Fundamental group: Difference between revisions

This article defines an association of a group to every topological space. The association is not necessarily functorial

Definition

Basic definition

The fundamental group of a based topological space ${\displaystyle (X,x_0)}$ is defined as follows:

• As a set, it is the set of all homotopy classes of loops at ${\displaystyle x_0}$ in ${\displaystyle X}$
• The group structure is obtained as follows: the composite of two loops is obtained by first traversing the first loop, and then traversing the second loop. Explicitly, if ${\displaystyle f_1,f_2:[0,1]\to X}$ are the two loops, then the composite of these is the loop given by ${\displaystyle t\mapsto f_1(2t)}$ for ${\displaystyle 0\le t\le 1/2}$ and ${\displaystyle t\mapsto f_2(2t-1)}$ for ${\displaystyle 1/2\le t\le 1}$. Continuity of this new loop follows from the gluing lemma.

Proof that this gives a group structure

To prove that the multiplication defined above does give a group structure, we note that there is a homotopy between the identity map on ${\displaystyle [0,1]}$ and any increasing homeomorphism on it. Thus any reparametrization of a curve is homotopic to the original curve. This can be used to show that the composition operation defined above is associative on homotopy classes of loops.

The inverse of a path is the same path traversed in the opposite direction, and the identity element is the homotopy class of the trivial loop.

Related properties of topological spaces

• A simply connected space is a topological space whose fundamental group is trivial
• For a H-space and hence in particular for any space that arises as a loop space, and for any topological monoid, the fundamental group is Abelian

Aspects of the fundamental group

• Fundamental group functor
• Actions of the fundamental group