Locally compact field

In algebra, a locally compact field is a topological field whose topology forms a locally compact Hausdorff space.^[1] These kinds of fields were originally introduced in p-adic analysis since the fields ${\displaystyle {\mathbb{\mathbb{Q}}}_p}$ are locally compact topological spaces constructed from the norm ${\displaystyle |\cdot {|}_p}$ on ${\displaystyle \mathbb{\mathbb{Q}}}$. The topology (and metric space structure) is essential because it allows one to construct analogues of algebraic number fields in the p-adic context.

Structure

Finite dimensional vector spaces

One of the useful structure theorems for vector spaces over locally compact fields is that the finite dimensional vector spaces have only an equivalence class of norm: the sup norm^{[2] pg. 58-59}.

Finite field extensions

Given a finite field extension

over a locally compact field

, there is at most one unique field norm

on

extending the field norm

; that is,

${\displaystyle |f{|}_K=|f{|}_F}$

for all

which is in the image of

. Note this follows from the previous theorem and the following trick: if

are two equivalent norms, and

${\displaystyle ||x|{|}_1<||x|{|}_2}$

then for a fixed constant

there exists an

such that

${\displaystyle {\left(\frac{||x|{|}_1}{||x|{|}_2}\right)}^N<\frac{1}{c_1}}$

for all

since the sequence generated from the powers of

converge to

.

Finite Galois extensions

If the index of the extension is of degree

and

is a Galois extension, (so all solutions to the minimal polynomial of any

is also contained in

) then the unique field norm

can be constructed using the field norm^{[2] pg. 61}. This is defined as

${\displaystyle |a{|}_K=|N_{K/F}(a){|}^{1/n}}$

Note the n-th root is required in order to have a well-defined field norm extending the one over

since given any

in the image of

its norm is

${\displaystyle N_{K/F}(f)=\det m_f=f^n}$

since it acts as scalar multiplication on the

-vector space

.

Examples

Finite fields

All finite fields are locally compact since they can be equipped with the discrete topology. In particular, any field with the discrete topology is locally compact since every point is the neighborhood of itself, and also the closure of the neighborhood, hence is compact.

Local fields

The main examples of locally compact fields are the p-adic rationals ${\displaystyle {\mathbb{\mathbb{Q}}}_p}$ and finite extensions ${\displaystyle K/{\mathbb{\mathbb{Q}}}_p}$. Each of these are examples of local fields. Note the algebraic closure ${\displaystyle {\overline{\mathbb{\mathbb{Q}}}}_p}$ and its completion ${\displaystyle {\mathbb{ℂ}}_p}$ are not locally compact fields^{[2] pg. 72} with their standard topology.

Field extensions of Q_p

Field extensions

can be found by using Hensel's lemma. For example,

has no solutions in

since

${\displaystyle \frac{d}{dx}(x^2-5)=2x}$

only equals zero mod

if

, but

has no solutions mod

. Hence

is a quadratic field extension.

See also

• Compact group – Topological group with compact topology
• Complete field
• Local field – Locally compact topological field
• Locally compact group
• Locally compact quantum group
• Ordered topological vector space
• Ramification of local fields
• Topological abelian group
• Topological field – Algebraic structure with addition, multiplication, and divisionPages displaying short descriptions of redirect targets
• Topological group – Group that is a topological space with continuous group action
• Topological module
• Topological ring
• Topological semigroup
• Topological vector space – Vector space with a notion of nearness

References

External links

• Inequality trick https://math.stackexchange.com/a/2252625