Conductor (class field theory)

In algebraic number theory, the conductor of a finite abelian extension of local or global fields provides a quantitative measure of the ramification in the extension. The definition of the conductor is related to the Artin map.

Let L/K be a finite abelian extension of non-archimedean local fields. The conductor of L/K, denoted ${\displaystyle 𝔣(L/K)}$, is the smallest non-negative integer n such that the higher unit group

${\displaystyle U^{(n)}=1+{𝔪}_K^n=\{u\in {𝒪}^{\times }:u\equiv 1(\mathrm{mod}{𝔪}_K^n)\}}$

is contained in N_L/K(L^×), where N_L/K is field norm map and ${\displaystyle {𝔪}_K}$ is the maximal ideal of K.^[1] Equivalently, n is the smallest integer such that the local Artin map is trivial on ${\displaystyle U_K^{(n)}}$. Sometimes, the conductor is defined as ${\displaystyle {𝔪}_K^n}$ where n is as above.^[2]

The conductor of an extension measures the ramification. Qualitatively, the extension is unramified if, and only if, the conductor is zero,^[3] and it is tamely ramified if, and only if, the conductor is 1.^[4] More precisely, the conductor computes the non-triviality of higher ramification groups: if s is the largest integer for which the "lower numbering" higher ramification group G_s is non-trivial, then ${\displaystyle 𝔣(L/K)={\eta }_{L/K}(s)+1}$, where η_L/K is the function that translates from "lower numbering" to "upper numbering" of higher ramification groups.^[5]

The conductor of L/K is also related to the Artin conductors of characters of the Galois group Gal(L/K). Specifically,^[6]

${\displaystyle {𝔪}_K^{𝔣(L/K)}=\underset{\chi }{\mathrm{lcm}}{𝔪}_K^{{𝔣}_{\chi }}}$

where χ varies over all multiplicative complex characters of Gal(L/K), ${\displaystyle {𝔣}_{\chi }}$ is the Artin conductor of χ, and lcm is the least common multiple.

The conductor can be defined in the same way for L/K a not necessarily abelian finite Galois extension of local fields.^[7] However, it only depends on L^ab/K, the maximal abelian extension of K in L, because of the "norm limitation theorem", which states that, in this situation,^[8][9]

${\displaystyle N_{L/K}\left(L^{\times }\right)=N_{L^{\text{ab}}/K}\left({\left(L^{\text{ab}}\right)}^{\times }\right).}$

Additionally, the conductor can be defined when L and K are allowed to be slightly more general than local, namely if they are complete valued fields with quasi-finite residue field.^[10]

Mostly for the sake of global conductors, the conductor of the trivial extension R/R is defined to be 0, and the conductor of the extension C/R is defined to be 1.^[11]

The conductor of an abelian extension L/K of number fields can be defined, similarly to the local case, using the Artin map. Specifically, let θ : I^m → Gal(L/K) be the global Artin map where the modulus m is a defining modulus for L/K; we say that Artin reciprocity holds for m if θ factors through the ray class group modulo m. We define the conductor of L/K, denoted ${\displaystyle 𝔣(L/K)}$, to be the highest common factor of all moduli for which reciprocity holds; in fact reciprocity holds for ${\displaystyle 𝔣(L/K)}$, so it is the smallest such modulus.^[12][13][14]

• Taking as base the field of rational numbers, the Kronecker–Weber theorem states that an algebraic number field K is abelian over Q if and only if it is a subfield of a cyclotomic field ${\displaystyle 𝐐\left({\zeta }_n\right)}$, where ${\displaystyle {\zeta }_n}$ denotes a primitive nth root of unity.^[15] If n is the smallest integer for which this holds, the conductor of K is then n if K is fixed by complex conjugation and ${\displaystyle n\mathrm{\infty }}$ otherwise.
• Let L/K be ${\displaystyle 𝐐\left(\sqrt{d}\right)/𝐐}$ where d is a squarefree integer. Then,^[16]

  ${\displaystyle 𝔣(𝐐\left(\sqrt{d}\right)/𝐐)=\{\begin{array}{cc}\left|{\mathrm{\Delta }}_{𝐐\left(\sqrt{d}\right)}\right|& \text{for }d>0\\ \mathrm{\infty }\left|{\mathrm{\Delta }}_{𝐐\left(\sqrt{d}\right)}\right|& \text{for }d<0\end{array}}$

where ${\displaystyle {\mathrm{\Delta }}_{𝐐(\sqrt{d})}}$ is the discriminant of ${\displaystyle 𝐐\left(\sqrt{d}\right)/𝐐}$.

The global conductor is the product of local conductors:^[17]

${\displaystyle 𝔣(L/K)=\prod _{𝔭}{𝔭}^{𝔣(L_{𝔭}/K_{𝔭})}.}$

As a consequence, a finite prime is ramified in L/K if, and only if, it divides ${\displaystyle 𝔣(L/K)}$.^[18] An infinite prime v occurs in the conductor if, and only if, v is real and becomes complex in L.

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