Extensions of complete valued fields - Local Fields

Theorem 6.1. Assuming that:

$(K, | ∙ |)$ is a complete discretely valued field
$L ∕ K$ a finite extension of degree $n$

Then

(i)

| ∙ |

extends uniquely to an absolute value

{| ∙ |}_{L}

L

defined by

{| y |}_{L} = {| N_{L ∕ L} (y) |}^{\frac{1}{n}} \forall y \in L .

(ii) $L$ is complete with respect to ${| ∙ |}_{L}$ .

Recall: If

L ∕ K

is finite,

N_{L ∕ K} : L \to K

is defined by

N_{L ∕ K} (y) = \underset{K}{\det} (m u l t (y)

where

m u l t (y) : L \to L

is the

K

-linear map induced by multiplication by

y

Definition 6.2 (Norm). Let $(K, | ∙ |)$ be a non-archimedean valued field, $V$ a vector space over $K$ . A normon $V$ is a function $∥ ∙ ∥ : V \to ℝ_{\geq 0}$ satisfying:

(i) $∥ x ∥ = 0 ⟺ x = 0$ .
(ii) $∥ λ x ∥ = ∥ λ ∥ ∥ x ∥$ for all $λ \in K$ , $x \in V$ .
(iii) $∥ x + y ∥ \leq \max (∥ x ∥, ∥ y ∥)$ for all $x, y \in V$ .

Example. If $V$ is finite dimensional and $e_{1}, \dots, e_{n}$ is a basis of $V$ . The supremum ${∥ ∙ ∥}_{\sup}$ on $V$ is defined by

{∥ x ∥}_{\sup} = \max_{i} | x_{i} |,

where $x = \sum_{i = 1}^{n} x_{i} e_{i}$ .

Exercise: ${∥ ∙ ∥}_{\sup}$ is a norm.

Fact: A norm defines a topology on

V

, and equivalent norms induce the same topology.

Proposition 6.4. Assuming that:

$(K, | ∙ |)$ is a complete non-archimedean valued field
$V$ a finite dimensional vector space over $K$

Then

V

is complete with respect to

{∥ ∙ ∥}_{\sup}

Proof. Let ${(v_{i})}_{i = 1}^{\infty}$ be a Cauchy sequence in $V$ , and let $e_{1}, \dots, e_{n}$ be a basis for $V$ .

Write $v_{i} = \sum_{j = 1}^{n} x_{j}^{i} e_{j}$ . Then ${(x_{j}^{i})}_{i = 1}^{\infty}$ is a Cauchy sequence in $K$ . Let $x_{j}^{i} \to x_{j} \in K$ , then $v_{i} \to v : = \sum_{j = 1}^{n} x_{j} e_{j}$ . □

Theorem 6.5. Assuming that:

$(K, | ∙ |)$ is a complete non-archimedean valued field
$V$ a finite dimensional vector space over $K$

Then any two norms on

K

are equivalent. In particular,

V

is complete with respect to any norm (using Proposition 6.4).

Proof. Since equivalence defines an equivalence relation on the set of norms, it suffices to show that any norm $∥ ∙ ∥$ is equivalent to ${∥ ∙ ∥}_{\sup}$ .

Let $e_{1}, \dots, e_{n}$ be a basis for $V$ , and set $D : = \max_{i} ∥ e_{i} ∥ > 0$ . Then for $x = \sum_{i = 1}^{n} x_{i} e_{i}$ , we have

∥ x ∥ \leq \max_{i} ∥ x_{i} e_{i} ∥ = \max_{i} | x_{i} | ∥ e_{i} ∥ \leq D \max_{i} | x_{i} | = D {∥ x ∥}_{\sup} .

To find $C$ such that $C {∥ ∙ ∥}_{\sup} \leq ∥ ∙ ∥$ , we induct on $n = \dim V$ .

For $n = 1$ : $∥ x ∥ = ∥ x_{1} e_{1} ∥ = | x_{1} | ∥ e_{1} ∥$ , so take $C = ∥ e_{1} ∥$ .

For $n > 1$ : set $V_{i} = span ⟨ e_{1}, \dots, e_{i - 1}, e_{i + 1}, \dots, e_{n} ⟩$ . By induction, $V_{i}$ is complete with respect to $∥ ∙ ∥$ , hence closed.

Then $e_{i} + V_{i}$ is closed for all $i$ , and hence

S : = ⋃_{i = 1}^{n} e_{i} + V_{i}

is a closed subset not containing $0$ . Thus there exists $c > 0$ such that $B (0, C) \cap S = \emptyset$ where $B (0, C) = {x \in V | ∥ x ∥ < C}$ .

Let $0 \neq x = \sum_{i = 1}^{n} x_{i} e_{i}$ and suppose $| x_{j} | = \max_{i} | x_{i} |$ . Then ${∥ x ∥}_{\sup} = | x_{j} |$ , and $\frac{1}{x_{j}} \in S$ . Thus $∥ \frac{x_{i}}{x_{j}} ∥ \geq C$ , and hence

∥ x ∥ \geq C | x_{j} | = C {∥ x ∥}_{\sup} .

$V$ is complete since it is complete with respect to ${∥ ∙ ∥}_{\sup}$ (see Proposition 6.4). □

Definition 6.6 (Integral closure). Let $R$ be a subring of $S$ . We say $s \in S$ is integral over $R$ if there exists a monic polynomial $f (X) \in R [X]$ such that $f (s) = 0$ .

The integral closure $R^{i n t (S)}$ of $R$ inside $S$ is defined to be

R^{i n t (S)} = {s \in S | s integral over R} .

We say $R$ is integrally closed in $S$ if $R^{i n t (S)} = R$ .

Proof. Example Sheet 2. □

Proof. Let $x \in K$ be integral over $O_{K}$ . Without loss of generality, $x \neq 0$ . Let $f (X) = X^{n} + a_{n - 1} X^{n - 1} + \dots + a_{0} \in O_{K} [X]$ such that $f (x) = 0$ . Then

x = - a_{n - 1} \frac{1}{x} - \dots - a_{0} \frac{1}{x_{n - 1}} .

If $| x | > 1$ , we have $| - a_{n - 1} \frac{1}{x} - \dots - a_{0} \frac{1}{x_{n - 1}} | < 1$ . Thus $| x | \leq 1 ⟹ x \in O_{K}$ . □

Proof. Let $0 \neq y \in L$ and let

f (X) = X^{d} + a_{d - 1} X^{d - 1} + \dots + a_{0} \in K [X]

be the minimal (monic) polynomial of $y$ .

Claim: $y$ integral over $O_{K}$ if and only if $f (X) \in ℚ_{K} [X]$ .

$\Rightarrow$ Clear.
$\Leftarrow$ Let $g (X) \in O_{K} [X]$ monic such that $g (y) = 0$ . Then $f | g$ (in $K [X]$ ), and hence every root of $f$ is a root of $g$ . So every root of $f$ in $\bar{K}$ is integral over $O_{K}$ , so $a_{i}$ are integral over $O_{K}$ for $i = 0, \dots, d - 1$ .

Hence $a_{i} \in O_{k}$ (by Lemma 6.8). By Corollary 4.5, $| a_{i} | \leq \max (| a_{0} |, 1)$ for $i = 0, \dots, d - 1$ . By property of $N_{L ∕ K}$ , we have $N_{L ∕ K} (y) = \pm a_{0}^{m}$ for $m \geq 1$ .

Hence

\begin{array}{l} y \in O_{L} & ⟺ | N_{L ∕ K} (y) | \leq 1 \\ ⟺ | a_{0} | \leq 1 \\ \overset{C o r o l l a r y 4.5}{⟺} | a_{i} | \leq 1 \forall i, i.e. a_{i} \in O_{K} \end{array}

Thus $msub int (L) = O_{L}$ and proves the Lemma. □

Proof of Theorem 6.1. We first show ${| ∙ |}_{L} = {| N_{L ∕ K} (∙) |}^{\frac{1}{n}}$ satisfies the three axioms in the definition of absolute value.

(i) $\begin{array}{l} {| y |}_{L} = 0 & ⟺ {| N_{L ∕ K} (y) |}^{\frac{1}{n}} = 0 \\ ⟺ N_{L ∕ K} (y) = 0 \\ ⟺ y = 0 \end{array}$
(ii) $\begin{array}{l} {| y_{1} y_{2} |}_{L} & = {| N_{L ∕ K} (y_{1}, y_{2}) |}^{\frac{1}{n}} \\ = {| N_{L ∕ K} (y_{1}) N_{L ∕ K} (y_{2}) |}^{\frac{1}{n}} \\ = {| N_{L ∕ K} (y_{1}) |}^{\frac{1}{n}} {| N_{L ∕ K} (y_{2}) |}^{\frac{1}{n}} \\ = {| y_{1} |}_{L} {| y_{2} |}_{L} \end{array}$
(iii) Set $O_{L} = {y \in L | {| y |}_{L} \leq 1}$ .
Claim: $O_{L}$ is the integral closure of $O_{K}$ inside $L$ .

Assuming this, we prove (iii). Let $x, y \in L$ , and without loss of generality assume ${| x |}_{L} \leq {| y |}_{L}$ . Then ${| \frac{x}{y} |}_{L}$ hence $\frac{x}{y} \in O_{L}$ . Since $1 \in O_{L}$ and $O_{L}$ is a ring, we have $1 + \frac{x}{y} \in O_{L}$ and hence ${| 1 + \frac{x}{y} |}_{L} \leq 1$ . Hence ${| x + y |}_{L} \leq {| y |}_{L} = \max ({| x |}_{L}, {| y |}_{L})$ thus (iii) is satisfied.

So we have proved that $| ∙ |_{L}$ is an absolute value on $L$ .

Since $N_{L ∕ K} (x) = x^{n}$ for $x \in K$ , $| x |_{L}$ extends $| ∙ |$ on $K$ .

If ${| ∙ |}_{L}^{'}$ is another absolute value on $L$ extending $| ∙ |$ , then $| ∙ |_{L}, | ∙ |_{L}^{'}$ are norms on $L$ .

Theorem 6.5 tells us that $| ∙ |_{L}^{'}, | ∙ |_{L}$ induce the same topology on $L$ . Hence $| ∙ |_{L}^{'} = | ∙ |_{L}^{c}$ for some $c > 0$ (by Proposition 1.4) since $| ∙ |_{L}^{'}$ extends $| ∙ |$ , we have $c = 1$ .

Now we show that $L$ is complete with respect to $| ∙ |_{L}$ : this is immediate by Theorem 6.5. □

Proof.

(i) $v$ a valuation on $K$ , $v_{L}$ valuation on $L$ such that $v_{L}$ extends $v$ . Let $n = [L : K]$ , and let $y \in L^{\times}$ . Then $| y |_{L} = | N_{L ∕ K} (y) |^{\frac{1}{n}}$ hence $v_{L} (y) = \frac{1}{n} v (N_{L ∕ K} (y))$ , hence $v_{L} (L^{\times}) \leq \frac{1}{n} v (K^{\times})$ , so $v_{L}$ is discrete.
(ii) Lemma 6.9.

□

Proof. Let $x \in \bar{K}$ , then $x \in L$ for some $L ∕ K$ finite. Define $| x |_{\bar{K}} = | x |_{L}$ . Well-defined, i.e. independent of $L$ by the uniqueness in Theorem 6.1.

The axioms for $| ∙ |_{\bar{K}}$ to be an absolute value can be checked over finite extensions.

Uniqueness: clear. □

Remark. $| ∙ |_{\bar{K}}$ on $\bar{K}$ is never discrete. For example $K = ℚ_{p}$ , $\sqrt[n]{p} \in \bar{ℚ_{p}}$ for all $n \in ℤ_{> 0}$ . Then

v_{p} (\sqrt[n]{p}) = \frac{1}{n} v (p) = \frac{1}{n} .

$\bar{ℚ_{p}}$ is not complete with respect to $| ∙ |_{ℚ_{p}}$ .

Example Sheet 2: $ℂ_{p} : =$ completion of $\bar{ℚ_{p}}$ with respect to $| ∙ |_{\bar{ℚ_{p}}}$ , then $ℂ_{p}$ is algebraically closed.

Proposition 6.12. Assuming that:

$L ∕ K$ finite extension of complete discretely valued fields.
(i): $O_{K}$ is compact.
(ii): The extension of residue fields $k_{L} ∕ k$ is finite and separable.

Then there exists

α \in O_{L}

such that

O_{L} = O_{K} [α]

Proof. We’ll choose $α \in O_{L}$ such that:

there exists $β \in O_{L} [α]$ a uniformiser for $O_{L}$
$O_{K} [α] \to k_{L}$ surjective

$k_{L} ∕ k$ separable tells us that there exists $\bar{α} \in k_{L}$ such that $k_{L} = k (\bar{α})$ .

Let $α \in O_{L}$ a lift of $\bar{α}$ , and $g (X) \in O_{K} [X]$ a monic lift of the minimal polynomial of $\bar{α}$ .

Fix $π_{L} \in O_{L}$ a uniformiser. Then $\bar{g} (X) \in k [X]$ irreducible and separable, hence $g (α) \equiv 0 mod π_{L}$ and $g^{'} (α) ⁄ \equiv 0 mod π_{L}$ .

If $g (α) \equiv 0 mod π_{L}^{2}$ , then

g (α + π_{L}) \equiv g (α) + π_{L} g^{'} (α) mod π_{L}^{2} .

Thus

v_{L} (g (α + π_{L})) = v_{L} (π_{L} g^{'} (α)) = v_{L} (π_{L}) = 1 .

( $v_{L}$ normalised valuation on $L$ ).

Thus either $v_{L} (g (α)) = 1$ or $v_{L} (g (α + π_{L})) = 1$ . Upon possibly replacing $α$ by $α + π_{L}$ , we may assume $v_{L} (g (α)) = 1$ .

Set $β = g (α) \in O_{K} [α]$ a uniformiser. Then $O_{K} [α] \subseteq L$ is the image of a continuous map:

\begin{array}{l} O_{K}^{n} & \to L \\ (x_{0}, \dots, x_{n - 1}) & \mapsto \sum_{i = 0}^{n} x_{i} a^{i} \end{array}

where $n = [K (α) : K]$ . Since $O_{K}$ is compact, $O_{K} [α] \subseteq L$ is compact, hence closed. Since $k_{L} = k (\bar{α})$ , $O_{K} [α]$ contians a set of coset representatives for $k_{L} = O_{L} ∕ β O_{L}$ .

Let $y \in O_{L}$ . Then Proposition 3.4 gives us

y = \sum_{i = 0}^{\infty} λ_{i} β^{i}, λ_{i} \in O_{K} [α]

Then $y_{m} = \sum_{i = 0}^{m} λ_{i} β^{i} \in O_{K} [α]$ . Hence $y \in O_{K} [α]$ , since $O_{k} [α]$ is closed. □

6 Extensions of complete valued fields