Herbrand–Ribet theorem
In mathematics, the Herbrand–Ribet theorem is a result on the class group of certain number fields. It is a strengthening of Ernst Kummer's theorem to the effect that the prime p divides the class number of the cyclotomic field of p-th roots of unity if and only if p divides the numerator of the n-th Bernoulli number Bn
for some n, 0 < n < p − 1. The Herbrand–Ribet theorem specifies what, in particular, it means when p divides such an Bn.
Statement
The Galois group Δ of the cyclotomic field of pth roots of unity for an odd prime p, Q with ζp = 1, consists of the p − 1 group elements σa, where. As a consequence of Fermat's little theorem, in the ring of p-adic integers we have p − 1 roots of unity, each of which is congruent mod p to some number in the range 1 to p − 1; we can therefore define a Dirichlet character ω with values in by requiring that for n relatively prime to p, ω be congruent to n modulo p. The p part of the class group is a -module, hence a module over the group ring. We now define idempotent elements of the group ring for each n from 1 to p − 1, asIt is easy to see that and where is the Kronecker delta. This allows us to break up the p part of the ideal class group G of Q by means of the idempotents; if G is the p-primary part of the ideal class group, then, letting Gn = εn, we have.
The Herbrand–Ribet theorem states that for odd n, Gn is nontrivial if and only if p divides the Bernoulli number Bp−n.
The theorem makes no assertion about even values of n, but there is no known p for which Gn is nontrivial for any even n: triviality for all p would be a consequence of Vandiver's conjecture.