Steinberg symbol
In mathematics a Steinberg symbol is a pairing function which generalises the Hilbert symbol and plays a role in the algebraic K-theory of fields. It is named after mathematician Robert Steinberg.
For a field F we define a Steinberg symbol (or simply a symbol) to be a function , where G is an abelian group, written multiplicatively, such that
- is bimultiplicative;
- if then .
The symbols on F derive from a "universal" symbol, which may be regarded as taking values in . By a theorem of Matsumoto, this group is and is part of the Milnor K-theory for a field.
Properties
If (⋅,⋅) is a symbol then (assuming all terms are defined)
- ;
- ;
- is an element of order 1 or 2;
- .
Examples
- The trivial symbol which is identically 1.
- The Hilbert symbol on F with values in {±1} defined by[1][2]
- The Contou-Carrère symbol is a symbol for the ring of Laurent power series over an Artinian ring.
Continuous symbols
If F is a topological field then a symbol c is weakly continuous if for each y in F∗ the set of x in F∗ such that c(x,y) = 1 is closed in F∗. This makes no reference to a topology on the codomain G. If G is a topological group, then one may speak of a continuous symbol, and when G is Hausdorff then a continuous symbol is weakly continuous.[3]
The only weakly continuous symbols on R are the trivial symbol and the Hilbert symbol: the only weakly continuous symbol on C is the trivial symbol.[4] The characterisation of weakly continuous symbols on a non-Archimedean local field F was obtained by Moore. The group K2(F) is the direct sum of a cyclic group of order m and a divisible group K2(F)m. A symbol on F lifts to a homomorphism on K2(F) and is weakly continuous precisely when it annihilates the divisible component K2(F)m. It follows that every weakly continuous symbol factors through the norm residue symbol.[5]
See also
References
- ↑ Serre, Jean-Pierre (1996). A Course in Arithmetic. Graduate Texts in Mathematics. 7. Berlin, New York: Springer-Verlag. ISBN 978-3-540-90040-5.
- ↑ Milnor (1971) p.94
- ↑ Milnor (1971) p.165
- ↑ Milnor (1971) p.166
- ↑ Milnor (1971) p.175
- Conner, P.E.; Perlis, R. (1984). A Survey of Trace Forms of Algebraic Number Fields. Series in Pure Mathematics. 2. World Scientific. ISBN 9971-966-05-0. Zbl 0551.10017.
- Lam, Tsit-Yuen (2005). Introduction to Quadratic Forms over Fields. Graduate Studies in Mathematics. 67. American Mathematical Society. pp. 132–142. ISBN 0-8218-1095-2. Zbl 1068.11023.
- Milnor, John Willard (1971). Introduction to algebraic K-theory. Annals of Mathematics Studies. 72. Princeton, NJ: Princeton University Press. MR 0349811. Zbl 0237.18005.
- Steinberg, Robert (1962). "Générateurs, relations et revêtements de groupes algébriques". Colloq. Théorie des Groupes Algébriques (in French). Bruxelles: Gauthier-Villars: 113–127. MR MR0153677. Zbl 0272.20036.