The Revolving Charge Particle Model

Name: The Revolving Charge Particle Model
Brand: Hachette Aotearoa New Zealand
SKU: 9781667867465
Price: 44.99 NZD
Availability: InStock

By Ernst Wall

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Summary

The Revolving Charge Particle Model by Ernst Wall presents an innovative theoretical framework where the electron is modelled as having a tiny charge revolving at light speed within a Compton wavelength orbit. This approach enables elegant algebraic derivations of fundamental properties such as the magnetic moment, mass-energy, and spin-angular momentum without reliance on wave mechanics.

The model extends to protons, neutrons, and a deuteron composed of revolving charged protons attracted by a pion, yielding dimensions and binding energy estimates close to known values. It also introduces unique electron-based coordinate units grounded in Compton wavelets to explore atomic structure nuances. Furthermore, the book offers predictions for meson masses with notable accuracies across several meson families up to 4074 MeV.
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The Revolving Charge Particle Model

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This technical book is ideal for advanced students, researchers, and professionals in physics or related fields with a strong interest in particle and nuclear models. Readers should be comfortable with algebra and fundamental physics concepts to fully engage with the novel theoretical developments presented.

Description

The Revolving Charge Particle Model

We have developed a novel revolving charge model wherein the electron's tiny charge revolves at the speed of light in a Compton wavelength orbit. Using this, we can derive the magnetic moment (the Bohr magneton) identically, in three simple algebraic equations. (See Eqs. 1-1 through 1-3.)

We derive the mass-energy in two easy equations, and the spin-angular momentum, again, in three easy equations. Wave mechanics is not needed here, and the results speak for themselves.

We expand this to cover the proton, the neutron, and a Yukawa-like deuteron model made up of two revolving charge protons that are mutually attracted to a pion. Using the diameter of the protons and the quadrupole moment of the deuteron, we determine its dimensions. It is interesting to note that using these discrete charges and their spacing, the graphically calculated electrostatic binding energy is 2.444 MeV, whereas the known binding energy is 2.22 MeV. (We note that there are likely those that will be sceptical about these results, but they can easily do the math for themselves.)

We also study the effects of the Compton wavelets on the first Bohr radius. To do this, we have to define "electron coordinates" where the unit of time is the time that it takes for the revolving charge to do one revolution (te = 8.09329979E-21 seconds), the unit of length is the Compton wavelength, and the unit of mass is the mass of the electron. Velocity, of course, is Comptons per rotation.

The meson model provides the masses of the mesons below 4074 MeV. The Psi meson masses have accuracies of -1.3% to 4.7%. The meson series from the Eta through the A0(980) have errors ranging from 0.5% to 2.3%. The remaining mesons have accuracies of -16% to +12%.

Book Details

INFORMATION

ISBN: 9781667867465

Publisher: BookBaby

Format: Paperback / softback

Date Published: 22 November 2022

Country: United States

Imprint: BookBaby

Illustration: Illustrations

Audience: General / adult

DIMENSIONS

Spine width: 10.0mm

Width: 215.0mm

Height: 279.0mm

Weight: 381g

Pages: 132

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Education & Reference Ernst Wall Non-Fiction Science & Nature

About the Author

Ernst Wall has an MS in cryophysics from the University of FL where for his thesis, he invented a strain gauge that provided the first direct measurements of the CVT surface of solid helium-3. He has designed superconducting magnets. He has done extensive C++ programing for device control. He has also worked with Kalman filters, infrared systems, and radar systems. He has done extensive systems simulations using C++, Java, and Matlab languages. He has done hardware design for RF systems and digital systems.