Minkowski shapes of pure number fields

Abstract

We study the Minkowski shape of pure number fields \[ Ka= Q(θ), θn=a. \] For admissible parameters satisfying an explicit local hypothesis at the primes dividing n, we prove a discrete--archimedean factorization \[ sh(Ka)=[C(a) Tdiag(s1(a),…,sn-1(a))C(a)], \] where the sm(a) arise from normalized monomials and C(a)∈GLn-1( Q) comes from a normalized integral basis. This yields a uniform odd/even rigidity dichotomy: for every odd n≥ 3, the Minkowski shape is a complete invariant among admissible pure degree-n fields, whereas for n=2r it determines the core field Q(|a|1/r); on the squarefree admissible subfamily it is complete up to sign, although infinitely many non-isomorphic pairs Ka and K-a have the same shape. We also derive explicit formulas for |disc(Ka)|, including exponent-vector and divisor-lattice factorizations. Finally, we show that the pure-field shape locus is supported on rational diagonal leaves in shape space: unconditionally it lies in a countable union of closed leaves, while under the same local hypothesis only finitely many leaves occur in each fixed degree. On a fixed normalized stratum, the shape depends only on ratio variables, whereas discriminant growth is governed by independent product variables.