Influence of Spinning Electric Fields on Natural Background Gamma-Radiation

TL;DR

This study investigates how spinning electric fields, acting as virtual gyroscopes with quantum properties, influence natural background gamma-radiation, revealing that rotation direction affects gamma-ray intensity and distribution.

Contribution

It introduces a novel concept of virtual gyroscopes affecting gamma radiation and demonstrates the impact of spinning electric fields on gamma-ray statistics and intensity.

Findings

Spinning electric fields reduce gamma-radiation intensity.

The effect depends on the rotation direction of the virtual gyroscope.

Rotation itself plays a key role, independent of the carrier matter.

Abstract

This paper considers influence of spinning electric field on statistics of natural background gamma-radiation. The spinning electric field, shown as a virtual gyroscope, has quantum mechanics characteristics. Interaction of the virtual fermion-like gyroscope with bosons (gamma-quanta) results in lowering intensity of the gamma-radiation and altering Poisson distribution. The statistic of the observed phenomenon depends on the direction of rotation of the virtual gyroscope. The results are discussed in a shade of spin-spin interaction having regard to realizing thermodynamically profitable conditions. Similarity of observed reduction of gamma-radiation in spinning electric fields and that for mechanical rotation stresses a special role of rotation itself, disregarding the matter of its carrier.