Dedekind–Kummer theorem

In algebraic number theory, the Dedekind–Kummer theorem describes how a prime ideal in a Dedekind domain factors over the domain's integral closure.^[1]

Statement for number fields[edit]

Let $K$ be a number field such that $K=\mathbb {Q} (\alpha )$ for $\alpha \in {\mathcal {O}}_{K}$ and let $f$ be the minimal polynomial for $\alpha$ over $\mathbb {Z} [x]$ . For any prime $p$ not dividing $[{\mathcal {O}}_{K}:\mathbb {Z} [\alpha ]]$ , write

f(x)\equiv \pi _{1}(x)^{e_{1}}\cdots \pi _{g}(x)^{e_{g}}\mod p

where

\pi _{i}(x)

are monic irreducible polynomials in

\mathbb {F} _{p}[x]

. Then

(p)=p{\mathcal {O}}_{K}

factors into prime ideals as

(p)={\mathfrak {p}}_{1}^{e_{1}}\cdots {\mathfrak {p}}_{g}^{e_{g}}

such that

N({\mathfrak {p}}_{i})=p^{\deg \pi _{i}}

.^[2]

Statement for Dedekind Domains[edit]

The Dedekind-Kummer theorem holds more generally than in the situation of number fields: Let ${\mathcal {o}}$ be a Dedekind domain contained in its quotient field $K$ , $L/K$ a finite, separable field extension with $L=K[\theta ]$ for a suitable generator $\theta$ and ${\mathcal {O}}$ the integral closure of ${\mathcal {o}}$ . The above situation is just a special case as one can choose ${\mathcal {o}}=\mathbb {Z} ,K=\mathbb {Q} ,{\mathcal {O}}={\mathcal {O}}_{L}$ ).

If $(0)\neq {\mathfrak {p}}\subseteq {\mathcal {o}}$ is a prime ideal coprime to the conductor ${\mathfrak {F}}=\{a\in {\mathcal {O}}\mid a{\mathcal {O}}\subseteq {\mathcal {o}}[\theta ]\}$ (i.e. their sum is ${\mathcal {O}}$ ). Consider the minimal polynomial $f\in {\mathcal {o}}[x]$ of $\theta$ . The polynomial ${\overline {f}}\in ({\mathcal {o}}/{\mathfrak {p}})[x]$ has the decomposition