SUSPENSION (TOPOLOGY)

In topology, the 'suspension' ''SX'' of a topological space ''X'' is the quotient space:
:$SX\; =\; (X\; imes\; I)/\{(x\_1,0)sim(x\_2,0)mbox\{\; and\; \}(x\_1,1)sim(x\_2,1)\; mbox\{\; for\; all\; \}\; x\_1,x\_2\; in\; X\}$

of the product of ''X'' with the unit interval ''I'' = [0, 1]. Intuitively, we make ''X'' into a cylinder and collapse both ends to two points. One views ''X'' as "suspended" between the end points. One can also view the suspension as two cones on ''X'' glued together at their base (or as a quotient of a single cone).
Given a continuous map $f:X$
ightarrow Y, there is a map $Sf:SX$
ightarrow SY defined by $Sf([x,t]):=[f(x),t].$ This makes $S$ into a functor from the category of topological spaces into itself. In rough terms increases dimension of a space by one: it takes an ''n''-sphere to an (''n'' + 1)-sphere for ''n'' ≥ 0.
Note that $SX$ is homeomorphic to the join $Xstar\; S^0,$ where $S^0$ is a discrete space with two points.
The space $SX$ is sometimes called the 'unreduced', 'unbased', or 'free suspension' of $X$, to distinguish it from the reduced suspension described below.
The suspension can be used to construct a homomorphism of homotopy groups, to which the Freudenthal suspension theorem applies. In homotopy theory, the phenomena which are preserved under suspension, in a suitable sense, make up stable homotopy theory.

Contents

Reduced suspension

See also

References

Reduced suspension

If ''X'' is a pointed space (with basepoint ''x''₀), there is a variation of the suspension which is sometimes more useful. The 'reduced suspension' or 'based suspension' Σ''X'' of ''X'' is the quotient space:
:$Sigma\; X\; =\; (X\; imes\; I)/(X\; imes\{0\}cup\; X\; imes\{1\}cup\; \{x\_0\}\; imes\; I)$.
This is the equivalent to taking ''SX'' and collapsing the line (''x''₀ × ''I'') joining the two ends to a single point. The basepoint of Σ''X'' is the equivalence class of (''x''₀, 0).
One can show that the reduced suspension of ''X'' is homeomorphic to the smash product of ''X'' with the unit circle ''S''¹.
:$Sigma\; X\; cong\; S^1\; wedge\; X$
For well-behaved spaces, such as CW complexes, the reduced suspension of ''X'' is homotopy equivalent to the ordinary suspension.
Σ gives rise to a functor from the category of pointed spaces to itself. An important property of this functor is that it is a left adjoint to the functor $Omega$ taking a (based) space $X$ to its loop space $Omega\; X$. In other words,
:$operatorname\{Maps\}\_$
★ left(Sigma X,Y
ight)cong operatorname{Maps}_
★ left(X,Omega Y
ight)
naturally, where $operatorname\{Maps\}\_$
★ left(X,Y
ight) stands for continuous maps which preserve basepoints.

See also

★ Cone (topology)

★ Join (topology)

References

★ Allen Hatcher, ''Algebraic topology.'' Cambridge University Press, Cambridge, 2002. xii+544 pp. ISBN 0-521-79160-X and ISBN 0-521-79540-0

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