A Challenge to Control Gravity via Applying Electromagnetic Low-Frequency Radiation - Theory and Proposed Model Experiments

TL;DR

This paper explores the theoretical possibility of controlling gravity through low-frequency electromagnetic radiation, proposing a model that predicts a decrease in gravitational mass of iron under specific electromagnetic conditions.

Contribution

It introduces a novel model combining Vaidya metric with the Expansive Nondecelerative Universe to localize gravitational energy and suggests experimental tests for gravity control via electromagnetic fields.

Findings

Theoretical model predicts gravitational mass reduction in iron under specific electromagnetic conditions.

Proposed experiments aim to verify the effect of electromagnetic radiation on gravitational mass.

Introduction of Yukawa-type potential replaces Newton potential in the model.

Abstract

Including Vaidya metric into the model of Expansive Nondecelerative Universe allows to localize the energy of gravitational field. A term of effective gravitational range is introduced and classic Newton potential is substituted for Yukawa-type potential. It allows to allocate a typical frequency value to each gravitational field. Derived theoretical conclusions led us to investigate the effect of electromagnetic field with a precisely predetermined frequency and intensity on iron. We believe that under certain circumstances a decrease in iron gravitational mass should be observed. Two model experiments verifying the theoretical conclusions are proposed.