nLab diffeomorphism group

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Contents

Context

Differential geometry

Manifolds and cobordisms

Definition
Properties

Relation to homotopy equivalences
Homotopy type and mapping class group

For 1-manifolds
For 2-manifolds (surfaces)
For 3-manifolds

References

Smooth structure
For 2-manifolds (surfaces)
For 3-manifolds
For 4-manifolds
General

Definition

The diffeomorphism group $Diff(X)$ of a smooth manifold $X$ is the group of its diffeomorphisms: the automorphism group of $X$ as an object of the category SmoothMfd.

Beware that when $X$ is assumed orientable then sometimes, but not always, $Diff(X)$ is implicitly taken to be the group of orientation-preserving diffeomorphisms.

Properties

Relation to homotopy equivalences

For the following kinds of manifolds $\Sigma$ it is true that every homotopy equivalence

\alpha \colon \Pi(\Sigma) \stackrel{\simeq}{\longrightarrow} \Pi(\Sigma)

(hence every equivalence of their fundamental infinity-groupoids) is homotopic to a diffeomorphism

a \colon \Sigma \stackrel{\simeq}{\longrightarrow} \Sigma

i.e. that given $\alpha$ there is $a$ with

\alpha \simeq \Pi(a) \,.

for $\Sigma$ any surface (Zieschang-Vogt-Coldeway)
for $\Sigma$ a Haken 3-manifold (Waldhausen)
for $\Sigma$ any hyperbolic manifold of finite volume and of dimension $\geq 3$ (by Mostow rigidity theorem) (check)

Homotopy type and mapping class group

The homotopy type $\Pi(Diff(\Sigma))$ of the diffeomorphism group $Diff(\Sigma)$ is of interest (e.g. Hatcher 12).

For instance this is the automorphism ∞-group of a manifold, regarded as a k-morphism in an (∞,n)-category of cobordisms.

Specifically, the group of connected components is the mapping class group

\pi_0(\Pi(Diff(\Sigma))) = MCG(\Sigma) \,.

For 1-manifolds

\Pi(Diff(S^1))\simeq \Pi(O(2))

\Pi(Diff(D^1))\simeq \Pi(O(1))

For 2-manifolds (surfaces)

Proposition

For $\Sigma$ a closed orientable surface, then the bare homotopy type of its diffeomorphism group is

if $\Sigma$ is the sphere then

$\begin{aligned} \Pi(Diff(S^2)) & \simeq \Pi(O(3)) \\ & \simeq MCG(S^2)\times \Pi(SO(3)) \\ & \simeq \mathbb{Z}_2 \times \Pi(SO(3)) \end{aligned}$
if $\Sigma$ is the torus then

$\begin{aligned} \Pi(Diff(S^1 \times S^1)) & \simeq MCG(S^1 \times S^1)\times \Pi(S^1 \times S^1 ) \\ & \simeq GL_2(\mathbb{Z}) \times B(\mathbb{Z} \times\mathbb{Z}) \end{aligned}$
in all other cases all higher homotopy groups vanish:

$\Pi(Diff(\Sigma)) \simeq MCG(\Sigma)$

The first statement is due to (Smale 58), see also at sphere eversion. The second and third are due to (Earle-Eells 67, Gramain 73).

For 3-manifolds

Proposition

\Pi(Diff(S^1 \times S^2)) \simeq \Pi(O(2) \times O(3)) \times \Omega \Pi(SO(3)) \,.

(Hatcher 81)

Theorem

(Smale conjecture)
The bare homotopy type of the diffeomorphism group of the 3-sphere is that of the orthogonal group $O(4)$

\esh\big( Diff(S^3) \big) \;\simeq\; \esh \, O(4)) \,,

the equivalence being exhibited by the canonical inclusion

O(4) \hookrightarrow Diff(S^3) \,.

Also

\esh \, Diff(D^3) \;\simeq\; \esh \, O(3) \,.

After being conjectured by Smale, this was proven in (Hatcher 1983).

Generally:

Theorem

For every smooth 3-manifold the canonical map

\Pi(Diff(X)) \to \Pi(Homeo(X))

sending diffeomorphisms to their underlying homeomorphisms of topological spaces is a weak homotopy equivalence.

That this follows from the Smale cojecture, theorem , was shown in (Cerf). For discussion see (Hatcher, 1978).

Proposition

If a 3-manifold $X$ is not a Seifert 3-manifold via an $S^1$ -action then

\Pi(Diff(X)) \simeq MCG(X) \,.

If $X$ is Seifert via an $S^1$ -action, then the component of $Diff(X)$ are typically $\Pi(S^1)$ -s.

References

Smooth structure

The observation that infinite-dimensional smooth groups such as diffeomorphism groups (and quantomorphism groups etc.) are naturally regarded as internal groups in diffeological spaces – diffeological groups – is due to

Jean-Marie Souriau, Groupes différentiels, in Differential Geometrical Methods in Mathematical Physics (Proc. Conf., Aix-en-Provence/Salamanca, 1979), Lecture Notes in Math. 836, Springer, Berlin, (1980), pp. 91–128. (MathScinet)

For 2-manifolds (surfaces)

C.J. Earle, J. Eells, The diffeomorphism group of a compact Riemann surface, Bulletin of the American Mathematical Society 73(4) 557–559, 1967
Zieschang, Vogt and Coldeway, Surfaces and planar discontinuous groups
J. S. Dowker, Note on the structure constants for the diffeomorphisms of the two-sphere [arXiv:2301.09487]

For 3-manifolds

J. Cerf, Sur les difféomorphismes de la sphère de dimension trois ( $\Gamma_4 = 0$ ), Lecture Notes in Math., vol. 53, Springer-Verlag, Berlin and New York, 1968_
Allen Hatcher, Linearization in 3-dimensional topology, Proceedings of the international congress of Mathematicians, Helsinki (1978)
Allen Hatcher, On the diffeomorphism group of $S^1\times S^2$ , Proceedings of the AMS 83 (1981), 427-43 (pdf)
Allen Hatcher, A proof of the Smale conjecture, $Diff(S^3) \simeq O(4)$ , Annals of Mathematics 117 (1983) (jstor)
Friedhelm Waldhausen, On Irreducible 3-Manifolds Which are Sufficiently Large, Annals of Mathematics

Second Series, Vol. 87, No. 1 (Jan., 1968), pp. 56-88 (JSTOR)

For 4-manifolds

For 4-manifolds the analogue of the Smale conjecture fails:

Tadayuki Watanabe, Some exotic nontrivial elements of the rational homotopy groups of $Diff(S^4)$ (arXiv:1812.02448)
Tadayuki Watanabe, Addendum to: Some exotic nontrivial elements of the rational homotopy groups of $Diff(S^4)$ (homological interpretation) (arXiv:2109.01609)

(via graph complexes)

General

Alan Hatcher, A 50-Year View of Diffeomorphism Groups, talk at the 50th Cornell Topology Festival in May 2012 (pdf, pdf)

Last revised on January 24, 2023 at 07:22:40. See the history of this page for a list of all contributions to it.