Developments in Quantum PhysicsNova Publishers, 2004 - 280 من الصفحات The forefront of contemporary advances in physics lies in the submicroscopic regime, whether it be in atomic, nuclear, condensed-matter, plasma, or particle physics, or in quantum optics, or even in the study of stellar structure. All are based upon quantum theory (i.e., quantum mechanics and quantum field theory) and relativity, which together form the theoretical foundations of modern physics. Many physical quantities whose classical counterparts vary continuously over a range of possible values are in quantum theory constrained to have discontinuous, or discrete, values. The intrinsically deterministic character of classical physics is replaced in quantum theory by intrinsic uncertainty. According to quantum theory, electromagnetic radiation does not always consist of continuous waves; instead, it must be viewed under some circumstances as a collection of particle-like photons, the energy and momentum of each being directly proportional to its frequency (or inversely proportional to its wavelength, the photons still possessing some wavelike characteristics). |
المحتوى
| 1 | |
The QuantumClassical Interface Bohmian Theory and Quantum Mechanics | 23 |
It From Bit? | 41 |
On the Origin of Conceptual Difficulties of Quantum Mechanics | 85 |
Time ordering in Quantum Mechanics | 111 |
Coherent population transfer between degenerate states | 123 |
The Maxwell Equations with GradientType Sources their Applications and Quantization | 143 |
Quantum Physics of Cold Fusion Phenomenon | 167 |
Neutrino Mixing | 197 |
Quantitative Determination of the Effect of the Harmonic Component in Monochromatised Synchrotron Xray Beam Experiments | 255 |
Orbital Angular Momentum of Photoelectrons Excited by CircularlyPolarized Light Rotation of Forward Scattering Peaks in Photoelectron Diffracti... | 261 |
عبارات ومصطلحات مألوفة
allowed angle appear approximation assumed atom becomes calculated charge classical coherence complete component condition considered constant corresponding dark matter density depends described determined Dirac direction discussed effect electromagnetic electron energy equation example excited existence exotic experimental experiments explained expressed fact field Figure force give given harmonic hydrogen initial interaction interpretation Kozima lattice light limit Majorana mass matrix matter Maxwell means measured micro-quantum mixing mode motion nature neutrino neutron nuclear nuclei observed obtained occurs operator oscillations parameter particle phase photon Phys physics polarized population positive possible potential probability problem propagation properties quantum mechanics radiation reactions regions relation relativity respectively scale scattering shown shows solar solids solution sources space standard symmetry term theory transform transition universe vacuum wave function zero point