The comparison of theoretical predictions with measuring data of stellar parameters

TL;DR

This paper develops a new theoretical framework for hot star interiors accounting for electrical interactions in plasma, and demonstrates its predictions align well with observational data, challenging traditional models based solely on the Euler equation.

Contribution

It introduces a new postulate incorporating electrical interactions in plasma, leading to a comprehensive theory of hot star interiors and related phenomena.

Findings

Predicted star mass distribution matches observed data.

Derived mass-radius, mass-temperature, and mass-luminosity relations agree with measurements.

The theory explains apsidal rotation and solar oscillation spectra successfully.

Abstract

The Euler equation has been accepted as the basic postulate of stellar physics long before the plasma physics was developed. The existence of electrical interaction between particles of interstellar plasma poses the question, how this interaction must be accounted for. We argue that the right way is in formulation of a new postulate. On the base of the new postulate, the theory of a hot star interior is developed. Using this theory we obtain the distribution of stars over their masses and mass-radius, mass-temperature and mass-luminosity dependencies. The theory of the apsidal rotation of binary stars and the spectrum of solar oscillation is considered. All these theoretical predictions are in a good agreement with the known measurement data, which confirms the validity of this consideration.