Unconditional Density Bounds for Quadratic Norm-Form Energies via Lorentzian Spectral Weights

Abstract

For a real quadratic field Q(d), we study the norm-form energy N = Sζ2 - d · SL2, where Sζ and SL are Lorentzian-weighted zero sums with w() = 2/(14 + γ2). We prove three main results. (1) Spacelike spectral data: N < 0 unconditionally for all squarefree d > 1, as a consequence of a low-lying zero dominance theorem proved via explicit zero-counting. (2) Effective density bound: at each verified truncation level M, dens\N > 0\ ≤ 2\|fSL(M)\|∞ · (W1(ζ)/d + εM), established unconditionally via Jacobi--Anger resonance analysis. At fixed M the bound is nontrivial only for sufficiently large d; the O(1/d) rate requires M to grow with d, which in turn requires a uniform density bound that we establish under a computationally verified finite-rank condition on the resonance lattice. (3) Exact asymptotic: under the computationally verified hypothesis that the infinite resonance lattice ∞ has finite rank (verified to have rank 0 for M ≤ 20), the sharp asymptotic dens\N > 0\ = C(d)/d + o(1/d) holds. For d = 5, C(5) = 2\,fSL(0)·E[|Sζ|] = 0.1193; the constant depends on d through the zeros of L(s,d), and C(d) = O(1/ d) as d ∞. Appendix F tabulates between 1004 and 1044 zeros at 70 decimal places for L(s,2), L(s,3), L(s,5), L(s,6), L(s,7), L(s,10), L(s,11), and L(s,13), all rigorously certified by ARB interval arithmetic.