Fundamental Laws and Quantum Dynamics

Eliade Stefanescu

doi:10.2174/0127723348321035240909070125

ISSN: 2772-3348
E-ISSN: 2772-3356

Fundamental Laws and Quantum Dynamics
By Eliade Stefanescu¹
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¹ Advanced Studies in Physics Centre of the Romanian Academy, Academy of Romanian Scientists, Bucharest, Romania
Source: Current Physics, Volume 1, Issue 1, Jan 2024, E27723348321035
DOI: https://doi.org/10.2174/0127723348321035240909070125
- Received: 08 May 2024
- Accepted: 22 Jul 2024
- Available online: 16 Sep 2024

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Abstract

Background

Recently, we obtained a unitary theory of quantum mechanics and general relativity, where a quantum particle is a continuous distribution of matter in the two conjugate spaces of the coordinates and momentum, quantized by the equality of the mass parameter describing the relativistic dynamics of the matter, with the mass as an integral of the matter density. However, in this framework, we have not explicitly revealed the connection between our new theory and the fundamental laws of quantum mechanics.

Methods

We analyzed in detail the three fundamental laws of quantum mechanics, explicitly describing experimental data: 1) Planck’s law of the blackbody electromagnetic radiation of a system of electrically charged harmonic oscillators, 2) Einstein’s law of the photon energy proportionality with the photon frequency, and 3) de Broglie’s law of the quantum particle as an oscillator in space.

Results

We reobtained the two dynamical equations, in the conjugate spaces of the coordinates and momentum, as functions of the Lagrangian system, unlike the Schrödinger equation, depending on the Hamiltonian.

Conclusion

According to the fundamental laws of quantum mechanics, a quantum particle is a continuous distribution of matter with an intrinsic mass, unlike the conventional quantum mechanics for the state occupation probabilities of punctual entities moving with the light velocity and getting an apparent mass only by collisions with some bosons pervading the whole universe. According to these laws, we obtained a quantum theory in agreement with common sense, classical logic, and general relativity.

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