Ideal norm

In commutative algebra, the norm of an ideal is a generalization of a norm of an element in the field extension. It is particularly important in number theory since it measures the size of an ideal of a complicated number ring in terms of an ideal in a less complicated ring. When the less complicated number ring is taken to be the ring of integers, Z, then the norm of a nonzero ideal I of a number ring R is simply the size of the finite quotient ring R/I.

Let A be a Dedekind domain with field of fractions K and integral closure of B in a finite separable extension L of K. (this implies that B is also a Dedekind domain.) Let ${\displaystyle {ℐ}_A}$ and ${\displaystyle {ℐ}_B}$ be the ideal groups of A and B, respectively (i.e., the sets of nonzero fractional ideals.) Following the technique developed by Jean-Pierre Serre, the norm map

${\displaystyle N_{B/A}:{ℐ}_B\to {ℐ}_A}$

is the unique group homomorphism that satisfies

${\displaystyle N_{B/A}(𝔮)={𝔭}^{[B/𝔮:A/𝔭]}}$

for all nonzero prime ideals ${\displaystyle 𝔮}$ of B, where ${\displaystyle 𝔭=𝔮\cap A}$ is the prime ideal of A lying below ${\displaystyle 𝔮}$.

Alternatively, for any ${\displaystyle 𝔟\in {ℐ}_B}$ one can equivalently define ${\displaystyle N_{B/A}(𝔟)}$ to be the fractional ideal of A generated by the set ${\displaystyle \{N_{L/K}(x)|x\in 𝔟\}}$ of field norms of elements of B.^[1]

For ${\displaystyle 𝔞\in {ℐ}_A}$, one has ${\displaystyle N_{B/A}(𝔞B)={𝔞}^n}$, where ${\displaystyle n=[L:K]}$.

The ideal norm of a principal ideal is thus compatible with the field norm of an element:

${\displaystyle N_{B/A}(xB)=N_{L/K}(x)A.}$^[2]

Let ${\displaystyle L/K}$ be a Galois extension of number fields with rings of integers ${\displaystyle {𝒪}_K\subset {𝒪}_L}$.

Then the preceding applies with ${\displaystyle A={𝒪}_K,B={𝒪}_L}$, and for any ${\displaystyle 𝔟\in {ℐ}_{{𝒪}_L}}$ we have

${\displaystyle N_{{𝒪}_L/{𝒪}_K}(𝔟)=K\cap \prod _{\sigma \in \mathrm{Gal}(L/K)}\sigma (𝔟),}$

which is an element of ${\displaystyle {ℐ}_{{𝒪}_K}}$.

The notation ${\displaystyle N_{{𝒪}_L/{𝒪}_K}}$ is sometimes shortened to ${\displaystyle N_{L/K}}$, an abuse of notation that is compatible with also writing ${\displaystyle N_{L/K}}$ for the field norm, as noted above.

In the case ${\displaystyle K=\mathbb{Q}}$, it is reasonable to use positive rational numbers as the range for ${\displaystyle N_{{𝒪}_L/\mathbb{Z}}}$ since ${\displaystyle \mathbb{Z}}$ has trivial ideal class group and unit group ${\displaystyle \{\pm 1\}}$, thus each nonzero fractional ideal of ${\displaystyle \mathbb{Z}}$ is generated by a uniquely determined positive rational number. Under this convention the relative norm from ${\displaystyle L}$ down to ${\displaystyle K=\mathbb{Q}}$ coincides with the absolute norm defined below.

Let ${\displaystyle L}$ be a number field with ring of integers ${\displaystyle {𝒪}_L}$, and ${\displaystyle 𝔞}$ a nonzero (integral) ideal of ${\displaystyle {𝒪}_L}$.

The absolute norm of ${\displaystyle 𝔞}$ is

${\displaystyle N(𝔞):=[{𝒪}_L:𝔞]=|{𝒪}_L/𝔞|.}$

By convention, the norm of the zero ideal is taken to be zero.

If ${\displaystyle 𝔞=(a)}$ is a principal ideal, then

${\displaystyle N(𝔞)=|N_{L/\mathbb{Q}}(a)|}$.^[3]

The norm is completely multiplicative: if ${\displaystyle 𝔞}$ and ${\displaystyle 𝔟}$ are ideals of ${\displaystyle {𝒪}_L}$, then

${\displaystyle N(𝔞\cdot 𝔟)=N(𝔞)N(𝔟)}$.^[3]

Thus the absolute norm extends uniquely to a group homomorphism

${\displaystyle N:{ℐ}_{{𝒪}_L}\to {\mathbb{Q}}_{>0}^{\times },}$

defined for all nonzero fractional ideals of ${\displaystyle {𝒪}_L}$.

The norm of an ideal ${\displaystyle 𝔞}$ can be used to give an upper bound on the field norm of the smallest nonzero element it contains:

there always exists a nonzero ${\displaystyle a\in 𝔞}$ for which

${\displaystyle |N_{L/\mathbb{Q}}(a)|\le {\left(\frac{2}{\pi }\right)}^s\sqrt{\left|{\mathrm{\Delta }}_L\right|}N(𝔞),}$

where

• ${\displaystyle {\mathrm{\Delta }}_L}$ is the discriminant of ${\displaystyle L}$ and
• ${\displaystyle s}$ is the number of pairs of (non-real) complex embeddings of Template:Math into ${\displaystyle ℂ}$ (the number of complex places of Template:Math).^[4]

• Field norm
• Dedekind zeta function

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