N-connected

From Wikipedia, the free encyclopedia

The correct title of this article is n-connected. The initial letter is shown capitalized due to technical restrictions.

In the mathematical branch of topology, a topological space X is said to be n-connected if and only if it is path-connected and its first n homotopy groups vanish identically, that is

\pi_i(X) \equiv 0~, \quad 1\leq i\leq n ,

where the left-hand side denotes the i-th homotopy group. The requirement of being path-connected can also be expressed as 0-connectedness, when defining the "0th homotopy group"

π0(X): = [S0,X].

A topological space X is path-connected if and only if its 0th homotopy group vanishes identically, as path-connectedness implies that any two points x1 and x2 in X can be connected with a continuous path which starts in x1 and ends in x2, which is equivalent to the assertion that every mapping from S0 (a discrete set of two points) to X can be deformed continuously to a constant map. With this definition, we can define X to be n-connected if and only if

\pi_i(X) \equiv 0, \quad 0\leq i\leq n.

[edit] Examples and applications

  • As described above, a space X is 0-connected if and only if it is path-connected.
  • A space is 1-connected if and only if it is simply connected. Thus, the term n-connected is a natural generalization of being path-connected or simply connected.

It is obvious from the definition that an n-connected space X is also i-connected for all i<n.

The concept of n-connectedness is used in the Hurewicz theorem which describes the relation between singular homology and the higher homotopy groups.

[edit] See also