Local field

Given such an absolute value on a fieldK,the following topology can be defined onK:for a positive real numberm,define the subsetB_mofKby

${\displaystyle B_{m}:=\{a\in K:|a|\leq m\}.}$

Then, theb+B_mmake up aneighbourhood basisof b inK.

Conversely, a topological field with a non-discrete locally compact topology has an absolute value defining its topology. It can be constructed using theHaar measureof theadditive groupof the field.

For a non-Archimedean local fieldF(with absolute value denoted by |·|), the following objects are important:

• itsring of integers${\displaystyle {\mathcal {O}}=\{a\in F:|a|\leq 1\}}$which is adiscrete valuation ring,is the closedunit ballofF,and iscompact;
• theunitsin its ring of integers${\displaystyle {\mathcal {O}}^{\times }=\{a\in F:|a|=1\}}$which forms agroupand is theunit sphereofF;
• the unique non-zeroprime ideal${\displaystyle {\mathfrak {m}}}$in its ring of integers which is its open unit ball${\displaystyle \{a\in F:|a|<1\}}$;
• agenerator${\displaystyle \varpi }$of${\displaystyle {\mathfrak {m}}}$called auniformizerof${\displaystyle F}$;
• its residue field${\displaystyle k={\mathcal {O}}/{\mathfrak {m}}}$which is finite (since it is compact anddiscrete).

Every non-zero elementaofFcan be written asa= ϖⁿuwithua unit, andna unique integer. Thenormalized valuationofFis thesurjective functionv:F→Z∪ {∞} defined by sending a non-zeroato the unique integernsuch thata= ϖⁿuwithua unit, and by sending 0 to ∞. Ifqis thecardinalityof the residue field, the absolute value onFinduced by its structure as a local field is given by:^[6]

${\displaystyle |a|=q^{-v(a)}.}$

An equivalent and very important definition of a non-Archimedean local field is that it is a field that iscomplete with respect to a discrete valuationand whose residue field is finite.

1. Thep-adic numbers:the ring of integers ofQ_pis the ring ofp-adic integersZ_p.Its prime ideal ispZ_pand its residue field isZ/pZ.Every non-zero element ofQ_pcan be written asupⁿwhereuis a unit inZ_pandnis an integer, thenv(upⁿ) =nfor the normalized valuation.
2. The formal Laurent series over a finite field:the ring of integers ofF_q((T)) is the ring offormal power seriesF_q[[T]]. Its maximal ideal is (T) (i.e. thepower serieswhoseconstant termis zero) and its residue field isF_q.Its normalized valuation is related to the (lower) degree of a formal Laurent series as follows:

   ${\displaystyle v\left(\sum _{i=-m}^{\infty }a_{i}T^{i}\right)=-m}$(wherea_−mis non-zero).

3. The formal Laurent series over the complex numbers isnota local field. For example, its residue field isC[[T]]/(T) =C,which is not finite.

Then^thhigher unit groupof a non-Archimedean local fieldFis

${\displaystyle U^{(n)}=1+{\mathfrak {m}}^{n}=\left\{u\in {\mathcal {O}}^{\times }:u\equiv 1\,(\mathrm {mod} \,{\mathfrak {m}}^{n})\right\}}$

forn≥ 1. The groupU⁽¹⁾is called thegroup of principal units,and any element of it is called aprincipal unit.The full unit group${\displaystyle {\mathcal {O}}^{\times }}$is denotedU⁽⁰⁾.

The higher unit groups form a decreasingfiltrationof the unit group

${\displaystyle {\mathcal {O}}^{\times }\supseteq U^{(1)}\supseteq U^{(2)}\supseteq \cdots }$

whosequotientsare given by

${\displaystyle {\mathcal {O}}^{\times }/U^{(n)}\cong \left({\mathcal {O}}/{\mathfrak {m}}^{n}\right)^{\times }{\text{ and }}\,U^{(n)}/U^{(n+1)}\approx {\mathcal {O}}/{\mathfrak {m}}}$

forn≥ 1.^[7](Here "${\displaystyle \approx }$"means a non-canonical isomorphism.)

The multiplicative group of non-zero elements of a non-Archimedean local fieldFis isomorphic to

${\displaystyle F^{\times }\cong (\varpi )\times \mu _{q-1}\times U^{(1)}}$

whereqis the order of the residue field, and μ_q−1is the group of (q−1)st roots of unity (inF). Its structure as an abelian group depends on itscharacteristic:

• IfFhas positive characteristicp,then

${\displaystyle F^{\times }\cong \mathbf {Z} \oplus \mathbf {Z} /{(q-1)}\oplus \mathbf {Z} _{p}^{\mathbf {N} }}$

whereNdenotes thenatural numbers;

• IfFhas characteristic zero (i.e. it is a finite extension ofQ_pof degreed), then

${\displaystyle F^{\times }\cong \mathbf {Z} \oplus \mathbf {Z} /(q-1)\oplus \mathbf {Z} /p^{a}\oplus \mathbf {Z} _{p}^{d}}$

wherea≥ 0 is defined so that the group ofp-power roots of unity inFis${\displaystyle \mu _{p^{a}}}$.^[8]

This theory includes the study of types of local fields, extensions of local fields usingHensel's lemma,Galois extensionsof local fields,ramification groupsfiltrations ofGalois groupsof local fields, the behavior of the norm map on local fields, the local reciprocity homomorphism and existence theorem inlocal class field theory,local Langlands correspondence,Hodge-Tate theory(also calledp-adic Hodge theory), explicit formulas for theHilbert symbolin local class field theory, see e.g.^[9]

A local field is sometimes called aone-dimensional local field.

A non-Archimedean local field can be viewed as the field of fractions of the completion of thelocal ringof a one-dimensional arithmetic scheme of rank 1 at its non-singular point.

For anon-negative integern,ann-dimensional local field is a complete discrete valuation field whose residue field is an (n− 1)-dimensional local field.^[5]Depending on the definition of local field, azero-dimensional local fieldis then either a finite field (with the definition used in this article), or a perfect field of positive characteristic.

From the geometric point of view,n-dimensional local fields with last finite residue field are naturally associated to a complete flag of subschemes of ann-dimensional arithmetic scheme.

• Hensel's lemma
• Ramification group
• Local class field theory
• Higher local field

• "Local field",Encyclopedia of Mathematics,EMS Press,2001 [1994]