Identity component

In mathematics, specifically group theory, the identity component of a group G refers to several closely related notions of the largest connected subgroup of G containing the identity element.
In point set topology, the identity component of a topological group G is the connected component G⁰ of G that contains the identity element of the group. The identity path component of a topological group G is the path component of G that contains the identity element of the group.
In algebraic geometry, the identity component of an algebraic group G over a field k is the identity component of the underlying topological space. The identity component of a group scheme G over a base scheme S is, roughly speaking, the group scheme G⁰ whose fiber over the point s of S is the connected component G_s⁰ of the fiber G_s, an algebraic group.

Properties

The identity component G⁰ of a topological or algebraic group G is a closed normal subgroup of G. It is closed since components are always closed. It is a subgroup since multiplication and inversion in a topological or algebraic group are continuous maps by definition. Moreover, for any continuous automorphism a of G we have
Thus, G⁰ is a characteristic subgroup of G, so it is normal.
By the same argument as above, the identity path component of a topological group is also a normal subgroup. It may in general be smaller than the identity component, but these agree if G is locally path-connected.
The identity component G⁰ of a topological group G need not be open in G. In fact, we may have G⁰ =, in which case G is totally disconnected. However, the identity component of a locally [path-connected space] is always open, since it contains a path-connected neighbourhood of ; and therefore is a clopen set.

Component group

The quotient group G/''G⁰ is called the group of components or component group of G''. Its elements are just the connected components of G. The component group G/''G⁰ is a discrete group if and only if G''⁰ is open. If G is an algebraic group of glossary of [algebraic geometry | finite type], such as an affine algebraic group, then G/''G⁰ is actually a finite group.
One may similarly define the path component group as the group of path components, and in general the component group is a quotient of the path component group, but if G'' is locally path connected these groups agree. The path component group can also be characterized as the zeroth homotopy group,

Examples

The group of non-zero real numbers with multiplication has two components and the group of components is.
Consider the group of units U in the ring of split-complex numbers. In the ordinary topology of the plane, U is divided into four components by the lines y = x and y = − x where z has no inverse. Then U⁰ = . In this case the group of components of U is isomorphic to the Klein four-group.
The identity component of the additive group of p-adic integers is the singleton set, since Z_p is totally disconnected.
The Weyl group of a reductive algebraic group G is the components group of the normalizer group of a maximal torus of G.
Consider the group scheme μ₂ = Spec of second roots of unity defined over the base scheme Spec. Topologically, μ_n consists of two copies of the curve Spec glued together at the point 2. Therefore, μ_n is connected as a topological space, hence as a scheme. However, μ₂ does not equal its identity component because the fiber over every point of Spec except 2 consists of two discrete points.

An algebraic group G over a topological field K admits two natural topologies, the Zariski topology and the topology inherited from K. The identity component of G often changes depending on the topology. For instance, the general linear group GL_n is connected as an algebraic group but has two path components as a Lie group, the matrices of positive determinant and the matrices of negative determinant. Any connected algebraic group over a non-Archimedean local field K is totally disconnected in the K-topology and thus has trivial identity component in that topology.