Beyond Conventionalism: Testing the One-Way Speed of Light via Classical Entanglement Synchronization

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AI-generated deep summary by claude@2026-06, 2026-06-24 · read from full text

The paper proposes and tests a method to examine the one-way speed of light by using classical entanglement synchronization, framing it as an alternative to conventional assumptions used in measuring light’s propagation. It presents an experimental/synchronization approach in which time coordination between systems is used to extract implications about the one-way speed of light. The key finding is that their synchronization-based test can be used to evaluate the one-way speed of light beyond conventionalism, according to the results reported by the authors. The main caveat is that the study’s interpretation is tied to the assumptions and operational definition embedded in the synchronization protocol and setup. The paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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Abstract

The conventionalist thesis holds that all internal clock synchronization procedures are equivalent to Einstein’s, that the one-way speed of light is conventional (i.e., not measurable), and that the Lorentz transformations (LT) and Lorentz transformations with absolute simultaneity (LTA) are empirically equivalent. In this paper, we challenge these claims by presenting a rotating rod synchronization procedure that operates independently of light signals or information transport. This procedure is a priori not equivalent to Einstein synchronization and can be used to experimentally discriminate between LT and LTA by measuring the one-way speed of light. We analyze Sagnac-type optical effects—including the linear Wang-Sagnac effect and its reciprocal variant—showing that only the LTA preserve spacetime continuity along closed non-simply connected contours. We further examine Faraday induction from moving electrified bodies and equilibrium paradoxes in relativistic electromagnetism, showing that the LTA resolve these paradoxes. The implications for quantum entanglement synchronization and variable speed of light (VSL) cosmology are briefly explored. Our analysis indicates that the claimed LT-LTA equivalence is not general, and that experimental tests of the one-way speed of light are feasible, potentially favoring the LTA framework. In particular, we find that the reciprocal linear Sagnac effect preserves reciprocity—a hallmark of the relativity principle—under the LTA, whereas the LT fail to do so, indicating that the LTA offer a more consistent description of relativistic phenomena across a wider class of physical scenarios.
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europepmc
last seen: 2026-05-20T01:45:00.602351+00:00
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License: CC-BY-4.0