A Trajectory Description of Quantum Processes. II. Applications: A Bohmian PerspectiveSpringer, 13 сент. 2013 г. - Всего страниц: 333 Trajectory-based formalisms are an intuitively appealing way of describing quantum processes because they allow the use of "classical" concepts. Beginning as an introductory level suitable for students, this two-volume monograph presents (1) the fundamentals and (2) the applications of the trajectory description of basic quantum processes. This second volume is focussed on simple and basic applications of quantum processes such as interference and diffraction of wave packets, tunneling, diffusion and bound-state and scattering problems. The corresponding analysis is carried out within the Bohmian framework. By stressing its interpretational aspects, the book leads the reader to an alternative and complementary way to better understand the underlying quantum dynamics. |
Содержание
| 1 | |
Quantum Interference and Superposition | 49 |
Interference and Interferometry | 96 |
Bound System Dynamics | 135 |
Tunneling Dynamics | 173 |
Atom Scattering from Periodic Surfaces | 212 |
Scattering from Surface Defects and Activated Diffusion | 249 |
ManyBody Systems and Quantum Hydrodynamics | 271 |
Epilogue | 304 |
Computing Bohmian Trajectories from the Wave Function The Analytic Approach | 309 |
| 331 | |
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A Trajectory Description of Quantum Processes. II. Applications: A Bohmian ... Ángel S. Sanz,Salvador Miret-Artés Недоступно для просмотра - 2013 |
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adsorbates analyze associated asymptotic atoms beam behavior Bohmian mechanics Bohmian trajectories Chap Chem classical trajectories coherent complex compute configuration space consider correlation function corresponding decay decoherence defined deflection function density functional theory density matrix described diffusion displayed in Fig dissipative distance dynamics effect eigenstates electrons energy equation of motion evolution expression friction Gaussian wave packet given grating Hamiltonian incident initial conditions initial wave function intensity interference interferometry Lett maxima Miret-Artés molecular molecules momentum observed obtained oscillator panel parameters particle pattern peaks phase phonons Phys physics plane wave probability density propagation quantum hydrodynamic quantum mechanics quantum potential quantum system quantum trajectories region respectively Sanz scattering Schrödinger equation Sect seen semiclassical slits solid line spreading stochastic superposition surface Talbot temperature theory time-dependent time-evolution tion tunneling two-slit unit cell velocity wave function width