English

Harmonically dancing space-time nodes: quantitatively deriving relativity, mass, and gravitation

General Physics 2007-05-23 v2

Abstract

The microscopic structure of space and time is investigated. It is proposed that space and time of an inertial observer Σ\Sigma are most conveniently described as a crystal array Λ\Lambda, with nodes representing measurement `tickmarks' and connected by independent quantized harmonic oscillators which vibrate more severely the faster Σ\Sigma moves with respect to the object being measured (due to the Uncertainty Principle). The Lorentz transformation of Special Relativity is derived. Further, mass is understood as a localized region ΔΛ\Delta \Lambda having higher vibration temperature than that of the ambient lattice. The effect of relativistic mass increase may then be calculated without appealing to energy-momentum conservation. The origin of gravitation is shown to be simply a transport of energy from the boundary of ΔΛ\Delta \Lambda outwards by lattice phonon conduction, as the system tends towards equilibrium. Application to a single point mass leads readily to the Schwarzschild metric, while a new solution is available for two point masses - a situation where General Relativity is too complicated to work with. The important consequence is that inertial observers who move at relative speeds too close to cc are no longer linked by the Lorentz transformation, because the lattice of the `moving' observer has already disintegrated into a liquid state.

Keywords

Cite

@article{arxiv.physics/0004071,
  title  = {Harmonically dancing space-time nodes: quantitatively deriving relativity, mass, and gravitation},
  author = {Richard Lieu},
  journal= {arXiv preprint arXiv:physics/0004071},
  year   = {2007}
}

Comments

13 pages, 3 figures