The Quantum Theory of Motion: An Account of the de Broglie-Bohm Causal Interpretation of Quantum MechanicsCambridge University Press, 1995. gada 26. janv. - 598 lappuses This book presents the first comprehensive exposition of the interpretation of quantum mechanics pioneered by Louis de Broglie and David Bohm. The purpose is to explain how quantum processes may be visualized without ambiguity or confusion in terms of a simple physical model. Dr. Holland develops the idea that a material system such as an electron is a particle guided by a surrounding quantum wave. He examines the classic phenomena of quantum theory in order to show how the spacetime orbits of an ensemble of particles can reproduce the statistical quantum predictions. The book will therefore appeal to all physicists with an interest in the foundations of their discipline. |
Saturs
Quantum mechanics and its interpretation | 1 |
HamiltonJacobi theory | 16 |
5 | 41 |
Elements of the quantum theory of motion | 66 |
Appendix A | 134 |
Interference and tunnelling | 173 |
The classical limit | 218 |
Manybody systems | 277 |
Theory of experiments | 324 |
the Pauli theory | 379 |
the rigid rotator | 424 |
The EinsteinPodolskyRosen experiment and nonlocality | 458 |
Appendix | 495 |
References | 572 |
585 | |
Appendix The connection between Q and stationary perturbation | 321 |
Bieži izmantoti vārdi un frāzes
actual amplitude angular momentum arbitrary associated atom beam Bohm Broglie causal interpretation Chap classical limit classical mechanics component concept configuration space constant coordinates correlated corresponding d³x defined definition density matrix depends described Dewdney distribution domain effect eigenfunctions eigenstate eigenvalue Einstein electromagnetic electron ensemble equation of motion example expectation value expression external potential factorizable field theory finite formalism function given Hamilton-Jacobi equation Hamilton-Jacobi theory Hamiltonian implies independent individual initial position interaction interference k₁ magnetic many-body mean measurement nonclassical nonlocality observed obtain operator orbit oscillator overlap Pauli Pauli equation Phys plane wave potential energy probability density problem properties quantal quantized quantum force quantum mechanics quantum number quantum potential quantum theory region result rotation scalar Schrödinger equation slit solution spacetime spin vector spinor stationary statistical superposition tensor theory of motion trajectory transformation variables velocity wave equation wavefunction
Atsauces uz šo grāmatu
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