. This paper explores the Energy Density Hypothesis, proposing that local vacuum stress (energy density) is the physical cause of relativistic time dilation, independent of its source (whether it be velocity or magnetic fields). Key aspects of the study: Theoretical Basis: Using data from the Fermilab Muon g-2 experiment (total energy approx 3. 1 GeV, gamma factor approx 29. 3), the author calculates the static magnetic field required to replicate the equivalent energy density in a resting muon. Critical Threshold: Assuming an effective vacuum perturbation radius of rₑff approx 1. 0 micrometer, the required critical field is calculated to be approximately 17. 25 Tesla. Predicted Phase Transition: The theory predicts that upon crossing the 17. 25 T threshold, the lifetime of a stopped muon will exhibit a non-linear increase, jumping from its rest value of 2. 2 microseconds to approximately 64 microseconds. Experimental Proposal: The paper outlines an "Experimentum Crucis" using surface muons in a solenoid with a field of at least 20 Tesla to falsify the hypothesis. Observation of this effect would constitute a significant deviation from Standard Model predictions and provide a completely new physical interpretation of the nature of time.
Sergey Yurevich Paygachkin (Fri,) studied this question.
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