Inverse Falconer Distance Theorems over the Integer Residue Rings Zn

Abstract

We establish an ideal-theoretic rigidity principle for quadratic distance images over integer residue rings. Specifically, we prove that near-extremal collapse of the distance set in Znd forces strong algebraic structure supported on annihilator submodules arising from the arithmetic of n. As a consequence, we obtain the first inverse theorem for the Falconer distance problem over Zn for composite moduli. We show that if a set E ⊂ Znd of size |E| n(d+1)/2 determines only O(n) distinct squared distances, then E must be supported on a coset of an annihilator submodule on which the distance form is algebraically degenerate. The proof introduces a divisor-depth decomposition intrinsic to Zn, together with a lifting mechanism that transfers local degeneracies at prime moduli into global ideal-theoretic constraints. This yields a complete classification of near-extremizers for the Falconer distance problem in the ring setting, revealing a rigidity phenomenon with no analogue over fields.