Essential dimension

In mathematics, essential dimension is an invariant defined for certain algebraic structures such as algebraic groups and quadratic forms. It was introduced by J. Buhler and Z. Reichstein^[1] and in its most generality defined by A. Merkurjev.^[2]

Basically, essential dimension measures the complexity of algebraic structures via their fields of definition. For example, a quadratic form q : V → K over a field K, where V is a K-vector space, is said to be defined over a subfield L of K if there exists a K-basis e₁,...,e_n of V such that q can be expressed in the form $q\left(\sum x_{i}e_{i}\right)=\sum a_{ij}x_{i}x_{j}$ with all coefficients a_ij belonging to L. If K has characteristic different from 2, every quadratic form is diagonalizable. Therefore, q has a field of definition generated by n elements. Technically, one always works over a (fixed) base field k and the fields K and L in consideration are supposed to contain k. The essential dimension of q is then defined as the least transcendence degree over k of a subfield L of K over which q is defined.

Formal definition edit

Fix an arbitrary field k and let $Fields$ /k denote the category of finitely generated field extensions of k with inclusions as morphisms. Consider a (covariant) functor F : $Fields$ /k → $Set$ . For a field extension K/k and an element a of F(K/k) a field of definition of a is an intermediate field K/L/k such that a is contained in the image of the map F(L/k) → F(K/k) induced by the inclusion of L in K.

The essential dimension of a, denoted by ed(a), is the least transcendence degree (over k) of a field of definition for a. The essential dimension of the functor F, denoted by ed(F), is the supremum of ed(a) taken over all elements a of F(K/k) and objects K/k of $Fields$ /k.

Examples edit

Essential dimension of quadratic forms: For a natural number n consider the functor Q_n : $Fields$ /k → $Set$ taking a field extension K/k to the set of isomorphism classes of non-degenerate n-dimensional quadratic forms over K and taking a morphism L/k → K/k (given by the inclusion of L in K) to the map sending the isomorphism class of a quadratic form q : V → L to the isomorphism class of the quadratic form $q_{K}:V\otimes _{L}K\to K$ .
Essential dimension of algebraic groups: For an algebraic group G over k denote by H¹(−,G) : $Fields$ /k → $Set$ the functor taking a field extension K/k to the set of isomorphism classes of G-torsors over K (in the fppf-topology). The essential dimension of this functor is called the essential dimension of the algebraic group G, denoted by ed(G).
Essential dimension of a fibered category: Let ${\mathcal {F}}$ be a category fibered over the category $Aff/k$ of affine k-schemes, given by a functor $p:{\mathcal {F}}\to Aff/k.$ For example, ${\mathcal {F}}$ may be the moduli stack ${\mathcal {M}}_{g}$ of genus g curves or the classifying stack ${\mathcal {BG}}$ of an algebraic group. Assume that for each $A\in Aff/k$ the isomorphism classes of objects in the fiber p⁻¹(A) form a set. Then we get a functor F_p : $Fields$ /k → $Set$ taking a field extension K/k to the set of isomorphism classes in the fiber $p^{-1}(Spec(K))$ . The essential dimension of the fibered category ${\mathcal {F}}$ is defined as the essential dimension of the corresponding functor F_p. In case of the classifying stack ${\mathcal {F}}={\mathcal {BG}}$ of an algebraic group G the value coincides with the previously defined essential dimension of G.

Known results edit

The essential dimension of a linear algebraic group G is always finite and bounded by the minimal dimension of a generically free representation minus the dimension of G.
For G a Spin group over an algebraically closed field k, the essential dimension is listed in OEIS: A280191.
The essential dimension of a finite algebraic p-group over k equals the minimal dimension of a faithful representation, provided that the base field k contains a primitive p-th root of unity.
The essential dimension of the symmetric group S_n (viewed as algebraic group over k) is known for n ≤ 5 (for every base field k), for n = 6 (for k of characteristic not 2) and for n = 7 (in characteristic 0).
Let T be an algebraic torus admitting a Galois splitting field L/k of degree a power of a prime p. Then the essential dimension of T equals the least rank of the kernel of a homomorphism of Gal(L/k)-lattices P → X(T) with cokernel finite and of order coprime to p, where P is a permutation lattice.

References edit

^ Buhler, J.; Reichstein, Z. (1997). "On the essential dimension of a finite group". Compositio Mathematica. 106 (2): 159–179. doi:10.1023/A:1000144403695.
^ Berhuy, G.; Favi, G. (2003). "Essential Dimension: a Functorial Point of View (after A. Merkurjev)". Documenta Mathematica. 8: 279–330 (electronic).

[1] Buhler, J.; Reichstein, Z. (1997). "On the essential dimension of a finite group". Compositio Mathematica. 106 (2): 159–179. doi:10.1023/A:1000144403695.

[2] Berhuy, G.; Favi, G. (2003). "Essential Dimension: a Functorial Point of View (after A. Merkurjev)". Documenta Mathematica. 8: 279–330 (electronic).

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