$\hbar$ as a Physical Constant of Classical Optics and Electrodynamics

TL;DR

This paper derives the Planck constant as a natural outcome of classical electromagnetic analysis in metallic cavities, linking it to boundary conditions and mode properties, thus providing a classical foundation for quantum constants.

Contribution

It presents a classical electromagnetic framework that derives the Planck constant from boundary conditions and mode analysis, challenging its traditional quantum postulate origin.

Findings

Derived $oxed{ ext{hbar} = 1.02 imes 10^{-34} ext{ J} imes ext{s}}$ from classical analysis.

Explained equilibrium in blackbody radiation via mode coupling and boundary conditions.

Connected the uncertainty principle to classical electromagnetic properties.

Abstract

The Planck constant ($\hbar$) plays a pivotal role in quantum physics. Historically, it has been proposed as postulate, part of a genius empirical relationship $E=\hbar \omega$ in order to explain the intensity spectrum of the blackbody radiation for which classical electrodynamic theory led to an unacceptable prediction: The ultraviolet catastrophe. While the usefulness of the Planck constant in various fields of physics is undisputed, its derivation (or lack of) remains unsatisfactory from a fundamental point of view. In this paper, the analysis of the blackbody problem is performed with a series expansion of the electromagnetic field in terms of TE, TM modes in a metallic cavity with small losses, that leads to developing the electromagnetic fields in a \textit{complete set of orthonormal functions}. This expansion, based on coupled power theory, maintains both space and time together enabling modeling of the blackbody's evolution toward equilibrium. Reaching equilibrium with a multimodal waveguide analysis brings into consideration the coupling between modes in addition to absorption and emission of radiation. The properties of the modes, such as spectral broadening, losses and lifetime, then progressively become independent of frequency and explains how equilibrium is allowed in good conductor metallic cavities. Based on the free electron relaxation time in gold, a value of $\hbar = 1.02 \times 10^{-34}$ J$\cdot$s for the reduced Planck constant is found and the uncertainty principle is also emerging from this \textit{a priori} classical study. The Planck constant is then obtained no longer as an ad hoc addition but as a natural consequence of the analysis taking boundary conditions into account as into optical resonators. That analysis based on finite-spacetime paradigm, also shine new light on the notion of decoherence in classical optics and electrodynamics.