Selective Atomic Heating in Plasmas: Implications for Quantum Theory

TL;DR

This paper introduces Classical Quantum Mechanics, a model where electrons are classical objects, predicting stable smaller hydrogen states called hydrinos, supported by experimental evidence of superheated hydrogen atoms in plasmas.

Contribution

The paper proposes a classical-based quantum model predicting hydrinos and explains superheated hydrogen atoms as evidence for these smaller stable states.

Findings

Prediction of stable hydrino states smaller than standard hydrogen

Experimental reports of superheated hydrogen atoms support the model

Alleged correlation between hydrino formation and superheated atoms

Abstract

A new model of quantum mechanics, Classical Quantum Mechanics, is based on the (nearly heretical) postulate that electrons are physical objects that obey classical physical laws. Indeed, ionization energies, excitation energies etc. are computed based on picturing electrons as bubbles of charge that symmetrically surround a nucleus. Hence, for example, simple algebraic expressions based on Newtonian force balances are used to predict ionization energies and stable excitation states with remarkable precision. One of the most startling predictions of the model is that there are stable sizes of the hydrogen atom electron (bubble diameter) that are smaller (called hydrinos) than that calculated for the standard ground state. Experimental evidence in support of this novel physical/classical version of quantum is alleged to be found in the existence of super heated hydrogen atoms reported by many teams in a variety of plasmas. It is postulated that the energy required for creating super heated H aoms comes from the shrinkage of ground state H atoms to form hydrinos. This claim is discussed with reference to a brief review of the published studies of line broadening.