Schuette–Nesbitt formula

In differential topology, a branch of mathematics, a Mazur manifold is a contractible, compact, smooth 4-dimensional manifold (with boundary) which is not diffeomorphic to the standard 4-ball. The boundary of a Mazur manifold is necessarily a homology 3-sphere.

Frequently the term Mazur manifold is restricted to a special class of the above definition: 4-manifolds that have a handle decomposition containing exactly three handles: a single 0-handle, a single 1-handle and single 2-handle. This is equivalent to saying the manifold must be of the form ${\displaystyle S^1\times D^3}$ union a 2-handle. An observation of Mazur's shows that the double of such manifolds is diffeomorphic to ${\displaystyle S^4}$ with the standard smooth structure.

Some properties

In general the double of a Mazur manifold is a homotopy 4-sphere, thus such manifolds are a source of possible counter-examples to the smooth Poincaré conjecture in dimension 4.

History

Barry Mazur ^[1] and Valentin Poenaru^[2] discovered these manifolds simultaneously. Akbulut and Kirby showed that the Brieskorn homology spheres ${\displaystyle \mathrm{\Sigma }(2,5,7)}$, ${\displaystyle \mathrm{\Sigma }(3,4,5)}$ and ${\displaystyle \mathrm{\Sigma }(2,3,13)}$ are boundaries of Mazur manifolds.^[3] This results were later generalized to other contractible manifolds by Casson, Harer and Stern.^[4][5][6] One of the Mazur manifolds is also an example of an Akbulut cork ^[7] which can be used to construct exotic 4-manifolds.^[8]

Mazur manifolds have been used by Fintushel and Stern ^[9] to construct exotic actions of a group of order 2 on the 4-sphere.

Mazur's discovery was surprising for several reasons:

• Every smooth homology sphere in dimension ${\displaystyle n\ge 5}$ is homeomorphic to the boundary of a compact contractible smooth manifold. This follows from the work of Kervaire ^[10] and the h-cobordism theorem. Every smooth homology 4-sphere is diffeomorphic to the boundary of a compact contractible smooth 5-manifold (also by the work of Kervaire). Moreover, not every homology 3-sphere is diffeomorphic to the boundary of a contractible compact smooth 4-manifold. For example, the Poincaré homology sphere does not bound such a 4-manifold because the Rochlin invariant provides an obstruction.

• The H-cobordism Theorem implies that, at least in dimensions ${\displaystyle n\ge 6}$ there is a unique contractible ${\displaystyle n}$-manifold with simply-connected boundary, where uniqueness is up to diffeomorphism. This manifold is the unit ball ${\displaystyle D^n}$. It's an open problem as to whether or not ${\displaystyle D^5}$ admits an exotic smooth structure, but by the h-cobordism theorem, such an exotic smooth structure, if it exists, must restrict to an exotic smooth structure on ${\displaystyle S^4}$. Whether or not ${\displaystyle S^4}$ admits an exotic smooth structure is equivalent to another open problem, the smooth Poincaré conjecture in dimension four. Whether or not ${\displaystyle D^4}$ admits an exotic smooth structure is another open problem, closely linked to the Schoenflies problem in dimension four.

Mazur's Observation

Let ${\displaystyle M}$ be the Mazur manifold, constructed as ${\displaystyle S^1\times D^3}$ union a 2-handle. Here is a sketch of Mazur's argument that the double of such a Mazur manifold is ${\displaystyle S^4}$. ${\displaystyle M\times [0,1]}$ is a contractible 5-manifold constructed as ${\displaystyle S^1\times D^4}$ union a 2-handle. The 2-handle can be unknotted since the attaching map is a framed knot in the 4-manifold ${\displaystyle S^1\times S^3}$. So ${\displaystyle S^1\times D^4}$ union the 2-handle is diffeomorphic to ${\displaystyle D^5}$. The boundary of ${\displaystyle D^5}$ is ${\displaystyle S^4}$. But the boundary of ${\displaystyle M\times [0,1]}$ is the double of ${\displaystyle M}$.

References