Difference between revisions of "Seifert matrix"
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− | + | A matrix associated with knots and links in order to investigate their topological properties by algebraic methods (cf. [[Knot theory|Knot theory]]). Named after H. Seifert [[#References|[1]]], who applied the construction to obtain algebraic invariants of one-dimensional knots in $ S ^ {3} $. | |
+ | Let $ L = ( S ^ {n+} 2 , l ^ {n} ) $ | ||
+ | be an $ n $- | ||
+ | dimensional $ m $- | ||
+ | component [[Link|link]], i.e. a pair consisting of an oriented sphere $ S ^ {n+} 2 $ | ||
+ | and a differentiable or piecewise-linear oriented submanifold $ l ^ {n} $ | ||
+ | of this sphere which is homeomorphic to the disconnected union of $ m $ | ||
+ | copies of the sphere $ S ^ {n} $. | ||
+ | There exists a compact $ ( n+ 1) $- | ||
+ | dimensional orientable submanifold $ V $ | ||
+ | of $ S ^ {n+} 2 $ | ||
+ | such that $ \partial V = l $; | ||
+ | it is known as the Seifert manifold of the link $ L $. | ||
+ | The orientation of the Seifert manifold $ V $ | ||
+ | is determined by the orientation of its boundary $ \partial V = l $; | ||
+ | since the orientation of $ S ^ {n+} 2 $ | ||
+ | is fixed, the normal bundle to $ V $ | ||
+ | in $ S ^ {n+} 2 $ | ||
+ | turns out to be oriented, so that one can speak of the field of positive normals to $ V $. | ||
+ | Let $ i _ {+} : V \rightarrow Y $ | ||
+ | be a small displacement along this field, where $ Y $ | ||
+ | is the complement to an open tubular neighbourhood of $ V $ | ||
+ | in $ S ^ {n+} 2 $. | ||
+ | If $ n = 2 q - 1 $ | ||
+ | is odd, one defines a pairing | ||
− | + | $$ | |
+ | \theta : H _ {q} V \otimes H _ {q} V \rightarrow \mathbf Z , | ||
+ | $$ | ||
− | + | associating with an element $ z _ {1} \otimes z _ {2} $ | |
+ | the [[Linking coefficient|linking coefficient]] of the classes $ z _ {1} \in H _ {q} V $ | ||
+ | and $ i _ {+} * z _ {2} \in H _ {q} Y $. | ||
+ | This $ \theta $ | ||
+ | is known as the Seifert pairing of the link $ L $. | ||
+ | If $ z _ {1} $ | ||
+ | and $ z _ {2} $ | ||
+ | are of finite order, then $ \theta ( z _ {1} \otimes z _ {2} ) = 0 $. | ||
+ | The following formula is valid: | ||
− | + | $$ | |
+ | \theta ( z _ {1} \otimes z _ {2} ) + ( - 1 ) ^ {q} \theta ( z _ {2} \otimes z _ {1} ) = z _ {1} \cdot z _ {2} , | ||
+ | $$ | ||
− | + | where the right-hand side is the [[Intersection index (in homology)|intersection index (in homology)]] of the classes $ z _ {1} $ | |
+ | and $ z _ {2} $ | ||
+ | on $ V $. | ||
− | + | Let $ e _ {1} \dots e _ {k} $ | |
+ | be a basis for the free part of the group $ H _ {q} V $. | ||
+ | The $ ( k \times k ) $- | ||
+ | matrix $ A = \| \theta ( e _ {i} \otimes e _ {j} ) \| $ | ||
+ | with integer entries is called the Seifert matrix of $ L $. | ||
+ | The Seifert matrix of any $ ( 2 q - 1 ) $- | ||
+ | dimensional knot has the following property: The matrix $ A = ( - 1 ) ^ {q} A ^ \prime $ | ||
+ | is unimodular (cf. [[Unimodular matrix|Unimodular matrix]]), and for $ q = 2 $ | ||
+ | the [[Signature|signature]] of the matrix $ A + A ^ \prime $ | ||
+ | is divisible by $ 16 $( | ||
+ | $ A ^ \prime $ | ||
+ | is the transpose of $ A $). | ||
+ | Any square matrix $ A $ | ||
+ | with integer entries is the Seifert matrix of some $ ( 2 q - 1 ) $- | ||
+ | dimensional knot if $ q \neq 2 $, | ||
+ | and the matrix $ A + ( - 1 ) ^ {q} A ^ \prime $ | ||
+ | is unimodular. | ||
− | where | + | The Seifert matrix itself is not an invariant of the link $ L $; |
+ | the reason is that the construction of the Seifert manifold $ V $ | ||
+ | and the choice of the basis $ e _ {1} \dots e _ {k} $ | ||
+ | are not unique. Matrices of the form | ||
+ | |||
+ | $$ | ||
+ | \left \| | ||
+ | |||
+ | \begin{array}{lcc} | ||
+ | A &{} & 0 \\ | ||
+ | \alpha & 0 & 1 \\ | ||
+ | 0 & 1 & 0 \\ | ||
+ | \end{array} | ||
+ | |||
+ | \right \| ,\ \ | ||
+ | \left \| | ||
+ | \begin{array}{lll} | ||
+ | A &\beta & 0 \\ | ||
+ | 0 & 0 & 1 \\ | ||
+ | {} & 0 & 0 \\ | ||
+ | \end{array} | ||
+ | \right \| , | ||
+ | $$ | ||
+ | |||
+ | where $ \alpha $ | ||
+ | is a row-vector and $ \beta $ | ||
+ | a column-vector, are known as elementary expansions of $ A $, | ||
+ | while $ A $ | ||
+ | itself is called an elementary reduction of its elementary expansions. Two square matrices are said to be $ S $- | ||
+ | equivalent if one can be derived from the other via elementary reductions, elementary expansions and unimodular congruences (i.e. transformations $ A \rightarrow P ^ \prime A P $, | ||
+ | where $ P $ | ||
+ | is a unimodular matrix). For higher-dimensional knots $ ( m = 1 ) $ | ||
+ | and one-dimensional links $ ( n = 1 ) $ | ||
+ | the $ S $- | ||
+ | equivalence class of the Seifert matrix is an invariant of the type of the link $ L $. | ||
+ | In case $ L $ | ||
+ | is a knot, the Seifert matrix $ A $ | ||
+ | uniquely determines a $ \mathbf Z [ t , t ^ {-} 1 ] $- | ||
+ | module $ H _ {q} \widetilde{X} $, | ||
+ | where $ \widetilde{X} $ | ||
+ | is an infinite cyclic covering of the complement of the knot. The polynomial matrix $ t A + ( - 1 ) ^ {q} A ^ \prime $ | ||
+ | is the Alexander matrix (see [[Alexander invariants|Alexander invariants]]) of the module $ H _ {q} \widetilde{X} $. | ||
+ | The Seifert matrix also determines the $ q $- | ||
+ | dimensional homology and the linking coefficients in the cyclic coverings of the sphere $ S ^ {2q+} 1 $ | ||
+ | that ramify over the link. | ||
====References==== | ====References==== | ||
<table><TR><TD valign="top">[1]</TD> <TD valign="top"> H. Seifert, "Ueber das Geschlecht von Knoten" ''Math. Ann.'' , '''110''' (1934) pp. 571–592</TD></TR><TR><TD valign="top">[2]</TD> <TD valign="top"> R.H. Crowell, R.H. Fox, "Introduction to knot theory" , Ginn (1963)</TD></TR><TR><TD valign="top">[3]</TD> <TD valign="top"> J. Levine, "Polynomial invariants of knots of codimension two" ''Ann. of Math.'' , '''84''' (1966) pp. 537–554</TD></TR><TR><TD valign="top">[4]</TD> <TD valign="top"> J. Levine, "An algebraic classification of some knots of codimension two" ''Comment. Math. Helv.'' , '''45''' (1970) pp. 185–198</TD></TR></table> | <table><TR><TD valign="top">[1]</TD> <TD valign="top"> H. Seifert, "Ueber das Geschlecht von Knoten" ''Math. Ann.'' , '''110''' (1934) pp. 571–592</TD></TR><TR><TD valign="top">[2]</TD> <TD valign="top"> R.H. Crowell, R.H. Fox, "Introduction to knot theory" , Ginn (1963)</TD></TR><TR><TD valign="top">[3]</TD> <TD valign="top"> J. Levine, "Polynomial invariants of knots of codimension two" ''Ann. of Math.'' , '''84''' (1966) pp. 537–554</TD></TR><TR><TD valign="top">[4]</TD> <TD valign="top"> J. Levine, "An algebraic classification of some knots of codimension two" ''Comment. Math. Helv.'' , '''45''' (1970) pp. 185–198</TD></TR></table> | ||
− | |||
− | |||
====Comments==== | ====Comments==== | ||
− | For a description of the Seifert manifold in the case | + | For a description of the Seifert manifold in the case $ n = 1 $, |
+ | i.e. the Seifert surface of a link, cf. [[Knot and link diagrams|Knot and link diagrams]]. |
Revision as of 14:55, 7 June 2020
A matrix associated with knots and links in order to investigate their topological properties by algebraic methods (cf. Knot theory). Named after H. Seifert [1], who applied the construction to obtain algebraic invariants of one-dimensional knots in $ S ^ {3} $.
Let $ L = ( S ^ {n+} 2 , l ^ {n} ) $
be an $ n $-
dimensional $ m $-
component link, i.e. a pair consisting of an oriented sphere $ S ^ {n+} 2 $
and a differentiable or piecewise-linear oriented submanifold $ l ^ {n} $
of this sphere which is homeomorphic to the disconnected union of $ m $
copies of the sphere $ S ^ {n} $.
There exists a compact $ ( n+ 1) $-
dimensional orientable submanifold $ V $
of $ S ^ {n+} 2 $
such that $ \partial V = l $;
it is known as the Seifert manifold of the link $ L $.
The orientation of the Seifert manifold $ V $
is determined by the orientation of its boundary $ \partial V = l $;
since the orientation of $ S ^ {n+} 2 $
is fixed, the normal bundle to $ V $
in $ S ^ {n+} 2 $
turns out to be oriented, so that one can speak of the field of positive normals to $ V $.
Let $ i _ {+} : V \rightarrow Y $
be a small displacement along this field, where $ Y $
is the complement to an open tubular neighbourhood of $ V $
in $ S ^ {n+} 2 $.
If $ n = 2 q - 1 $
is odd, one defines a pairing
$$ \theta : H _ {q} V \otimes H _ {q} V \rightarrow \mathbf Z , $$
associating with an element $ z _ {1} \otimes z _ {2} $ the linking coefficient of the classes $ z _ {1} \in H _ {q} V $ and $ i _ {+} * z _ {2} \in H _ {q} Y $. This $ \theta $ is known as the Seifert pairing of the link $ L $. If $ z _ {1} $ and $ z _ {2} $ are of finite order, then $ \theta ( z _ {1} \otimes z _ {2} ) = 0 $. The following formula is valid:
$$ \theta ( z _ {1} \otimes z _ {2} ) + ( - 1 ) ^ {q} \theta ( z _ {2} \otimes z _ {1} ) = z _ {1} \cdot z _ {2} , $$
where the right-hand side is the intersection index (in homology) of the classes $ z _ {1} $ and $ z _ {2} $ on $ V $.
Let $ e _ {1} \dots e _ {k} $ be a basis for the free part of the group $ H _ {q} V $. The $ ( k \times k ) $- matrix $ A = \| \theta ( e _ {i} \otimes e _ {j} ) \| $ with integer entries is called the Seifert matrix of $ L $. The Seifert matrix of any $ ( 2 q - 1 ) $- dimensional knot has the following property: The matrix $ A = ( - 1 ) ^ {q} A ^ \prime $ is unimodular (cf. Unimodular matrix), and for $ q = 2 $ the signature of the matrix $ A + A ^ \prime $ is divisible by $ 16 $( $ A ^ \prime $ is the transpose of $ A $). Any square matrix $ A $ with integer entries is the Seifert matrix of some $ ( 2 q - 1 ) $- dimensional knot if $ q \neq 2 $, and the matrix $ A + ( - 1 ) ^ {q} A ^ \prime $ is unimodular.
The Seifert matrix itself is not an invariant of the link $ L $; the reason is that the construction of the Seifert manifold $ V $ and the choice of the basis $ e _ {1} \dots e _ {k} $ are not unique. Matrices of the form
$$ \left \| \begin{array}{lcc} A &{} & 0 \\ \alpha & 0 & 1 \\ 0 & 1 & 0 \\ \end{array} \right \| ,\ \ \left \| \begin{array}{lll} A &\beta & 0 \\ 0 & 0 & 1 \\ {} & 0 & 0 \\ \end{array} \right \| , $$
where $ \alpha $ is a row-vector and $ \beta $ a column-vector, are known as elementary expansions of $ A $, while $ A $ itself is called an elementary reduction of its elementary expansions. Two square matrices are said to be $ S $- equivalent if one can be derived from the other via elementary reductions, elementary expansions and unimodular congruences (i.e. transformations $ A \rightarrow P ^ \prime A P $, where $ P $ is a unimodular matrix). For higher-dimensional knots $ ( m = 1 ) $ and one-dimensional links $ ( n = 1 ) $ the $ S $- equivalence class of the Seifert matrix is an invariant of the type of the link $ L $. In case $ L $ is a knot, the Seifert matrix $ A $ uniquely determines a $ \mathbf Z [ t , t ^ {-} 1 ] $- module $ H _ {q} \widetilde{X} $, where $ \widetilde{X} $ is an infinite cyclic covering of the complement of the knot. The polynomial matrix $ t A + ( - 1 ) ^ {q} A ^ \prime $ is the Alexander matrix (see Alexander invariants) of the module $ H _ {q} \widetilde{X} $. The Seifert matrix also determines the $ q $- dimensional homology and the linking coefficients in the cyclic coverings of the sphere $ S ^ {2q+} 1 $ that ramify over the link.
References
[1] | H. Seifert, "Ueber das Geschlecht von Knoten" Math. Ann. , 110 (1934) pp. 571–592 |
[2] | R.H. Crowell, R.H. Fox, "Introduction to knot theory" , Ginn (1963) |
[3] | J. Levine, "Polynomial invariants of knots of codimension two" Ann. of Math. , 84 (1966) pp. 537–554 |
[4] | J. Levine, "An algebraic classification of some knots of codimension two" Comment. Math. Helv. , 45 (1970) pp. 185–198 |
Comments
For a description of the Seifert manifold in the case $ n = 1 $, i.e. the Seifert surface of a link, cf. Knot and link diagrams.
Seifert matrix. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Seifert_matrix&oldid=49419