Explicit Factorization of xp+1-1 over Zpe: A Structural Approach via Dickson Polynomials

Abstract

Let p be an odd prime. The factorization of the polynomial xp+1-1 over the integer residue ring Zpe is pivotal for constructing cyclic codes with Hermitian symmetry, a critical resource for Linear Complementary Dual (LCD) codes and Entanglement-Assisted Quantum Error-Correcting Codes (EAQECC). Traditionally, lifting factorizations relies on the generic Hensel's Lemma, masking the underlying algebraic structure. In this paper, we establish a structural isomorphism between the lifting process and the roots of a special auxiliary polynomial V(x), unveiling a deterministic link to Dickson polynomials. Based on this theory, we develop Dickson-Engine, a linear-time algorithm (O(ep)) that outperforms standard libraries by orders of magnitude. Applying this engine to Z169, we explicitly construct a family of classical LCD codes of length n=182 via the isometric Gray map. Our search reveals codes with parameters (e.g., [182, 1, 168]13 and [182, 2, 144]13) that are near-optimal with respect to the theoretical Griesmer Bound. Notably, we discover a ``robustness plateau'' starting from non-trivial dimensions (k=4), where the minimum distance remains stable (d=120) even as the dimension triples (k=4 → 12). These codes provide exceptional resources for post-quantum cryptography and quantum error correction without entanglement consumption (c=0).