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In [[surgery theory]], a branch of [[mathematics]], the '''stable normal bundle''' of a [[differentiable manifold]] is an invariant which encodes the stable normal (dually, tangential) data. There are analogs for generalizations of manifold, notably [[PL-manifold]]s and [[topological manifold]]s. There is also an analogue in [[homotopy theory]] for [[Poincaré space]]s, the '''Spivak spherical fibration''', named after [[Michael Spivak]].<ref>{{citation<br />
|last=Spivak<br />
|first=Michael<br />
|author-link=Michael Spivak<br />
|title=Spaces satisfying Poincaré duality<br />
|journal=[[Topology (journal)|Topology]]<br />
|issue=6<br />
|year=1967<br />
|volume=6<br />
|pages=77–101<br />
|mr=0214071<br />
|doi=10.1016/0040-9383(67)90016-X<br />
|doi-access=<br />
}}</ref><br />
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==Construction via embeddings==<br />
Given an embedding of a manifold in [[Euclidean space]] (provided by the theorem of [[Hassler Whitney]]), it has a [[normal bundle]]. The embedding is not unique, but for high dimension of the Euclidean space it is unique up to [[Homotopy#Isotopy|isotopy]], thus the (class of the) bundle is unique, and called the ''stable normal bundle''.<br />
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This construction works for any [[Poincaré space]] ''X'': a finite [[CW-complex]] admits a stably unique (up to homotopy) embedding in [[Euclidean space]], via [[general position]], and this embedding yields a spherical fibration over ''X''. For more restricted spaces (notably PL-manifolds and topological manifolds), one gets stronger data.<br />
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===Details===<br />
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Two embeddings <math>i,i'\colon X \hookrightarrow \R^m</math> are ''isotopic'' if they are [[homotopic]]<br />
through embeddings. Given a manifold or other suitable space ''X,'' with two embeddings into Euclidean space <math>i\colon X \hookrightarrow \R^m,</math> <math>j\colon X \hookrightarrow \R^n,</math> these will not in general be isotopic, or even maps into the same space (<math>m</math> need not equal <math>n</math>). However, one can embed these into a larger space <math>\mathbf{R}^N</math> by letting the last <math>N-m</math> coordinates be 0:<br />
:<math>i\colon X \hookrightarrow \R^m \cong \R^m \times \left\{(0,\dots,0)\right\} \subset \R^m \times \R^{N-m} \cong \R^N</math>.<br />
This process of adjoining trivial copies of Euclidean space is called ''stabilization.''<br />
One can thus arrange for any two embeddings into Euclidean space to map into the same Euclidean space (taking <math>N = \max(m,n)</math>), and, further, if <math>N</math> is sufficiently large, these embeddings are isotopic, which is a theorem.<br />
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Thus there is a unique stable isotopy class of embedding: it is not a particular embedding (as there are many embeddings), nor an isotopy class (as the target space is not fixed: it is just "a sufficiently large Euclidean space"), but rather a stable isotopy class of maps. The normal bundle associated with this (stable class of) embeddings is then the stable normal bundle.<br />
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One can replace this stable isotopy class with an actual isotopy class by fixing the target space, either by using [[Hilbert space]] as the target space, or (for a fixed dimension of manifold <math>n</math>) using a fixed <math>N</math> sufficiently large, as ''N'' depends only on ''n'', not the manifold in question.<br />
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More abstractly, rather than stabilizing the embedding, one can take any embedding, and then take a vector bundle direct sum with a sufficient number of trivial line bundles; this corresponds exactly to the normal bundle of the stabilized embedding.<br />
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==Construction via [[classifying space]]s==<br />
An ''n''-manifold ''M'' has a tangent bundle, which has a classifying map (up to homotopy)<br />
:<math>\tau_M\colon M \to B\textrm{O}(n).</math><br />
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Composing with the inclusion <math>B\textrm{O}(n) \to B\textrm{O}</math> yields (the homotopy class of a classifying map of) the stable tangent bundle. The normal bundle of an embedding <math>M \subset \R^{n+k}</math> (<math>k</math> large) is an inverse <math>\nu_M\colon M \to B\textrm{O}(k)</math> for <math>\tau_M</math>, such that the [[Whitney sum]] <math>\tau_M\oplus \nu_M<br />
\colon M \to B\textrm{O}(n+k)</math> is trivial. The homotopy class of the composite<br />
<math>\nu_M\colon M \to B\textrm{O}(k) \to B\textrm{O}</math> is independent of the choice of embedding, classifying the stable normal bundle <math>\nu_M</math>.<br />
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==Motivation==<br />
There is no intrinsic notion of a normal vector to a manifold, unlike tangent or cotangent vectors – for instance, the normal space depends on which dimension one is embedding into – so the stable normal bundle instead provides a notion of a stable normal space: a normal space (and normal vectors) up to trivial summands.<br />
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Why stable normal, instead of stable tangent? Stable normal data is used instead of unstable tangential data because generalizations of manifolds have natural stable normal-type structures, coming from [[tubular neighborhood]]s and generalizations, but not unstable tangential ones, as the local structure is not smooth.<br />
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Spherical fibrations over a space ''X'' are classified by the homotopy classes of maps <math>X \to BG</math> to a<br />
[[classifying space]] <math>BG</math>, with [[homotopy groups]] the [[stable homotopy groups of spheres]]<br />
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:<math>\pi_*(BG)=\pi_{*-1}^S</math>.<br />
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The forgetful map <math>B\textrm{O} \to BG</math> extends to a [[fibration]] sequence<br />
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:<math>B\textrm{O} \to BG \to B(G/\textrm{O})</math>.<br />
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A [[Poincaré space]] ''X'' does not have a tangent bundle, but it does have a well-defined stable spherical [[fibration]], which for a differentiable manifold is the spherical fibration associated to the stable normal bundle; thus a primary obstruction to ''X'' having the homotopy type of a differentiable manifold is that the spherical fibration lifts to a vector bundle, i.e., the Spivak spherical fibration <math>X \to BG</math> must lift to <math>X \to B\textrm{O}</math>, which is equivalent to the map <math>X \to B(G/\textrm{O})</math> being [[null homotopic]]<br />
Thus the bundle obstruction to the existence of a (smooth) manifold structure is the class <math>X \to B(G/\textrm{O})</math>.<br />
The secondary obstruction is the Wall [[surgery obstruction]].<br />
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==Applications==<br />
The stable normal bundle is fundamental in [[surgery theory]] as a primary obstruction:<br />
*For a [[Poincaré space]] ''X'' to have the homotopy type of a smooth manifold, the map <math>X \to B(G/\textrm{O})</math> must be [[null homotopic]]<br />
*For a homotopy equivalence <math>f\colon M \to N</math> between two manifolds to be homotopic to a diffeomorphism, it must pull back the stable normal bundle on ''N'' to the stable normal bundle on ''M''.<br />
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More generally, its generalizations serve as replacements for the (unstable) tangent bundle.<br />
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==References==<br />
{{reflist}}<br />
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{{Manifolds}}<br />
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[[Category:Differential geometry]]<br />
[[Category:Surgery theory]]</div>imported>OAbot