Impact models of gravitational and electrostatic forces: Potential energies, atomic clocks, gravitational anomalies and redshift

TL;DR

This paper presents a heuristic impact model for gravitational and electrostatic forces involving hypothetical massless entities, exploring potential energies, atomic clock behavior, gravitational anomalies, and redshift effects.

Contribution

It introduces a modified impact model with anti-parallel emission of gravitons, providing new insights into gravitational potential effects on clocks and light.

Findings

Potential energy in two-body systems explained by impact model

Photon speed varies with gravitational potential

Atomic clock rates depend on gravitational potential

Abstract

The far-reaching gravitational force is described by a heuristic impact model with hypothetical massless entities propagating at the speed of light in vacuum and transferring momentum and energy be- tween massive bodies through interactions on a local basis. In the original publication (Wilhelm et al. 2013), a spherical symmetric emission of secondary entities had been postulated. The potential energy problems in gravitationally and electrostatically bound two-body systems have been studied in the framework of this im- pact model of gravity and of a proposed impact model of the electrostatic force (Wilhelm et al. 2014). These studies have indicated that an anti-parallel emission of a secondary entity - now called graviton - with respect to the incoming one is more appropriate. This article is based on the latter choice and presents the modifications resulting from this change. The model has been applied to multiple interactions of gravitons in large mass conglomerations in several publications. They will be summarized here taking the modified interaction process into account. In addition, the speed of photons as a function of the gravitational potential are considered in this context together with the dependence of atomic clocks and the redshift on the gravitational potential.