On the Galois structure of units in totally real p-rational number fields
Abstract
The theory of factor-equivalence of integral lattices establishes a far-reaching relationship between the Galois module structure of the unit group of the ring of integers of a number field and its arithmetic. For a number field K that is Galois over Q or an imaginary quadratic field, we prove a necessary and sufficient condition on the quotients of class numbers of subfields of K, for the quotient EK of the unit group of the ring of integers of K modulo the subgroup of roots of unity to be factor equivalent to the standard cyclic Galois module. Using strong arithmetic properties of totally real p-rational number fields, we prove that the non-abelian p-rational p-extensions of Q do not admit Minkowski units, thereby extending a result of Burns to non-abelian number fields. We also study the relative Galois module structure of EL for varying Galois extensions L/F of totally real p-rational number fields whose Galois groups are isomorphic to a fixed finite group G. In that case, we prove that there exists a finite set of Zp[G]-lattices such that for every L, Zp Z EL is factor equivalent to Zp[G]n X as Zp[G]-lattices for some X ∈ and an integer n ≥ 0.
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