Reflection theorem

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For reflection principles in set theory, see reflection principle.

In algebraic number theory, a reflection theorem or Spiegelungssatz (German for reflection theorem – see Spiegel and Satz) is one of a collection of theorems linking the sizes of different ideal class groups (or ray class groups), or the sizes of different isotypic components of a class group. The original example is due to Ernst Eduard Kummer, who showed that the class number of the cyclotomic field ${\displaystyle \mathbb {Q} \left(\zeta _{p}\right)}$, with p a prime number, will be divisible by p if the class number of the maximal real subfield ${\displaystyle \mathbb {Q} \left(\zeta _{p}\right)^{+}}$ is. Another example is due to Scholz^[1]. A simplified version of his theorem states that if 3 divides the class number of a real quadratic field ${\displaystyle \mathbb {Q} \left({\sqrt {d}}\right)}$, then 3 also divides the class number of the imaginary quadratic field ${\displaystyle \mathbb {Q} \left({\sqrt {-3d}}\right)}$.

Both of the above results are generalized by Leopoldt's "Spiegelungssatz", which relates the p-ranks of different isotypic components of the class group of a number field K, considered as a module over the Galois group of a Galois extension K/k.

Extensions of this Spiegelungssatz were given by Oriat and Oriat-Satge, where class groups were no longer associated with characters of the Galois group of K/k, but rather by ideals in a group ring over the Galois group of K/k. Leopoldt's Spiegelungssatz was generalized in a different direction by Kuroda, who extended it to a statement about ray class groups. This was further developed into the very general "T-S reflection theorem" of Georges Gras^[2]. Kenkichi Iwasawa also provided an Iwasawa-theoretic reflection theorem.