Quantum-Resistant RSA Modulus Decomposition via Adaptive Rényi Entropy Optimization

This paper explores a theoretical approach to enhance RSA's resistance against quantum attacks by optimizing prime selection through R\'enyi entropy constraints. We develop a framework where primes are generated with controlled proximity ($|p-q| < \gamma\sqrt{pq}$) to minimize the collision entropy $\mathscr{H}_2$ of the quantum period-finding operator. The main contributions include: (1) establishing a connection between prime distribution properties and quantum attack complexity via Maynard's prime gap theorem, (2) providing a constructive proof for prime existence under entropy constraints, and (3) demonstrating security reduction to ideal lattice problems under the quantum random oracle model. Theoretical analysis suggests that for $k$-bit moduli with $\gamma < k^{-1/2+\epsilon}$, Shor's algorithm requires $\Omega(\gamma^{-1}k^{3/2})$ quantum operations while maintaining classical security equivalent to standard RSA. Key Enhancements: (1) Prime existence proof via Maynard's theorem (Theorem 3.1), (2) Ideal lattice embedding for SVP reduction (Theorem 5.3), (3) Quantum Fano bound for information-theoretic analysis (Theorem 6.3), (4) Multi-prime RSA extension (Section 7.3).