Odd degree number fields with odd class number

Abstract

For every odd integer n ≥ 3, we prove that there exist infinitely many number fields of degree n and associated Galois group Sn whose class number is odd. To do so, we study the class groups of families of number fields of degree n whose rings of integers arise as the coordinate rings of the subschemes of P1 cut out by integral binary n-ic forms. By obtaining upper bounds on the mean number of 2-torsion elements in the class groups of fields in these families, we prove that a positive proportion (tending to 1 as n tends to ∞) of such fields have trivial 2-torsion subgroup in their class groups and narrow class groups. Conditional on a tail estimate, we also prove the corresponding lower bounds and obtain the exact values of these averages, which are consistent with the heuristics of Cohen-Lenstra-Martinet-Malle and Dummit-Voight. Additionally, for any order Of of degree n arising from an integral binary n-ic form f, we compare the sizes of Cl2(Of), the 2-torsion subgroup of ideal classes in Of, and I2(Of), the 2-torsion subgroup of ideals in Of. For the family of orders arising from integral binary n-ic forms and contained in fields with fixed signature (r1,r2), we prove that the mean value of the difference |Cl2(Of)| - 21-r1-r2|I2(Of)| is equal to 1, generalizing a result of Bhargava and the third-named author for cubic fields. Conditional on certain tail estimates, we also prove that the mean value of |Cl2(Of)| - 21-r1-r2|I2(Of)| remains 1 for certain families obtained by imposing local splitting and maximality conditions.