Reciprocity law

In mathematics, a reciprocity law is a generalization of the law of quadratic reciprocity to arbitrary monic irreducible polynomials $f(x)$ with integer coefficients. Recall that first reciprocity law, quadratic reciprocity, determines when an irreducible polynomial $f(x)=x^{2}+ax+b$ splits into linear terms when reduced mod $p$ . That is, it determines for which prime numbers the relation

$f(x)\equiv f_{p}(x)=(x-n_{p})(x-m_{p}){\text{ }}({\text{mod }}p)$

holds. For a general reciprocity law^[1]^{pg 3}, it is defined as the rule determining which primes $p$ the polynomial $f_{p}$ splits into linear factors, denoted ${\text{Spl}}\{f(x)\}$ .

There are several different ways to express reciprocity laws. The early reciprocity laws found in the 19th century were usually expressed in terms of a power residue symbol (p/q) generalizing the quadratic reciprocity symbol, that describes when a prime number is an nth power residue modulo another prime, and gave a relation between (p/q) and (q/p). Hilbert reformulated the reciprocity laws as saying that a product over p of Hilbert norm residue symbols (a,b/p), taking values in roots of unity, is equal to 1. Artin reformulated the reciprocity laws as a statement that the Artin symbol from ideals (or ideles) to elements of a Galois group is trivial on a certain subgroup. Several more recent generalizations express reciprocity laws using cohomology of groups or representations of adelic groups or algebraic K-groups, and their relationship with the original quadratic reciprocity law can be hard to see.

The name reciprocity law was coined by Legendre in his 1785 publication Recherches d'analyse indéterminée,^[2] because odd primes reciprocate or not in the sense of quadratic reciprocity stated below according to their residue classes ${\bmod {4}}$ . This reciprocating behavior does not generalize well, the equivalent splitting behavior does. The name reciprocity law is still used in the more general context of splittings.

^ Hiramatsu, Toyokazu; Saito, Seiken (2016-05-04). An Introduction to Non-Abelian Class Field Theory. Series on Number Theory and Its Applications. WORLD SCIENTIFIC. doi:10.1142/10096. ISBN 978-981-314-226-8.
^ Chandrasekharan, K. (1985). Elliptic Functions. Grundlehren der mathematischen Wissenschaften. Vol. 281. Berlin: Springer. p. 152f. doi:10.1007/978-3-642-52244-4. ISBN 3-540-15295-4.

[1] Hiramatsu, Toyokazu; Saito, Seiken (2016-05-04). An Introduction to Non-Abelian Class Field Theory. Series on Number Theory and Its Applications. WORLD SCIENTIFIC. doi:10.1142/10096. ISBN 978-981-314-226-8.

[EllFct-2] Chandrasekharan, K. (1985). Elliptic Functions. Grundlehren der mathematischen Wissenschaften. Vol. 281. Berlin: Springer. p. 152f. doi:10.1007/978-3-642-52244-4. ISBN 3-540-15295-4.

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