We present a concise and self-contained extension of the Finite Ring Continuum (FRC) programme, showing that symmetry-complete prime shells \ (F \) with \ (p = 4t + 1\) exhibit a fundamental Euclidean-Lorentzian dichotomy. A genuine Lorentzian quadratic form cannot be realised within a single space-like prime shell \ (F \), since to split time from space one requires a time coefficient \ (c²\) in the nonsquare class of \ (F ^\), but then \ (c F \). An explicit finite-field Lorentz transformation is subsequently derived that preserves the Minkowski form and generates a finite orthogonal group \ (O (Q_, Fℂ) \) of split type (Witt index 1). These results demonstrate that the essential algebraic features of special relativity—the invariant interval and Lorentz symmetry—emerge naturally within finite-field arithmetic, which further provides a comprehensive justification for the ``relativistic algebra'' terminology in FRC. Finally, this dichotomy implies the algebraic origin of causality: Euclidean invariants reside within a space-like shell \ (F \), while Lorentzian structure and causal separation arise in its quadratic (space-time) extension \ (Fℂ\).
Yosef Akhtman (Wed,) studied this question.
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