Every natural number is a sum of distinct semiprime unit fractions

Abstract

We prove that every natural number is a finite sum of distinct unit fractions whose denominators are semiprimes (products of two distinct primes). This is the ω=2 integer case of a problem of Erdős and Graham, stated only as a conjecture by Butler, Erdős and Graham (Integers 15 (2015), A51), who proved the ω=3 analogue. Counterintuitively the problem hardens as ω decreases -- the induction's feed thins -- so ω=2 is the hard case; our proof adapts the Butler-Erdős-Graham induction to this thin-feed regime, where the entire content of the induction step reduces to an explicit onset inequality Y0(N)\β(N),β'(N)\, proved for all N10 by Olson's addition theorem and elementary Chebyshev bounds above a finite, machine-checked base range. The same engine extends to the rationals: for every squarefree b, every a/b above an explicit threshold \BNb/6,\,1/5\ is ω=2 representable, unconditionally. As an application we give the first complete proof of the rational ω=3 statement -- every a/b with squarefree b is a sum of distinct sphenic unit fractions -- that Butler, Erdős and Graham conjectured but left unpublished; a descent settles every ω3. What remains open is the ω=2 regime below this threshold, which we reduce to a single explicit conjecture -- that the gap-free floor of a semiprime subset-sum set tends to zero. This work is a human-AI collaboration: AI tools (notably Anthropic's Claude, used through Claude Code) contributed substantially to the Lean formalisation, the experiments, and the writing; correspondingly, every result is machine-checked in Lean 4 / Mathlib (no sorry; two cited classical axioms, plus the nativedecide compiler-trust base for the finite computations), so its correctness is independent of the tools used.