The Artin reciprocity law, which was established by Emil Artin in a series of papers (1924; 1927; 1930), is a general theorem in number theory that forms a central part of global class field theory.[1] The term "reciprocity law" refers to a long line of more concrete number theoretic statements which it generalized, from the quadratic reciprocity law and the reciprocity laws of Eisenstein and Kummer to Hilbert's product formula for the norm symbol. Artin's result provided a partial solution to Hilbert's ninth problem.
Let
L/K
CL
L
\theta:CK/{NL/K(CL)}\to\operatorname{Gal}(L/K)ab,
where
ab
\operatorname{Gal}(L/K)
L
K
\theta
\thetav:
| x | |
| K | |
| v |
| /N | |
| Lv/Kv |
| x | |
| (L | |
| v |
)\toGab,
v
K
\theta
\thetav
v
\thetav
A cohomological proof of the global reciprocity law can be achieved by first establishing that
(\operatorname{Gal}(Ksep/K),\varinjlimCL)
constitutes a class formation in the sense of Artin and Tate.[6] Then one proves that
\hat{H}0(\operatorname{Gal}(L/K),CL)\simeq\hat{H}-2(\operatorname{Gal}(L/K),\Z),
where
\hat{H}i
\theta
See also: Quadratic reciprocity and Eisenstein reciprocity. Artin's reciprocity law implies a description of the abelianization of the absolute Galois group of a global field K which is based on the Hasse local–global principle and the use of the Frobenius elements. Together with the Takagi existence theorem, it is used to describe the abelian extensions of K in terms of the arithmetic of K and to understand the behavior of the nonarchimedean places in them. Therefore, the Artin reciprocity law can be interpreted as one of the main theorems of global class field theory. It can be used to prove that Artin L-functions are meromorphic, and also to prove the Chebotarev density theorem.[7]
Two years after the publication of his general reciprocity law in 1927, Artin rediscovered the transfer homomorphism of I. Schur and used the reciprocity law to translate the principalization problem for ideal classes of algebraic number fields into the group theoretic task of determining the kernels of transfers of finite non-abelian groups.[8]
(See https://math.stackexchange.com/questions/4131855/frobenius-elements#:~:text=A%20Frobenius%20element%20for%20P,some%20%CF%84%E2%88%88KP for an explanation of some of the terms used here)
The definition of the Artin map for a finite abelian extension L/K of global fields (such as a finite abelian extension of
\Q
If
ak{p}
ak{P}
ak{p}
ak{p}
Dak{p}
l{O}L,ak{P
l{O}K,ak{p
Frobak{p}
| \left( | L/K |
| ak{p |
| \Delta | |
| I | |
| K |
| \begin{cases} \left( | L/K |
| ⋅ |
| \Delta | |
| \right):I | |
| K |
\longrightarrow
| ni | |
| \operatorname{Gal}(L/K)\\ \prod | |
| i |
\longmapsto
| ni | |
| \prod | |
| i}\right) |
\end{cases}
The Artin reciprocity law (or global reciprocity law) states that there is a modulus c of K such that the Artin map induces an isomorphism
| c/i(K | |
| I | |
| c,1 |
)NL/K
| c)\overset{\sim}{\longrightarrow}Gal(L/K) | |
| (I | |
| L |
where Kc,1 is the ray modulo c, NL/K is the norm map associated to L/K and
| c | |
| I | |
| L |
ak{f}(L/K).
If
d ≠ 1
K=\Q,
L=\Q(\sqrt{d})
\operatorname{Gal}(L/\Q)
\Q
| p\mapsto\left( | \Delta |
| p |
\right)
where
| \left( | \Delta |
| p |
\right)
L/\Q
| \left( | \Delta |
| n |
\right).
| \left( | \Delta |
| p |
\right)
Let m > 1 be either an odd integer or a multiple of 4, let
\zetam
L=\Q(\zetam)
\operatorname{Gal}(L/\Q)
(\Z/m\Z) x
\sigma(\zetam)=\zeta
| a\sigma | |
| m |
.
The conductor of
L/\Q
(\Z/m\Z) x .
Let p and
\ell
\ell*=
| ||||
| (-1) |
\ell
| \left( | \ell* | \right)=\left( |
| p |
| p | |
| \ell |
\right).
The relation between the quadratic and Artin reciprocity laws is given by studying the quadratic field
F=\Q(\sqrt{\ell*})
L=\Q(\zeta\ell)
G=\operatorname{Gal}(L/\Q),
\operatorname{Gal}(F/\Q)=G/H.
(\Z/\ell\Z) x .
| \left( | F/\Q | \right)=\left( |
| (n) |
| L/\Q | |
| (n) |
\right)\pmodH.
When n = p, this shows that
| \left( | \ell* |
| p |
\right)=1
An alternative version of the reciprocity law, leading to the Langlands program, connects Artin L-functions associated to abelian extensions of a number field with Hecke L-functions associated to characters of the idèle class group.[9]
A Hecke character (or Größencharakter) of a number field K is defined to be a quasicharacter of the idèle class group of K. Robert Langlands interpreted Hecke characters as automorphic forms on the reductive algebraic group GL(1) over the ring of adeles of K.[10]
Let
E/K
\sigma:G\to\Complex x
\chi
| Artin | |
| L | |
| E/K |
(\sigma,s)=
| Hecke | |
| L | |
| K |
(\chi,s)
where the left hand side is the Artin L-function associated to the extension with character σ and the right hand side is the Hecke L-function associated with χ, Section 7.D of.[10]
The formulation of the Artin reciprocity law as an equality of L-functions allows formulation of a generalisation to n-dimensional representations, though a direct correspondence is still lacking.