Internal Energy and the Dynamics of Quantum Particles, Part III - Quantum Relativity

摘要

Classical physics can predict relativistic effects, such as mass increase, length contraction andtime dilation without recourse to particular hypotheses like the existence of aether. The compo-nents of 'elementary' particles are bound by gauge bosons, i.e., quanta of inner forces. The averageenergy of these quanta and particle velocity are correlated according to the classic Doppler effect.The relativistic Doppler effect is not taken into account because Einstein's principle of relativity isuntenable. Based on the law of energy equi-partition, all oscillators within an 'elementary' particle,i.e., all quanta and matter-like components, have the same average energy. As a result, the relativ-istic energy and mass are proportional to the Lorentz factor. In turn, this mass increase leads tolength contraction and time dilation. The velocity of light in vacuum obeys the classic rule of ve-locity addition, but length contraction can hide this fact and therefore explains Michelson and Mor-ley's null results. More recent measurements, which are not skewed by length contraction, provelight obeys the classic theorem of velocity addition.