-9458-7, ISBN 0-387-90190-6, MR 0450380

External links

"Character of a group", Encyclopedia of Mathematics , EMS Press, 2001 [1994]

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[1] "character in nLab". ncatlab.org. Retrieved 2017-10-31.

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