Surgery obstruction

In mathematics, specifically in surgery theory, the surgery obstructions define a map ${\displaystyle \theta \colon {\mathcal {N}}(X)\to L_{n}(\pi _{1}(X))}$ from the normal invariants to the L-groups which is in the first instance a set-theoretic map (that means not necessarily a homomorphism) with the following property when ${\displaystyle n\geq 5}$:

A degree-one normal map ${\displaystyle (f,b)\colon M\to X}$ is normally cobordant to a homotopy equivalence if and only if the image ${\displaystyle \theta (f,b)=0}$ in ${\displaystyle L_{n}(\mathbb {Z} [\pi _{1}(X)])}$.

Sketch of the definition

The surgery obstruction of a degree-one normal map has a relatively complicated definition.

Consider a degree-one normal map ${\displaystyle (f,b)\colon M\to X}$ . The idea in deciding the question whether it is normally cobordant to a homotopy equivalence is to try to systematically improve ${\displaystyle (f,b)}$  so that the map ${\displaystyle f}$  becomes ${\displaystyle m}$ -connected (that means the homotopy groups ${\displaystyle \pi _{*}(f)=0}$  for ${\displaystyle *\leq m}$ ) for high ${\displaystyle m}$ . It is a consequence of Poincaré duality that if we can achieve this for ${\displaystyle m>\lfloor n/2\rfloor }$  then the map ${\displaystyle f}$  already is a homotopy equivalence. The word systematically above refers to the fact that one tries to do surgeries on ${\displaystyle M}$  to kill elements of ${\displaystyle \pi _{i}(f)}$ . In fact it is more convenient to use homology of the universal covers to observe how connected the map ${\displaystyle f}$  is. More precisely, one works with the surgery kernels ${\displaystyle K_{i}({\tilde {M}}):=\mathrm {ker} \{f_{*}\colon H_{i}({\tilde {M}})\rightarrow H_{i}({\tilde {X}})\}}$  which one views as ${\displaystyle \mathbb {Z} [\pi _{1}(X)]}$ -modules. If all these vanish, then the map ${\displaystyle f}$  is a homotopy equivalence. As a consequence of Poincaré duality on ${\displaystyle M}$  and ${\displaystyle X}$  there is a ${\displaystyle \mathbb {Z} [\pi _{1}(X)]}$ -modules Poincaré duality ${\displaystyle K^{n-i}({\tilde {M}})\cong K_{i}({\tilde {M}})}$ , so one only has to watch half of them, that means those for which ${\displaystyle i\leq \lfloor n/2\rfloor }$ .

Any degree-one normal map can be made ${\displaystyle \lfloor n/2\rfloor }$ -connected by the process called surgery below the middle dimension. This is the process of killing elements of ${\displaystyle K_{i}({\tilde {M}})}$  for ${\displaystyle i<\lfloor n/2\rfloor }$  described here when we have ${\displaystyle p+q=n}$  such that ${\displaystyle i=p<\lfloor n/2\rfloor }$ . After this is done there are two cases.

1. If ${\displaystyle n=2k}$  then the only nontrivial homology group is the kernel ${\displaystyle K_{k}({\tilde {M}}):=\mathrm {ker} \{f_{*}\colon H_{k}({\tilde {M}})\rightarrow H_{k}({\tilde {X}})\}}$ . It turns out that the cup-product pairings on ${\displaystyle M}$  and ${\displaystyle X}$  induce a cup-product pairing on ${\displaystyle K_{k}({\tilde {M}})}$ . This defines a symmetric bilinear form in case ${\displaystyle k=2l}$  and a skew-symmetric bilinear form in case ${\displaystyle k=2l+1}$ . It turns out that these forms can be refined to ${\displaystyle \varepsilon }$ -quadratic forms, where ${\displaystyle \varepsilon =(-1)^{k}}$ . These ${\displaystyle \varepsilon }$ -quadratic forms define elements in the L-groups ${\displaystyle L_{n}(\pi _{1}(X))}$ .

2. If ${\displaystyle n=2k+1}$  the definition is more complicated. Instead of a quadratic form one obtains from the geometry a quadratic formation, which is a kind of automorphism of quadratic forms. Such a thing defines an element in the odd-dimensional L-group ${\displaystyle L_{n}(\pi _{1}(X))}$ .

If the element ${\displaystyle \theta (f,b)}$  is zero in the L-group surgery can be done on ${\displaystyle M}$  to modify ${\displaystyle f}$  to a homotopy equivalence.

Geometrically the reason why this is not always possible is that performing surgery in the middle dimension to kill an element in ${\displaystyle K_{k}({\tilde {M}})}$  possibly creates an element in ${\displaystyle K_{k-1}({\tilde {M}})}$  when ${\displaystyle n=2k}$  or in ${\displaystyle K_{k}({\tilde {M}})}$  when ${\displaystyle n=2k+1}$ . So this possibly destroys what has already been achieved. However, if ${\displaystyle \theta (f,b)}$  is zero, surgeries can be arranged in such a way that this does not happen.

Example

In the simply connected case the following happens.

If ${\displaystyle n=2k+1}$  there is no obstruction.

If ${\displaystyle n=4l}$  then the surgery obstruction can be calculated as the difference of the signatures of M and X.

If ${\displaystyle n=4l+2}$  then the surgery obstruction is the Arf-invariant of the associated kernel quadratic form over ${\displaystyle \mathbb {Z} _{2}}$ .

References

• Browder, William (1972), Surgery on simply-connected manifolds, Berlin, New York: Springer-Verlag, MR 0358813
• Lück, Wolfgang (2002), A basic introduction to surgery theory (PDF), ICTP Lecture Notes Series 9, Band 1, of the school "High-dimensional manifold theory" in Trieste, May/June 2001, Abdus Salam International Centre for Theoretical Physics, Trieste 1-224
• Ranicki, Andrew (2002), Algebraic and Geometric Surgery, Oxford Mathematical Monographs, Clarendon Press, ISBN 978-0-19-850924-0, MR 2061749
• Wall, C. T. C. (1999), Surgery on compact manifolds, Mathematical Surveys and Monographs, vol. 69 (2nd ed.), Providence, R.I.: American Mathematical Society, ISBN 978-0-8218-0942-6, MR 1687388