Arf invariant of a knot: Difference between revisions

Template:Short description In the mathematical field of knot theory, the Arf invariant of a knot, named after Cahit Arf, is a knot invariant obtained from a quadratic form associated to a Seifert surface. If F is a Seifert surface of a knot, then the homology group Template:Nowrap has a quadratic form whose value is the number of full twists mod 2 in a neighborhood of an embedded circle representing an element of the homology group. The Arf invariant of this quadratic form is the Arf invariant of the knot.

Let ${\displaystyle V=v_{i,j}}$ be a Seifert matrix of the knot, constructed from a set of curves on a Seifert surface of genus g which represent a basis for the first homology of the surface. This means that V is a Template:Nowrap matrix with the property that Template:Nowrap is a symplectic matrix. The Arf invariant of the knot is the residue of

${\displaystyle \sum _{i=1}^g{v}_{2i-1,2i-1}{v}_{2i,2i}(\mathrm{mod}2).}$

Specifically, if ${\displaystyle \{a_i,b_i\},i=1\dots g}$, is a symplectic basis for the intersection form on the Seifert surface, then

${\displaystyle \mathrm{Arf}(K)=\sum _{i=1}^g\mathrm{lk}(a_i,a_i^{+})\mathrm{lk}(b_i,b_i^{+})(\mathrm{mod}2).}$

where lk is the link number and ${\displaystyle a^{+}}$ denotes the positive pushoff of a.

This approach to the Arf invariant is due to Louis Kauffman.

We define two knots to be pass equivalent if they are related by a finite sequence of pass-moves.^[1]

Every knot is pass-equivalent to either the unknot or the trefoil; these two knots are not pass-equivalent and additionally, the right- and left-handed trefoils are pass-equivalent.^[2]

Now we can define the Arf invariant of a knot to be 0 if it is pass-equivalent to the unknot, or 1 if it is pass-equivalent to the trefoil. This definition is equivalent to the one above.

Vaughan Jones showed that the Arf invariant can be obtained by taking the partition function of a signed planar graph associated to a knot diagram.

This approach to the Arf invariant is by Raymond Robertello.^[3] Let

${\displaystyle \mathrm{\Delta }(t)=c_0+c_{1}t+\cdots +c_n{t}^n+\cdots +c_0{t}^{2n}}$

be the Alexander polynomial of the knot. Then the Arf invariant is the residue of

${\displaystyle c_{n-1}+c_{n-3}+\cdots +c_r}$

modulo 2, where Template:Nowrap for n odd, and Template:Nowrap for n even.

Kunio Murasugi^[4] proved that the Arf invariant is zero if and only if Template:Nowrap.

From the Fox-Milnor criterion, which tells us that the Alexander polynomial of a slice knot ${\displaystyle K\subset {𝕊}^3}$ factors as ${\displaystyle \mathrm{\Delta }(t)=p(t)p\left(t^{-1}\right)}$ for some polynomial ${\displaystyle p(t)}$ with integer coefficients, we know that the determinant ${\displaystyle |\mathrm{\Delta }(-1)|}$ of a slice knot is a square integer. As ${\displaystyle |\mathrm{\Delta }(-1)|}$ is an odd integer, it has to be congruent to 1 modulo 8. Combined with Murasugi's result, this shows that the Arf invariant of a slice knot vanishes.

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