Signature Of A Knot
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The signature of a knot is a
topological invariant In topology and related areas of mathematics, a topological property or topological invariant is a property of a topological space that is invariant under homeomorphisms. Alternatively, a topological property is a proper class of topological space ...
in
knot theory In topology, knot theory is the study of knot (mathematics), mathematical knots. While inspired by knots which appear in daily life, such as those in shoelaces and rope, a mathematical knot differs in that the ends are joined so it cannot be und ...
. It may be computed from the
Seifert surface In mathematics, a Seifert surface (named after German mathematician Herbert Seifert) is an orientable surface whose boundary is a given knot or link. Such surfaces can be used to study the properties of the associated knot or link. For exampl ...
. Given a
knot A knot is an intentional complication in Rope, cordage which may be practical or decorative, or both. Practical knots are classified by function, including List of hitch knots, hitches, List of bend knots, bends, List of loop knots, loop knots, ...
''K'' in the
3-sphere In mathematics, a hypersphere or 3-sphere is a 4-dimensional analogue of a sphere, and is the 3-dimensional n-sphere, ''n''-sphere. In 4-dimensional Euclidean space, it is the set of points equidistant from a fixed central point. The interior o ...
, it has a
Seifert surface In mathematics, a Seifert surface (named after German mathematician Herbert Seifert) is an orientable surface whose boundary is a given knot or link. Such surfaces can be used to study the properties of the associated knot or link. For exampl ...
''S'' whose boundary is ''K''. The Seifert form of ''S'' is the pairing \phi : H_1(S) \times H_1(S) \to \mathbb Z given by taking the
linking number In mathematics, the linking number is a numerical invariant that describes the linking of two closed curves in three-dimensional space. Intuitively, the linking number represents the number of times that each curve winds around the other. In E ...
\operatorname(a^+,b^-) where a, b \in H_1(S) and a^+, b^- indicate the translates of ''a'' and ''b'' respectively in the positive and negative directions of the
normal bundle In differential geometry, a field of mathematics, a normal bundle is a particular kind of vector bundle, complementary to the tangent bundle, and coming from an embedding (or immersion). Definition Riemannian manifold Let (M,g) be a Riemannian ...
to ''S''. Given a basis b_1,...,b_ for H_1(S) (where ''g'' is the genus of the surface) the Seifert form can be represented as a ''2g''-by-''2g''
Seifert matrix In mathematics, a Seifert surface (named after German mathematician Herbert Seifert) is an orientable surface whose boundary is a given knot or link. Such surfaces can be used to study the properties of the associated knot or link. For exampl ...
''V'', V_=\phi(b_i,b_j). The
signature A signature (; from , "to sign") is a depiction of someone's name, nickname, or even a simple "X" or other mark that a person writes on documents as a proof of identity and intent. Signatures are often, but not always, Handwriting, handwritt ...
of the matrix V+V^t, thought of as a symmetric bilinear form, is the signature of the knot ''K''.
Slice knot A slice knot is a knot (mathematics), mathematical knot in 3-dimensional space that bounds an embedded disk in 4-dimensional space. Definition A knot K \subset S^3 is said to be a topologically slice knot or a smoothly slice knot, if it is the ...
s are known to have zero signature.


The Alexander module formulation

Knot signatures can also be defined in terms of the Alexander module of the knot complement. Let X be the universal abelian cover of the knot complement. Consider the Alexander module to be the first
homology group In mathematics, the term homology, originally introduced in algebraic topology, has three primary, closely-related usages. The most direct usage of the term is to take the ''homology of a chain complex'', resulting in a sequence of abelian grou ...
of the universal abelian cover of the knot complement: H_1(X;\mathbb Q). Given a \mathbb Q mathbb Z/math>-module V, let \overline denote the \mathbb Q mathbb Z/math>-module whose underlying \mathbb Q-module is V but where \mathbb Z acts by the inverse covering transformation. Blanchfield's formulation of
Poincaré duality In mathematics, the Poincaré duality theorem, named after Henri Poincaré, is a basic result on the structure of the homology (mathematics), homology and cohomology group (mathematics), groups of manifolds. It states that if ''M'' is an ''n''-dim ...
for X gives a canonical isomorphism H_1(X;\mathbb Q) \simeq \overline where H^2(X;\mathbb Q) denotes the 2nd cohomology group of X with compact supports and coefficients in \mathbb Q. The universal coefficient theorem for H^2(X;\mathbb Q) gives a canonical isomorphism with \operatorname_(H_1(X;\mathbb Q),\mathbb Q mathbb Z (because the Alexander module is \mathbb Q mathbb Z/math>-torsion). Moreover, just like in the quadratic form formulation of Poincaré duality, there is a canonical isomorphism of \mathbb Q mathbb Z/math>-modules \operatorname_(H_1(X;\mathbb Q),\mathbb Q mathbb Z \simeq \operatorname_(H_1(X;\mathbb Q), mathbb Q[\mathbb Z/\mathbb Q[\mathbb Z">mathbb_Z.html" ;"title="mathbb Q[\mathbb Z">mathbb Q[\mathbb Z/\mathbb Q[\mathbb Z), where mathbb Q[\mathbb Z denotes the field of fractions of \mathbb Q mathbb Z/math>. This isomorphism can be thought of as a sesquilinear duality pairing H_1(X;\mathbb Q) \times H_1(X;\mathbb Q) \to mathbb Q[\mathbb Z/\mathbb Q mathbb Z/math> where mathbb Q[\mathbb Z denotes the field of fractions of \mathbb Q mathbb Z/math>. This form takes value in the rational polynomials whose denominators are the Alexander polynomial of the knot, which as a \mathbb Q mathbb Z/math>-module is isomorphic to \mathbb Q mathbb Z\Delta K. Let tr : \mathbb Q mathbb Z\Delta K \to \mathbb Q be any linear function which is invariant under the involution t \longmapsto t^, then composing it with the sesquilinear duality pairing gives a symmetric bilinear form on H_1 (X;\mathbb Q) whose signature is an invariant of the knot. All such signatures are concordance invariants, so all signatures of
slice knot A slice knot is a knot (mathematics), mathematical knot in 3-dimensional space that bounds an embedded disk in 4-dimensional space. Definition A knot K \subset S^3 is said to be a topologically slice knot or a smoothly slice knot, if it is the ...
s are zero. The sesquilinear duality pairing respects the prime-power decomposition of H_1 (X;\mathbb Q)—i.e.: the prime power decomposition gives an orthogonal decomposition of H_1 (X;\mathbb R). Cherry Kearton has shown how to compute the ''Milnor signature invariants'' from this pairing, which are equivalent to the ''Tristram-Levine invariant''.


See also

*
Link concordance In mathematics, two links L_0 \subset S^n and L_1 \subset S^n are concordant if there exists an embedding f : L_0 \times ,1\to S^n \times ,1/math> such that f(L_0 \times \) = L_0 \times \ and f(L_0 \times \) = L_1 \times \. By its nature, link ...


References

* C.Gordon, Some aspects of classical knot theory. Springer Lecture Notes in Mathematics 685. Proceedings Plans-sur-Bex Switzerland 1977. * J.Hillman, Algebraic invariants of links. Series on Knots and everything. Vol 32. World Scientific. * C.Kearton, Signatures of knots and the free differential calculus, Quart. J. Math. Oxford (2), 30 (1979). * J.Levine, Knot cobordism groups in codimension two, Comment. Math. Helv. 44, 229-244 (1969) * J.Milnor, Infinite cyclic coverings, J.G. Hocking, ed. Conf. on the Topology of Manifolds, Prindle, Weber and Schmidt, Boston, Mass, 1968 pp. 115–133. * K.Murasugi, On a certain numerical invariant of link types, Trans. Amer. Math. Soc. 117, 387-482 (1965) * A.Ranick
On signatures of knots
Slides of lecture given in Durham on 20 June 2010. * H.Trotter, Homology of group systems with applications to knot theory, Ann. of Math. (2) 76, 464-498 (1962) {{DEFAULTSORT:Signature Of A Knot Knot invariants