Difference between revisions of "Kervaire-Milnor invariant"
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− | An invariant of framed [[Surgery|surgery]] of a closed 6- or | + | An invariant of framed [[Surgery|surgery]] of a closed 6- or 14-dimensional framed manifold. |
− | dimensional framed manifold. | ||
Let $ M ^ {6} $ | Let $ M ^ {6} $ | ||
− | be a stably-parallelizable | + | be a stably-parallelizable 2-connected manifold on which is given a stable $ N $-dimensional framing $ ( M ^ {6} , U ) $, |
− | connected manifold on which is given a stable $ N $- | + | i.e. a trivialization of the stable $ N $-dimensional [[Normal bundle|normal bundle]]. Let $ S _ {i} ^ {3} $ |
− | dimensional framing $ ( M ^ {6} , U ) $, | + | be spheres realizing a basis of the 3-dimensional homology space of $ M ^ {6} $. |
− | i.e. a trivialization of the stable $ N $- | + | By summing the given $ N $-trivialization $ U $ |
− | dimensional [[Normal bundle|normal bundle]]. Let $ S _ {i} ^ {3} $ | ||
− | be spheres realizing a basis of the | ||
− | dimensional homology space of $ M ^ {6} $. | ||
− | By summing the given $ N $- | ||
− | trivialization $ U $ | ||
with certain trivializations $ \alpha _ {i} \in \pi _ {3} ( \mathop{\rm SO} _ {3} ) $ | with certain trivializations $ \alpha _ {i} \in \pi _ {3} ( \mathop{\rm SO} _ {3} ) $ | ||
of tubular neighbourhoods of the spheres $ S _ {i} ^ {3} $ | of tubular neighbourhoods of the spheres $ S _ {i} ^ {3} $ | ||
in $ M ^ {6} $, | in $ M ^ {6} $, | ||
− | one obtains an $ ( N + 3 ) $- | + | one obtains an $ ( N + 3 ) $-dimensional trivialization of the stable normal bundles to the spheres $ S _ {i} ^ {3} $ |
− | dimensional trivialization of the stable normal bundles to the spheres $ S _ {i} ^ {3} $ | + | and the corresponding elements $ \alpha _ {i} ^ {1} \in \pi _ {3} ( \mathop{\rm SO} _ {N+ 3} ) $. |
− | and the corresponding elements $ \alpha _ {i} ^ {1} \in \pi _ {3} ( \mathop{\rm SO} _ {N+} | + | The cokernel of the stable homomorphism $ s : \pi _ {n} ( \mathop{\rm SO} _ {N+ 3} ) \rightarrow \pi _ {n} ( \mathop{\rm SO} _ {N+} n ) $ |
− | The cokernel of the stable homomorphism $ s : \pi _ {n} ( \mathop{\rm SO} _ {N+} | ||
is isomorphic to $ \mathbf Z _ {2} $ | is isomorphic to $ \mathbf Z _ {2} $ | ||
for $ n = 3 $, | for $ n = 3 $, | ||
so that each sphere $ S _ {i} ^ {3} $ | so that each sphere $ S _ {i} ^ {3} $ | ||
− | is put into correspondence with an element of the group $ \pi _ {3} ( \mathop{\rm SO} _ {N+} | + | is put into correspondence with an element of the group $ \pi _ {3} ( \mathop{\rm SO} _ {N+ 3} ) / \mathop{\rm Im} s $ (according to the value of the elements $ \alpha _ {i} ^ {1} $ |
− | according to the value of the elements $ \alpha _ {i} ^ {1} $ | ||
which they take in the group $ \mathbf Z _ {2} $ | which they take in the group $ \mathbf Z _ {2} $ | ||
after factorization by $ \alpha _ {i} ^ {1} $). | after factorization by $ \alpha _ {i} ^ {1} $). | ||
Line 45: | Line 37: | ||
$ \mathop{\rm mod} 2 $, | $ \mathop{\rm mod} 2 $, | ||
where $ \phi ( x , y ) $ | where $ \phi ( x , y ) $ | ||
− | is the intersection form of the | + | is the intersection form of the 3-dimensional homology space on the manifold $ M ^ {6} $, |
− | dimensional homology space on the manifold $ M ^ {6} $, | ||
and is called the Kervaire–Milnor invariant of this manifold with framing $ U $. | and is called the Kervaire–Milnor invariant of this manifold with framing $ U $. | ||
The pair $ ( M ^ {6} , U ) $ | The pair $ ( M ^ {6} , U ) $ | ||
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Similar constructions have been carried out for $ M ^ {14} $. | Similar constructions have been carried out for $ M ^ {14} $. | ||
− | The Kervaire–Milnor invariant in dimension six is the only invariant of the stable | + | The Kervaire–Milnor invariant in dimension six is the only invariant of the stable 6-dimensional framed cobordism and defines an isomorphism $ \pi _ {n+ 6} ( S ^ {n} ) \approx \mathbf Z _ {2} $, |
− | dimensional framed cobordism and defines an isomorphism $ \pi _ {n+} | ||
$ n \geq 7 $. | $ n \geq 7 $. | ||
− | However, in dimension fourteen it is not a unique invariant of the stable | + | However, in dimension fourteen it is not a unique invariant of the stable 14-dimensional framed cobordism, i.e. the stable group $ \pi _ {n+14} ( S ^ {n} ) $, |
− | dimensional framed cobordism, i.e. the stable group $ \pi _ {n+} | ||
$ n \geq 16 $, | $ n \geq 16 $, | ||
is defined by framings on the sphere $ S ^ {14} $ | is defined by framings on the sphere $ S ^ {14} $ |
Revision as of 17:52, 20 January 2022
An invariant of framed surgery of a closed 6- or 14-dimensional framed manifold.
Let $ M ^ {6} $ be a stably-parallelizable 2-connected manifold on which is given a stable $ N $-dimensional framing $ ( M ^ {6} , U ) $, i.e. a trivialization of the stable $ N $-dimensional normal bundle. Let $ S _ {i} ^ {3} $ be spheres realizing a basis of the 3-dimensional homology space of $ M ^ {6} $. By summing the given $ N $-trivialization $ U $ with certain trivializations $ \alpha _ {i} \in \pi _ {3} ( \mathop{\rm SO} _ {3} ) $ of tubular neighbourhoods of the spheres $ S _ {i} ^ {3} $ in $ M ^ {6} $, one obtains an $ ( N + 3 ) $-dimensional trivialization of the stable normal bundles to the spheres $ S _ {i} ^ {3} $ and the corresponding elements $ \alpha _ {i} ^ {1} \in \pi _ {3} ( \mathop{\rm SO} _ {N+ 3} ) $. The cokernel of the stable homomorphism $ s : \pi _ {n} ( \mathop{\rm SO} _ {N+ 3} ) \rightarrow \pi _ {n} ( \mathop{\rm SO} _ {N+} n ) $ is isomorphic to $ \mathbf Z _ {2} $ for $ n = 3 $, so that each sphere $ S _ {i} ^ {3} $ is put into correspondence with an element of the group $ \pi _ {3} ( \mathop{\rm SO} _ {N+ 3} ) / \mathop{\rm Im} s $ (according to the value of the elements $ \alpha _ {i} ^ {1} $ which they take in the group $ \mathbf Z _ {2} $ after factorization by $ \alpha _ {i} ^ {1} $). This value does not depend on the choice of the elements $ \alpha _ {i} $, but depends only on the homology classes realized by the spheres $ S ^ {3} $ and the framing $ U $. The Arf-invariant of the function $ \phi _ {0} : H _ {3} ( M ^ {6} , \mathbf Z ) \rightarrow \mathbf Z _ {2} $ so obtained satisfies the formula $ \phi _ {0} ( x + y ) = \phi _ {0} ( x) + \phi _ {0} ( y) + \phi ( x, y ) $ $ \mathop{\rm mod} 2 $, where $ \phi ( x , y ) $ is the intersection form of the 3-dimensional homology space on the manifold $ M ^ {6} $, and is called the Kervaire–Milnor invariant of this manifold with framing $ U $. The pair $ ( M ^ {6} , U ) $ has a framed surgery to the pair $ ( S ^ {6} , V ) $ if and only if the Kervaire–Milnor invariant of $ ( M ^ {6} , U ) $ is zero.
Similar constructions have been carried out for $ M ^ {14} $. The Kervaire–Milnor invariant in dimension six is the only invariant of the stable 6-dimensional framed cobordism and defines an isomorphism $ \pi _ {n+ 6} ( S ^ {n} ) \approx \mathbf Z _ {2} $, $ n \geq 7 $. However, in dimension fourteen it is not a unique invariant of the stable 14-dimensional framed cobordism, i.e. the stable group $ \pi _ {n+14} ( S ^ {n} ) $, $ n \geq 16 $, is defined by framings on the sphere $ S ^ {14} $ and on $ S ^ {7} \times S ^ {7} $.
For references see Kervaire invariant.
Kervaire-Milnor invariant. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Kervaire-Milnor_invariant&oldid=47494