Quantum Mechanics from General Relativity [E-Book] : An Approximation for a Theory of Inertia / by Mendel Sachs.
This monograph is a sequel to my earlier work, General Relativity and Matter [1], which will be referred to henceforth as GRM. The monograph, GRM, focuses on the full set of implications of General Relativity Theory, as a fundamental theory of matter in all domains, from elementary particle physics...
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Full text |
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Personal Name(s): | Sachs, Mendel, author |
Imprint: |
Dordrecht :
Springer,
1986
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Physical Description: |
XVI, 227 p. online resource. |
Note: |
englisch |
ISBN: |
9789400946644 |
DOI: |
10.1007/978-94-009-4664-4 |
Series Title: |
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Fundamental Theories of Physics, A New International Book Series on The Fundamental Theories of Physics: Their Clarification, Development and Application ;
18 |
Subject (LOC): |
- 1 / Fundamental Outlook
- 2 / On the Comparison of the Quantum and Relativity Theories
- 2.1 Competing Concepts
- 2.2 Is the Quantum Jump Compatible with the Theory of Relativity?
- 2.3 Is the Theory of Relativity Complete as a Theory of Matter?
- 2.4 The Einstein—Podolsky—Rosen Paradox
- 2.5 The Hidden Variable Approach
- 2.6 Bell’s Inequalities and General Relativity
- 3 / Basis of a Matter Field Theory of Inertia — a Generalization of Quantum Mechanics
- 3.1. The General Mathematical Structure and Philosophical Implications
- 3.2. The Conservation of Interaction
- 3.3. Determinism
- 4 / A Covariant Field Theory of Inertia
- 4.1. On the Origin of Inertial Mass
- 4.2. The Spinor Formalism in Special Relativity
- 4.3. The Spinor Variables in General Relativity
- 4.4. The Spinor Matter Field Equations in General Relativity
- 4.5. Matter and Antimatter
- 4.6. On the Quantization of Electrical Charge from General Relativity
- 4.7. Conclusions
- 5 / The Electromagnetic Interaction
- 5.1. On the Meaning of the Electromagnetic Field Equations
- 5.2. Generalization of the Elementary Interaction Formalism
- 5.3. A Spinor Formulation of Electromagnetism
- 5.4. The Interaction Lagrangian
- 6 / Quantum Mechanics from the Matter Field Equations and Derivation of the Pauli Exclusion Principle
- 6.1. Approximations to Quantum Mechanics
- 6.2. The Pauli Exclusion Principle — a Derivation
- 6.3. The Hartree Approximation for the Matter Field Equations
- 6.4 Scattering Cross Section
- 7 / The Particle—Antiparticle Pair without Annihilation Creation
- 7.1. The Field Equations for the Particle—Antiparticle Pair
- 7.2. An Exact Bound State Solution for the Particle—Antiparticle Pair
- 7.3. The Energy and Momentum of the Bound Particle—Anti particle in its Ground State
- 7.4. The Free Particle Limit and Pair Creation
- 7.5. The Continuity of Energy Values
- 7.6. Dynamical Properties of the Pair in the Ground State
- 7.7. The Compton Effect
- 7.8. Blackbody Radiation — a Derivation of Plank’s Law
- 7.9. The Anomalous Magnetic Moment of the Electron
- 8 / The Electron—Proton System
- 8.1. Linearization of the Hydrogen Field Equations
- 8.2. The Lamb Splitting
- 8.3. Deuterium and He+
- 8.4. The Lifetimes of Atomic Excited States
- 8.5. Atomic Helium
- 8.6. Electron—Proton Scattering in a Vacuum
- 8.7. Electron—Proton Scattering in a Background of Pairs
- 8.8. Summary
- 9 / Elementary Particle Physics
- 9.1. The Neutron
- 9.2. The Pion
- 9.3. On the Possible Origin of CP-Violation in Neutral Kaon Decay
- 9.4. On Time Reversal Noninvariance in Nuclear Forces — a Magnetic Resonance Experimental Test
- 9.5. Proton—Antiproton Collisions and the W±-Particle from General Relativity
- 9.6. Concluding Remarks
- Epilogue
- Appendix A / Computation of the Lamb Splitting 207.