A380104 Minimal conductors c of complex dihedral normal closures K = L(zeta_3) of pure cubic number fields L = Q(d^1/3), d > 1 cubefree, with elementary bicyclic 3-class group Cl_3(K)=(3,3) and second 3-class group M=Gal(F_3^2(K)/K) of assigned coclass cc(M)=0,1,2,3,...
30, 90, 418, 1626
Offset: 1
Examples
We have M abelian for c=30=2*3*5 (a singlet), cc(M)=1 for c=90=2*3^2*5 (two fields in a quartet), cc(M)=2 for c=418=2*11*19, cc(M)=3 for c=1626=2*3*271.
Links
- D. C. Mayer, The distribution of second p-class groups on coclass graphs, arXiv:1403.3833 [math.NT], 2014; J. Théor. Nombres Bordeaux 25 (2013), 401-456.
- Daniel Constantin Mayer, Magma program "PureCoClass.m" with endless loop
Crossrefs
Analog of A379524 for real quadratic fields.
Programs
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Magma
// See Links section.
Formula
According to Theorem 3.12 on page 435 of "The distribution of second p-class groups on coclass graphs", the coclass of the group M is given by cc(M)+1=log_3(h_3(E_2)), where h_3(E_2) is the second largest 3-class number among the four unramified cyclic cubic extensions E_1,..,E_4 of the complex dihedral field K, and log_3 denotes the logarithm with respect to the basis 3. An exception is the abelian 3-group A=(3,3) with correct cc(A)=1, where the FORMULA yields cc(A)=0.
Comments