Anomalies In The beta-decay Processes And The Pulse Strong-Current Discharges As Consequence Of Electron Gravitational Emission

TL;DR

This paper explores anomalies in beta-decay and strong-current discharges as potential manifestations of gravitational emission, proposing new fundamental insights and suggesting experimental tests for these phenomena.

Contribution

It introduces a novel hypothesis that links anomalies in beta-decay and plasma discharges to gravitational emission, offering a new perspective on fundamental interactions.

Findings

Parity nonconservation as an anomaly potentially related to gravitational effects

Generation of high-temperature plasma formations in discharges linked to gravitational emission

Testable predictions for beta-decay and plasma discharge experiments

Abstract

Parity nonconservation in the beta-decay processes is considered as fundamental property of weak interactions. Nevertheless, this property can be treated as anomaly, because in fundamental interactions of the rest types parity is conserved. Analogously, anomaly in the short-duration strong-current pulse discharges is well known. The essence of this phenomenon consists in generation of local high-temperature plasma formations (LHTF) with the typical values of its thermodynamical parameters exceeding those related to the central section of a discharge. In this paper, an attempt is undertaken to treat these anomalies as manifestation of fundamental properties of gravitational emission. Some consequences of this assumption can be tested in the beta-decay experiments as well as in the experiments with short-duration z-pinch-type pulse discharges.