On the Absolute Geometry of SpecZ

Abstract

A guiding principle in P. Scholze's p-adic geometry asserts that the points of SpecZ over an algebraically closed perfectoid field of characteristic p are classified, up to equivalence, by its untilts. In this paper, we give a concrete geometric realization and a generalization of this paradigm. We construct the absolute F1-arithmetic curve (SpecZ)F1 by pulling back the F1-structure sheaf of the arithmetic site to SpecZ. We demonstrate that (SpecZ)F1 provides a common geometric origin for fundamental structures in p-adic Hodge theory, complex analytic geometry, and the adelic scaling site. The moduli space of points of (SpecZ)F1 over an arbitrary perfectoid field, modulo intrinsic symmetries, canonically parameterizes the space of all perfectoid fields with the same tilt, providing a universal, characteristic-independent geometric realization of Scholze's heuristic. Evaluating the points of (SpecZ)F1 over the field C of complex numbers reveals, at each prime p, that the non-trivial points canonically form two principal homogeneous spaces (torsors) over the Weil groups Wp=Qp× and W∞=C×. Quotienting the archimedean orbit by the discrete Frobenius symmetries yields the complex Tate curve with modulus q=p-1. We show that this elliptic curve canonically decomposes as the product of its real locus, which exactly recovers the adelic periodic orbit Cp=R+×/pZ, and a p-independent phase space that emerges naturally as a real analogue of the Fargues--Fontaine curve.