Abstract

This paper proposes that quantum uncertainty arises from stochastic mass-energy interconversion at the subatomic level. Integrating Einstein's mass-energy equivalence and quantum mechanics, the hypothesis introduces fluctuating mass terms into mathematical frameworks like the Schrödinger equation, yielding novel implications for the Heisenberg Uncertainty Principle. The theory extends to quantum field theory, string theory, and cosmology, suggesting a dynamic mechanism for phenomena ranging from particle decay rates to black hole evaporation. By bridging quantum mechanics and general relativity through stochastic fluctuations, this framework offers testable predictions for high-energy physics, gravitational wave analysis, and cosmological observations, advancing the search for a unified Theory of Everything.

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