This paper develops a mathematically controlled upgrade of a prime-circle spectral-flow model by replacing the auxiliary real circle attached to a prime with a local p-adic spectral package extracted from the Fargues-Fontaine curve. The starting point is the finite prime-orbit Dirac family in which the Connes-Consani scaling-site orbit of length is modeled by a circle . We replace that circle by a Fargues-Fontaine datum consisting of a local field , an algebraically closed perfectoid untilt , the curve , a Frobenius-normalized slope circle of length , and a finite modification-defect space attached to a torsion quotient at the untilt point. The resulting object is not asserted to be a literal Riemannian Dirac operator on . Rather, it is a rigorous spectral-flow functor from finite Fargues-Fontaine modification data to self-adjoint Fredholm families. We prove a one-dimensional coefficient theorem, a two-dimensional cancellation theorem, and a three-dimensional product-index theorem. In particular, for a finite modification and an even-dimensional compact spin transverse manifold , the spectral flow is the product of the Fargues-Fontaine defect length with the transverse Dirac index. We also formulate a finite-packet local-to-global construction over finitely many primes and explain why naive infinite prime sums remain non-Fredholm unless an explicit uniform weighting or compactness hypothesis is imposed. The paper separates proved operator-theoretic statements from conjectural links with zeta spectral triples and global arithmetic Langlands.
Ying Ye (Sat,) studied this question.