What question did this study set out to answer?

This research aims to derive quantum-scale predictions from the mass curvature rate framework.

February 23, 2026Open Access

MUT v6.25.1: Quantum Predictions of the MCR Framework – Detailed Calculations

Key Points

This research aims to derive quantum-scale predictions from the mass curvature rate framework.
Utilized theoretical derivations and numerical estimates to create five quantum-scale predictions.
Conducted Python simulations to demonstrate computational feasibility.
Outlined potential experimental tests for each prediction.
Identified proton radius variation and electron g-factor anomaly as major phenomena of interest.
Demonstrated links between scalar-induced energy shifts and measurable quantum observables.
Explored entanglement decoherence timescales and high-frequency gravitational wave tails.

Abstract

MUT 6.25.1 presents five precise quantum-scale predictions derived from the Mass Curvature Rate (MCR) framework. Each prediction includes detailed theoretical derivations, numerical estimates, and potential experimental tests. Covered phenomena include proton radius variation, electron g-factor anomaly, high-frequency gravitational wave tails, scalar-induced energy level shifts, and entanglement decoherence timescales. Python simulations illustrate practical computation and experimental feasibility, linking MCR scalar field effects to measurable quantum observables.

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Cite This Study

Myomin Aung (Sat,) studied this question.

synapsesocial.com/papers/699ba05e72792ae9fd86fd0d https://doi.org/https://doi.org/10.5281/zenodo.18719272