Thurston norm

In mathematics, the Thurston norm is a function on the second homology group of an oriented 3-manifold introduced by William Thurston, which measures in a natural way the topological complexity of homology classes represented by surfaces.

Definition[edit]

Let $M$ be a differentiable manifold and $c\in H_{2}(M)$ . Then $c$ can be represented by a smooth embedding $S\to M$ , where $S$ is a (not necessarily connected) surface that is compact and without boundary. The Thurston norm of $c$ is then defined to be^[1]

\|c\|_{T}=\min _{S}\sum _{i=1}^{n}\chi _{-}(S_{i})

,

where the minimum is taken over all embedded surfaces $S=\bigcup _{i}S_{i}$ (the $S_{i}$ being the connected components) representing $c$ as above, and $\chi _{-}(F)=\max(0,-\chi (F))$ is the absolute value of the Euler characteristic for surfaces which are not spheres (and 0 for spheres).

This function satisfies the following properties:

$\|kc\|_{T}=|k|\cdot \|c\|_{T}$ for $c\in H_{2}(M),k\in \mathbb {Z}$ ;
$\|c_{1}+c_{2}\|_{T}\leq \|c_{1}\|_{T}+\|c_{2}\|_{T}$ for $c_{1},c_{2}\in H_{2}(M)$ .

These properties imply that $\|\cdot \|$ extends to a function on $H_{2}(M,\mathbb {Q} )$ which can then be extended by continuity to a seminorm $\|\cdot \|_{T}$ on $H_{2}(M,\mathbb {R} )$ .^[2] By Poincaré duality, one can define the Thurston norm on $H^{1}(M,\mathbb {R} )$ .

When $M$ is compact with boundary, the Thurston norm is defined in a similar manner on the relative homology group $H_{2}(M,\partial M,\mathbb {R} )$ and its Poincaré dual $H^{1}(M,\mathbb {R} )$ .

It follows from further work of David Gabai^[3] that one can also define the Thurston norm using only immersed surfaces. This implies that the Thurston norm is also equal to half the Gromov norm on homology.

Topological applications[edit]

The Thurston norm was introduced in view of its applications to fiberings and foliations of 3-manifolds.

The unit ball $B$ of the Thurston norm of a 3-manifold $M$ is a polytope with integer vertices. It can be used to describe the structure of the set of fiberings of $M$ over the circle: if $M$ can be written as the mapping torus of a diffeomorphism $f$ of a surface $S$ then the embedding $S\hookrightarrow M$ represents a class in a top-dimensional (or open) face of $B$ : moreover all other integer points on the same face are also fibers in such a fibration.^[4]

Embedded surfaces which minimise the Thurston norm in their homology class are exactly the closed leaves of foliations of $M$ .^[3]

Notes[edit]

^ Thurston 1986.
^ Thurston 1986, Theorem 1.
^ ^a ^b Gabai 1983.
^ Thurston 1986, Theorem 5.

References[edit]

Gabai, David (1983). "Foliations and the topology of 3-manifolds". Journal of Differential Geometry. 18 (3): 445–503. doi:10.4310/jdg/1214437784. MR 0723813.
Thurston, William (1986). "A norm for the homology of 3-manifolds". Memoirs of the American Mathematical Society. 59 (33): i–vi and 99–130. MR 0823443.

[FOOTNOTEThurston1986-1] Thurston 1986.

[FOOTNOTEThurston1986Theorem_1-2] Thurston 1986, Theorem 1.

[FOOTNOTEGabai1983-3] Gabai 1983.

[FOOTNOTEThurston1986Theorem_5-4] Thurston 1986, Theorem 5.

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