Saturation and No-Go Theorems for Scalar Poisson Certificates of Gaussian Mass Maximality

Abstract

Regev and Stephens-Davidowitz conjectured that the Gaussian mass ΘΛ(t) = Σx ∈ Λ e-t x2 of any integral lattice Λ⊂ Rn is bounded above by ΘZn(t). For n 4, we prove a saturation theorem for the natural scalar Poisson-summation certificates of this conjecture: any such certificate that is sharp at Zn must interpolate the Gaussian, and have vanishing Fourier transform, at every nonzero point of integer squared norm. Applied to the lattice E8 Zn-8, this rigidity is incompatible with the strict theta-series gap ΘZ8(t) - ΘE8(t) = θ2(it/π)4\,θ4(it/π)4 > 0. Consequently, in dimensions n 8, no scalar Poisson certificate can attain the sharp Zn Gaussian mass bound. The same argument rules out the corresponding scalar certificate strategy for the stable-lattice formulation of the conjecture, and extends to orbit-constant graded families Λ hΛ; near-sharp sequences are similarly excluded under a uniform summability hypothesis.