Arf invariant
Encyclopedia
In mathematics
Mathematics
Mathematics is the study of quantity, space, structure, and change. Mathematicians seek out patterns and formulate new conjectures. Mathematicians resolve the truth or falsity of conjectures by mathematical proofs, which are arguments sufficient to convince other mathematicians of their validity...

, the Arf invariant of a nonsingular quadratic form
Quadratic form
In mathematics, a quadratic form is a homogeneous polynomial of degree two in a number of variables. For example,4x^2 + 2xy - 3y^2\,\!is a quadratic form in the variables x and y....

 over a field of characteristic 2 was defined by
when he started the systematic study of quadratic forms over arbitrary fields of characteristic
2. The Arf invariant is the substitute, in
characteristic 2, of the discriminant for quadratic
forms in characteristic not 2. Arf used his invariant,
among others, in his endeavor to classify quadratic
forms in characteristic 2.

In the special case of
the 2-element field F2
GF(2)
GF is the Galois field of two elements. It is the smallest finite field.- Definition :The two elements are nearly always called 0 and 1, being the additive and multiplicative identities, respectively...

 the Arf invariant can be described as the element of F2 that occurs most often among the values of the form. Two nonsingular quadratic forms over F2 are isomorphic if and only if they have the same dimension and the same Arf invariant. This fact was essentially known to , even for any finite field of characteristic 2, and it follows from Arf's results for an arbitrary perfect field. An assessment of Arf's results in the framework of the theory of quadratic forms can be found in ,

The Arf invariant is particularly applied in geometric topology
Geometric topology
In mathematics, geometric topology is the study of manifolds and maps between them, particularly embeddings of one manifold into another.- Topics :...

, where it is primarily used to define an invariant of (4k+2)-dimensional manifolds (singly even-dimension manifolds: surfaces (2-manifolds), 6-manifolds, 10-manifolds, etc.) with certain additional structure called a framing, and thus the Arf–Kervaire invariant and the Arf invariant of a knot. The Arf invariant is analogous to the signature of a manifold, which is defined for 4k-dimensional manifolds (doubly even-dimensional); this 4-fold periodicity corresponds to the 4-fold periodicity of L-theory
L-theory
Algebraic L-theory is the K-theory of quadratic forms; the term was coined by C. T. C. Wall,with L being used as the letter after K. Algebraic L-theory, also known as 'hermitian K-theory',is important in surgery theory.-Definition:...

. The Arf invariant can also be defined more generally for certain 2k-dimensional manifolds.

Definitions

The Arf invariant belongs to a quadratic form
Quadratic form
In mathematics, a quadratic form is a homogeneous polynomial of degree two in a number of variables. For example,4x^2 + 2xy - 3y^2\,\!is a quadratic form in the variables x and y....

 over a field K of characteristic 2.
Any binary non-singular
quadratic form over K is equivalent
to a form with in K.
The Arf invariant is defined to be the product .
If the form is
equivalent to , then the products and
differ
by an element of the form with in K. These
elements form an additive subgroup U of K. Hence the
coset of modulo U is an invariant of , which
means that it is not changed when is replaced by
an equivalent form.

Every nonsingular quadratic form over K is equivalent
to a direct sum of nonsingular
binary forms. This has been shown by Arf but it had
been earlier observed by Dickson in the case of finite
fields of characteristic 2. The Arf invariant Arf() is
defined to be the sum of the Arf invariants of the
. By definition, this is a coset
of K modulo U. Arf has shown that indeed Arf()
does not change if is replaced by an equivalent
quadratic form, which is to say that it is an invariant of
.

The Arf invariant is additive; in other words, the Arf invariant of an orthogonal sum of two quadratic forms is the sum of their Arf invariants.

Arf's main results

If the field K is perfect then
every nonsingular quadratic form over K is uniquely
determined (up to equivalence) by its dimension and
its Arf invariant. In particular this holds over the field
F2. In this case U=0 and hence
the Arf invariant is an element of the base field
F2; it is either 0 or 1.

If the field is not perfect then the Clifford algebra
Clifford algebra
In mathematics, Clifford algebras are a type of associative algebra. As K-algebras, they generalize the real numbers, complex numbers, quaternions and several other hypercomplex number systems. The theory of Clifford algebras is intimately connected with the theory of quadratic forms and orthogonal...


is another important invariant of a quadratic form.
For various fields Arf has shown that every quadratic
form is
completely characterized by its dimension, its Arf
invariant
and its Clifford algebra. Examples of such fields are
function fields (or power series fields) of one
variable over perfect base fields.

Quadratic forms over F2

Over F2
the Arf invariant is 0 if the quadratic form is equivalent to a direct sum of copies of the binary form , and it is 1 if the form is a direct sum of with a number of copies of .

William Browder
William Browder (mathematician)
William Browder is an American mathematician, specializing in algebraic topology, differential topology and differential geometry...

 has called the Arf invariant the democratic invariant because it is the value which is assumed most often by the quadratic form. Another characterization: q has Arf invariant 0 if and only if the underlying 2k-dimensional vector space over the field F2 has a k-dimensional subspace on which q is identically 0 – that is, a totally isotropic subspace of half the dimension; its isotropy index is k (this is the maximum dimension of a totally isotropic subspace of a nonsingular form).

The Arf invariant in topology

Let M be a compact
Compact space
In mathematics, specifically general topology and metric topology, a compact space is an abstract mathematical space whose topology has the compactness property, which has many important implications not valid in general spaces...

, connected
Connected space
In topology and related branches of mathematics, a connected space is a topological space that cannot be represented as the union of two or more disjoint nonempty open subsets. Connectedness is one of the principal topological properties that is used to distinguish topological spaces...

 2k-dimensional manifold
Manifold
In mathematics , a manifold is a topological space that on a small enough scale resembles the Euclidean space of a specific dimension, called the dimension of the manifold....

 with a boundary
such that the induced morphisms in -coefficient homology,
are both zero (e.g. if is closed). The intersection form
Intersection theory
In mathematics, intersection theory is a branch of algebraic geometry, where subvarieties are intersected on an algebraic variety, and of algebraic topology, where intersections are computed within the cohomology ring. The theory for varieties is older, with roots in Bézout's theorem on curves and...


is non-singular. (Topologists usually write F2 as .) A quadratic refinement for is a function which satisfies
Let be any 2-dimensional subspace of , such that . Then there are two possibilities. Either all of are 1, or else just one of them is 1, and the other two are 0. Call the first case , and the second case .
Since every form is equivalent to a symplectic form, we can always find subspaces with x and y being -dual. We can therefore split into a direct sum of subspaces isomorphic to either or .
Furthermore, by a clever change of basis, .
We therefore define the Arf invariant = (number of copies of in a decomposition Mod 2) .

Examples

  • Let be a compact, connected, oriented 2-dimensional manifold
    Manifold
    In mathematics , a manifold is a topological space that on a small enough scale resembles the Euclidean space of a specific dimension, called the dimension of the manifold....

    , i.e. a surface
    Surface
    In mathematics, specifically in topology, a surface is a two-dimensional topological manifold. The most familiar examples are those that arise as the boundaries of solid objects in ordinary three-dimensional Euclidean space R3 — for example, the surface of a ball...

    , of genus
    Genus
    In biology, a genus is a low-level taxonomic rank used in the biological classification of living and fossil organisms, which is an example of definition by genus and differentia...

      such that the boundary is either empty or is connected. Embed  in , where . Choose a framing of M, that is a trivialization of the normal (m-2)-plane vector bundle
    Vector bundle
    In mathematics, a vector bundle is a topological construction that makes precise the idea of a family of vector spaces parameterized by another space X : to every point x of the space X we associate a vector space V in such a way that these vector spaces fit together...

    . (This is possible for , so is certainly possible for ). Choose a symplectic basis
    Symplectic vector space
    In mathematics, a symplectic vector space is a vector space V equipped with a bilinear form ω : V × V → R that is...

      for . Each basis element is represented by an embedded circle . The normal (m-1)-plane vector bundle
    Vector bundle
    In mathematics, a vector bundle is a topological construction that makes precise the idea of a family of vector spaces parameterized by another space X : to every point x of the space X we associate a vector space V in such a way that these vector spaces fit together...

     of has two trivializations, one determined by a standard framing of a standard embedding and one determined by the framing of M, which differ by a map i.e. an element of for . This can also be viewed as the framed cobordism class of with this framing in the 1-dimensional framed cobordism group , which is generated by the circle with the Lie group framing. The isomorphism here is via the Pontrjagin-Thom construction.) Define to be this element. The Arf invariant of the framed surface is now defined

Note that , so we had to stabilise, taking to be at least 4, in order to get an element of . The case is also admissible as long as we take the residue modulo 2 of the framing.
  • The Arf invariant of a framed surface detects whether there is a 3-manifold whose boundary is the given surface which extends the given framing. This is because does not bound. represents a torus with a trivialisation on both generators of which twists an odd number of times. The key fact is that up to homotopy there are two choices of trivialisation of a trivial 3-plane bundle over a circle, corresponding to the two elements of . An odd number of twists, known as the Lie group framing, does not extend across a disc, whilst an even number of twists does. (Note that this corresponds to putting a spin structure
    Spin structure
    In differential geometry, a spin structure on an orientable Riemannian manifold \,allows one to define associated spinor bundles, giving rise to the notion of a spinor in differential geometry....

     on our surface.) Pontrjagin used the Arf invariant of framed surfaces to compute the 2-dimensional framed cobordism
    Cobordism
    In mathematics, cobordism is a fundamental equivalence relation on the class of compact manifolds of the same dimension, set up using the concept of the boundary of a manifold. Two manifolds are cobordant if their disjoint union is the boundary of a manifold one dimension higher. The name comes...

     group , which is generated by the torus
    Torus
    In geometry, a torus is a surface of revolution generated by revolving a circle in three dimensional space about an axis coplanar with the circle...

      with the Lie group framing. The isomorphism here is via the Pontrjagin-Thom construction.

  • Let be a Seifert surface
    Seifert surface
    In mathematics, a Seifert surface is a 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 example, many knot invariants are most easily calculated using a Seifert surface...

     for a knot, , which can be represented as a disc with bands attached. The bands will typically be twisted and knotted. Each band corresponds to a generator . can be represented by a circle which traverses one of the bands. Define to be the number of full twists in the band modulo 2. Suppose we let bound , and push the Seifert surface into , so that its boundary still resides in . Around any generator , we now have a trivial normal 3-plane vector bundle. Trivialise it using the trivial framing of the normal bundle to the embedding for 2 of the sections required. For the third, choose a section which remains normal to , whilst always remaining tangent to . This trivialisation again determines an element of , which we take to be . Note that this coincides with the previous definition of .

  • The Arf invariant of a knot
    Arf invariant (knot)
    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...

     is defined via its Seifert surface. It is independent of the choice of Seifert surface (The basic surgery change of S-equivalence, adding/removing a tube, adds/deletes a direct summand), and so is a knot invariant
    Knot invariant
    In the mathematical field of knot theory, a knot invariant is a quantity defined for each knot which is the same for equivalent knots. The equivalence is often given by ambient isotopy but can be given by homeomorphism. Some invariants are indeed numbers, but invariants can range from the...

    . It is additive under connected sum
    Connected sum
    In mathematics, specifically in topology, the operation of connected sum is a geometric modification on manifolds. Its effect is to join two given manifolds together near a chosen point on each...

    , and vanishes on slice knots, so is a knot concordance invariant.

  • The intersection form
    Intersection form
    Intersection form may refer to:*Intersection theory *intersection form...

      on the 2k+1-dimensional -coefficient homology of a framed 4k+2-dimensional manifold M has a quadratic refinement , which depends on the framing. For and represented by an embedding
    Embedding
    In mathematics, an embedding is one instance of some mathematical structure contained within another instance, such as a group that is a subgroup....

      the value is 0 or 1, according as to the normal bundle of is trivial or not. The Kervaire invariant of the framed 4k+2-dimensional manifold M is the Arf invariant of the quadratic refinement on . The Kervaire invariant is a homomorphism on the 4k+2-dimensional stable homotopy group of spheres. The Kervaire invariant can also be defined for a 4k+2-dimensional manifold M which is framed except at a point.

  • In surgery theory
    Surgery theory
    In mathematics, specifically in geometric topology, surgery theory is a collection of techniques used to produce one manifold from another in a 'controlled' way, introduced by . Surgery refers to cutting out parts of the manifold and replacing it with a part of another manifold, matching up along...

    , for any -dimensional normal map there is defined a nonsingular quadratic form on the -coefficient homology kernel refining the homological intersection form . The Arf invariant of this form is the Kervaire invariant of (f,b). In the special case this is the Kervaire invariant of M. The Kervaire invariant features in the classification of exotic sphere
    Exotic sphere
    In differential topology, a mathematical discipline, an exotic sphere is a differentiable manifold M that is homeomorphic but not diffeomorphic to the standard Euclidean n-sphere...

    s by Kervaire and Milnor, and more generally in the classification of manifolds by surgery theory
    Surgery theory
    In mathematics, specifically in geometric topology, surgery theory is a collection of techniques used to produce one manifold from another in a 'controlled' way, introduced by . Surgery refers to cutting out parts of the manifold and replacing it with a part of another manifold, matching up along...

    . Browder
    William Browder (mathematician)
    William Browder is an American mathematician, specializing in algebraic topology, differential topology and differential geometry...

     defined using functional Steenrod squares, and Wall defined using framed immersion
    Immersion
    Immersion may refer to:* Immersion therapy overcoming fears through confrontation* Baptism by immersion* Immersion Games a developer of video games...

    s. The quadratic enhancement crucially provides more information than : it is possible to kill x by surgery if and only if . The corresponding Kervaire invariant detects the surgery obstruction of in the L-group
    L-theory
    Algebraic L-theory is the K-theory of quadratic forms; the term was coined by C. T. C. Wall,with L being used as the letter after K. Algebraic L-theory, also known as 'hermitian K-theory',is important in surgery theory.-Definition:...

    .
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