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Lasers in chemistry --- Laser manipulation (Nuclear physics) --- Molecular dynamics
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This comprehensive book presents at a theoretical level the main aspects of high-power lasers interacting with nuclei at a broad range of intensities for scientists and students involved in this new and challenging area of research. It presents theoretical techniques, some borrowed from atomic physics, and applications related to important chapters of nuclear physics. This book provides an overview of the field's state-of-the-art and an introduction to the classical and quantum foundations of the interaction of a particle or a system of particles with the electromagnetic field. Topics such as particle emission of nuclei, collective dipole modes induced by strong laser beams and laser-assisted heavy-ion scattering are discussed.
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This book provides a thorough introduction to the interaction of atoms and atomic ions with optical and magnetic fields. Particular emphasis is placed on the wealth of important multilevel effects, where atomic vapours exhibit anisotropic behaviour. As well as covering the classic two-level atom approach to light-atom interactions, a general multi-level formalism is also described in detail, and used to discuss optical pumping, two-dimensional spectroscopy and nonlinear optical dynamics. The final chapter deals with the mechanical effects of light, including the cooling and trapping of atoms. With full theoretical and experimental coverage, and over 250 illustrations, the book will be of great interest to graduate students of laser spectroscopy, quantum electronics and quantum optics, and to researchers in these fields.
Laser manipulation (Nuclear physics) --- Optical pumping. --- Laser spectroscopy.
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Laser cooling is an important emerging technology in such areas as the cooling of semiconductors. The book examines and suggests solutions for a range of problems in the development of miniature solid-state laser refrigerators, self-cooling solid-state lasers and optical echo-processors. It begins by looking at the basic theory of laser cooling before considering such topics as self-cooling of active elements of solid-state lasers, laser cooling of solid-state information media of optical echo-processors, and problems of cooling solid-state quantum processors.Laser Cooling of Solids is
Laser manipulation (Nuclear physics) --- Solids --- Laser cooling. --- Cooling. --- Cooling --- Solid state physics --- Transparent solids --- Manipulation, Laser (Nuclear physics) --- Nuclear physics
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Laser manipulation (Nuclear physics) --- Atoms --- Solids --- Laser-plasma interactions --- Laser pulses, Ultrashort --- High power lasers --- Effect of radiation on --- Laser manipulation --- Congresses --- Laser plasmas --- Laser pulses [Ultrashort ] --- Laser manipulation (Nuclear physics) - Congresses --- Atoms - Congresses --- Solids - Effect of radiation on - Congresses --- Laser-plasma interactions - Congresses --- Laser pulses, Ultrashort - Congresses --- High power lasers - Congresses
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Laser manipulation (Nuclear physics) --- Miniature electronic equipment. --- Electronic equipment, Miniature --- Microminiaturization (Electronics) --- Miniaturization (Electronics) --- Subminiature electronic equipment --- Subminiaturization (Electronics) --- Electronic apparatus and appliances --- Microelectronics --- Manipulation, Laser (Nuclear physics) --- Nuclear physics
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This graduate textbook introduces the com-putational techniques to study ultra-fast quantum dynamics of matter exposed to strong laser fields. Coverage includes methods to propagate wavefunctions according to the time dependent Schrödinger, Klein-Gordon or Dirac equation, the calculation of typical observables, time-dependent density functional theory, multi configurational time-dependent Hartree-Fock, time-dependent configuration interaction singles, the strong-field approximation, and the microscopic particle-in-cell approach. Contents How to propagate a wavefunction? Calculation of typical strong-field observables Time-dependent relativistic wave equations: Numerics of the Dirac and the Klein-Gordon equation Time-dependent density functional theory The multiconfiguration time-dependent Hartree-Fock method Time-dependent configuration interaction singles Strong-field approximation and quantum orbits Microscopic particle-in-cell approach
Quantum optics. --- Quantum theory. --- Laser manipulation (Nuclear physics) --- High power lasers. --- Lasers --- Manipulation, Laser (Nuclear physics) --- Nuclear physics --- Quantum dynamics --- Quantum mechanics --- Quantum physics --- Physics --- Mechanics --- Thermodynamics --- Optics --- Photons --- Quantum theory
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Laser cooling of atoms provides an ideal case study for the application of Lévy statistics in a privileged situation where the statistical model can be derived from first principles. This book demonstrates how the most efficient laser cooling techniques can be simply and quantitatively understood in terms of non-ergodic random processes dominated by a few rare events. Lévy statistics are now recognised as the proper tool for analysing many different problems for which standard Gaussian statistics are inadequate. Laser cooling provides a simple example of how Lévy statistics can yield analytic predictions that can be compared to other theoretical approaches and experimental results. The authors of this book are world leaders in the fields of laser cooling and light-atom interactions, and are renowned for their clear presentation. This book will therefore hold much interest for graduate students and researchers in the fields of atomic physics, quantum optics, and statistical physics.
Laser manipulation (Nuclear physics) --- Laser cooling. --- Atoms --- Lévy processes. --- Random walks (Mathematics) --- Chemistry, Physical and theoretical --- Matter --- Stereochemistry --- Cooling --- Manipulation, Laser (Nuclear physics) --- Nuclear physics --- Cooling. --- Constitution --- Optics. Quantum optics --- Atomic physics --- Levy processes.
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Lasers in chemistry --- Laser manipulation (Nuclear physics) --- Molecular dynamics --- Lasers en chimie --- Manipulation par laser (Physique nucléaire) --- Dynamique moléculaire --- Congresses. --- Congresses. --- Congrès --- Congrès --- Congrès
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Work with individual atoms and molecules aims to demonstrate that miniaturized electronic, optical, magnetic, and mechanical devices can operate ultimately even at the level of a single atom or molecule. As such, atomic and molecular manipulation has played an emblematic role in the development of the field of nanoscience. New methods based on the use of the scanning tunnelling microscope (STM) have been developed to characterize and manipulate all the degrees of freedom of individual atoms and molecules with an unprecedented precision. In the meantime, new concepts have emerged to design m
Atomic force microscopy -- Industrial applications. --- Laser manipulation (Nuclear physics). --- Molecular dynamics. --- Nanoelectromechanical systems. --- Nanotechnology -- Research. --- Scanning tunneling microscopy. --- SCIENCE / Chemistry / Industrial & Technical. --- SCIENCE / Solid State Physics. --- TECHNOLOGY & ENGINEERING / Material Science. --- Nanoelectromechanical systems --- Scanning tunneling microscopy --- Laser manipulation (Nuclear physics) --- Physics --- Physical Sciences & Mathematics --- Atomic Physics --- Atomic structure. --- Molecular structure. --- Nanoscience. --- Nanotechnology. --- Structure, Atomic --- Atomic theory --- Molecular technology --- Nanoscale technology --- High technology --- Nano science --- Nanoscale science --- Nanosciences --- Science --- Dynamics, Molecular --- Dynamics --- Structure, Molecular --- Chemical structure --- Structural bioinformatics
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