TITLE:
Holographic Origin of Matter Dominance and Weak CP Violation: A Unified Theory beyond the Standard Model
AUTHORS:
Rulin Xiu
KEYWORDS:
Grand Unified Theory, Matter-Antimatter Asymmetry, CP Violation, Beyond Standard Model, Holographic Principle, Electroweak Symmetry Breaking, Generation of Large Hierarchy, Holographic Quantum Theory
JOURNAL NAME:
Journal of Modern Physics,
Vol.17 No.1,
January
22,
2026
ABSTRACT: The observed matter-antimatter asymmetry in the universe and the origin of charge-parity (CP) violation remain among the most profound unresolved questions in modern physics. While the Standard Model has achieved remarkable success, it fails to adequately account for the observed imbalance. This paper introduces a novel theoretical framework grounded in the holographic principle, proposing that the universe emerges as a projection from a two-dimensional elementary information (EI) spacetime. Within this model, matter and antimatter occupy distinct domains—termed the holomorphic and anti-holomorphic sectors, respectively. This intrinsic separation offers a natural explanation for the predominance of matter in our universe. The theory posits that interactions mediated by background fields—corresponding to gravity and gauge forces—permit the generation of antimatter within the matter-dominated holomorphic sector, aligning with empirical observations. It further elucidates why all elementary particles carry SU(2) weak charge and why violations of C, P, and CP symmetries are confined to the weak interaction. Notably, the model accounts for the SU(2) doublet nature of matter particles and the singlet nature of their antimatter counterparts. This unified holographic approach provides a fresh perspective on fundamental symmetries and the architecture of the universe, potentially resolving long-standing puzzles in cosmology and particle physics. The model also predicts the existence of a distinct, parallel mirror antimatter universe—largely decoupled from ours but interacting through gravitational and gauge fields. The theoretical implications and experimental prospects of this prediction merit further investigation.