We present a unified treatment of four Millennium Prize Problems — the Riemann Hypothesis, the Yang–Mills mass gap, the Birch–Swinnerton-Dyer conjecture, and the Hodge conjecture — from a single structural principle: the identity Dₑ (X) = D_φ (X) of the additive (e-mode) and multiplicative (φ-mode) descriptions of any self-grounding mathematical object X. Each problem asserts this identity for a specific object: ℕ (RH), gauge theory on P³ = S³/2I* (YM), elliptic curves over ℚ (BSD), and smooth projective varieties (Hodge). Each proof is accompanied by a strengthened argument connecting the identity principle to established results: the Li criterion and a computed Mode Balance on P³ for the RH; the exact eigenvalue λ₁ = 168 on the Poincaré homology sphere for Yang–Mills; the Gross–Zagier formula for BSD; and the GAGA principle for Hodge. We prove the Mode Balance on P³ by direct computation: the spectral gap λ₁ = 168 suppresses eigenvalue contributions by exp (−168t), securing the balance overwhelmingly rather than marginally. We then argue that all four problems are grounds rather than theorems: each cannot be false (its denial dissolves the object it describes) and cannot be proved from more basic principles (every proof presupposes the coherence the problem asserts). The 165-year history of failed RH proofs is reinterpreted not as inadequate technique but as the empirical signature of a ground — a self-grounding circle in which 0/0 resolves into e and φ, generates Σ and Π, whose equality is the RH, whose proof requires Σ and Π, which presupposes the equality, which returns to 0/0. No free parameters are introduced. All results follow from the self-grounding equation Z = ∫ dS exp (−Tr ηS, S²) with η = diag (+1, +1, +1, −1, −1, −1).
Gereon Kraemer (Thu,) studied this question.