In topology, a branch of mathematics, the loop space ΩX of a pointed topological space X is the space of (based) loops in X, i.e. continuous pointed maps from the pointed circle S1 to X, equipped with the compact-open topology. Two loops can be multiplied by concatenation. With this operation, the loop space is an A∞-space. That is, the multiplication is homotopy-coherently associative.
The set of path components of ΩX, i.e. the set of based-homotopy equivalence classes of based loops in X, is a group, the fundamental group π1(X).
The iterated loop spaces of X are formed by applying Ω a number of times.
There is an analogous construction for topological spaces without basepoint. The free loop space of a topological space X is the space of maps from the circle S1 to X with the compact-open topology. The free loop space of X is often denoted by
l{L}X
The loop space is dual to the suspension of the same space; this duality is sometimes called Eckmann–Hilton duality. The basic observation is that
[\SigmaZ,X] ≈ eq[Z,\OmegaX]
[A,B]
A → B
\SigmaA
≈ eq
In general,
[A,B]
A
B
[\SigmaZ,X]
[Z,\OmegaX]
Z
X
Z=Sk-1
k-1
\pik(X) ≈ eq\pik-1(\OmegaX)
This follows since the homotopy group is defined as
| k,X] | |
| \pi | |
| k(X)=[S |
Sk=\SigmaSk-1