Relativizing Newton


Ramzi Suleiman
University of Haifa, & Triangle Research & Development Center (TRDC), Israel

Series: Physics Research and Technology
BISAC: SCI055000

Relativizing Newton is a first step towards a simple and beautiful theory of everything. The theory, termed “Information Relativity” (IR) takes an innovative approach to physics that overlooks all post-Newtonian physics. It stands on the shoulders of Newtonian dynamics, but modifies it by accounting for the time-travel of information from one reference-frame to another, a fact which somehow was ignored by Galileo Galilee and Isaac Newton, and which remained ill-treated by all post-Newtonian theories, including Einstein’s relativity and quantum theories. Except for the aforementioned correction of classical physics, IR has no axiomatic presumptions, nor arbitrary free parameters.

Astonishingly, accounting for the aforementioned delays in information results in a set of simple and beautiful transformations, which explain and predict a great deal of physical phenomena. Most importantly, IR’s transformations reveal the mysteries of dark matter, dark energy, and gravity. They also provide a unifying platform for the physics of the too-big (astrophysics and cosmology), and the too-small (small particles dynamics and quantum mechanics).

The phenomena explained and predicted successfully by IR include the “time-dilation” of decaying muons, the neutrino velocities measured by OPERA and other collaborations, particle diffraction in the double-slit experiment, Sagnac Effects, the quantization of orbits in Bohr’s hydrogen atom, entanglement, quantum criticality, confinement, asymptotic freedom, solar light bending, gravitational redshift, the Pioneer anomaly, dark matter in galaxies, and the Schwarzschild’s black hole.
(Imprint: Nova)



Table of Contents

Foreword by Nobel Laureate Prof. Vernon L. Smith


A Personal Note

Part 1: On the Dynamics of Bodies in Rectilinear Motion
Chapter 1. How Newton’s Laws Were Relativized? The Case of Inertial Rectilinear Motion
Chapter 2. Applications to Small Particle Physics I
Chapter 3. The Twin Paradox – A Commonsensical Solution
Chapter 4. Application to Quantum Mechanics I: Particle Diffraction in the Double-Slit Experiment
Chapter 5. Applications to Cosmology I: Dark Energy
Chapter 6. Relativizing Newton’s Law of Gravitation
Chapter 7. Application to Astrophysics I: Light Bending
Chapter 8. Application to Astrophysics II: Gravitational Redshift
Chapter 9. Application to Astrophysics III: Relativizing Newton’s Second Law and the Pioneer Anomaly

Part 2. On the Dynamics of Bodies in Rotational Motion
Chapter 10. Rethinking Newton’s First Law
Chapter 11. Application to Small Particle Physics II: Circular and Rectilinear Sagnac Effects
Chapter 12. Application to Quantum Mechanics II: Solving the Hydrogen Atom Problem
Chapter 13. Matter-Dark-Matter Dynamics in Rotating Bodies
Chapter 14. Application to Cosmology II: Matter-Dark-Matter Dynamics in Rotationally Supported Galaxies
Chapter 15. Application to Cosmology III: Do Galaxies 1052 = NGC – DF2 and NGC 1052 – DF4 Lack Dark Matter?
Chapter 16. Application to Cosmology IV: The Schwarzschild Black Hole
Chapter 17. On Gravity and Dark Matter
Chapter 18. Integrative Summary




“The presented ingenious physical conclusions of the new IR theory are well understandable, because one needs just a high-school level of mathematical skill to follow them. So I wish that the book will become a bestseller educating the next generation of physics students.” READ MORE… – Dr. Hermann Otto, Professor Emeritus of Materials Research and Crystallography, Clausthal University of Technology, Germany


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