This short note presents a structural argument for a nonzero neutron electric dipole moment (EDM) within the framework of Triadic Mesh Dynamics (TMD), a discrete geometric model of space based on oriented 2‑simplices. While the Standard Model predicts the neutron EDM to be extremely close to zero, TMD introduces subtle orientational asymmetries in the underlying triadic network, which naturally generate an effective CP‑violating contribution at the level of emergent baryons. The paper outlines the qualitative mechanism by which orientational noise and local asymmetry in the triadic mesh lead to a displacement between positive and negative charge centres inside the neutron. A simple geometric CP‑violating term in the effective action is proposed as an analogue to the QCD 𝜃‑term, arising purely from the discrete orientational structure of space. The ongoing n2EDM experiment at ILL Grenoble is highlighted as a direct and decisive test of this class of models. A nonzero neutron EDM in the experimentally accessible range would strongly support the existence of a discrete orientational substrate of space. A null result would not falsify TMD but would constrain the degree of orientational asymmetry and refine the baryonic module of the theory. This note does not attempt a numerical prediction; instead, it establishes the conceptual and geometric basis for why TMD generically implies a nonzero neutron EDM unless the triadic network is perfectly symmetric.
Aleš Kováč (Thu,) studied this question.
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