Equality in a Reverse Minkowski Shell Bound for Integral Lattices via Spherical Designs
Abstract: For a full-rank integral lattice $\mathcal{L}\subset\mathbb{R}n$, Regev and Stephens-Davidowitz proved that [N_{=k}(\mathcal{L}):=|{y\in\mathcal{L}:\lVert y\rVert2=k}|\le 2\binom{n+2k-2}{2k-1}.] We classify the equality cases. For $n\ge2$, equality holds if and only if either $k=1$ and $\mathcal{L}\cong\mathbb{Z}n$, or $n=8$, $k=2$, and $\mathcal{L}\cong E_8$. For $n=1$, equality holds exactly when $\mathcal{L}$ represents $k$. The proof shows that equality is rigid. Saturation of the shell bound forces the normalized norm-$k$ shell to be an antipodal tight spherical $(4k-1)$-design. The associated Delsarte--Goethals--Seidel annihilator polynomial gives an arithmetic root condition, which isolates $E_8$ at $k=2$, rules out $k=3$, and combines with the Bannai--Damerell/Bannai theorem and an elementary circle argument to exclude all remaining cases in dimension at least $2$.
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