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Magnetic resonance quantum theory

As the foundation of quantum statistical mechanics, the theory of open quantum systems has remained an active topic of research since about the middle of the last century [1-40]. Its development has involved scientists working in fields as diversified as nuclear magnetic resonance, quantum optics and nonlinear spectroscopy, solid-state physics, material science, chemical physics, biophysics, and quantum information. The key quantity in quantum dissipation theory (QDT) is the reduced system density operator, defined formally as the partial trace of the total composite density operator over the stochastic surroundings (bath) degrees of freedom. [Pg.9]

Atomic Physics Atomic Spectrometry Chemical Kinetics, Experimentation Nuclear Magnetic Resonance Perturbation Theory Quantum Mechanics... [Pg.133]

A systematic development of relativistic molecular Hamiltonians and various non-relativistic approximations are presented. Our starting point is the Dirac one-fermion Hamiltonian in the presence of an external electromagnetic field. The problems associated with generalizing Dirac s one-fermion theory smoothly to more than one fermion are discussed. The description of many-fermion systems within the framework of quantum electrodynamics (QED) will lead to Hamiltonians which do not suffer from the problems associated with the direct extension of Dirac s one-fermion theory to many-fermion system. An exhaustive discussion of the recent QED developments in the relevant area is not presented, except for cursory remarks for completeness. The non-relativistic form (NRF) of the many-electron relativistic Hamiltonian is developed as the working Hamiltonian. It is used to extract operators for the observables, which represent the response of a molecule to an external electromagnetic radiation field. In this study, our focus is mainly on the operators which eventually were used to calculate the nuclear magnetic resonance (NMR) chemical shifts and indirect nuclear spin-spin coupling constants. [Pg.435]

Memory, J. D. (1968). Quantum Theory of Magnetic Resonance Parameters. McGraw-Hill, New York. [Pg.174]

Abbreviations MD, molecular dynamics TST, transition state theory EM, energy minimization MSD, mean square displacement PFG-NMR, pulsed field gradient nuclear magnetic resonance VAF, velocity autocorrelation function RDF, radial distribution function MEP, minimum energy path MC, Monte Carlo GC-MC, grand canonical Monte Carlo CB-MC, configurational-bias Monte Carlo MM, molecular mechanics QM, quantum mechanics FLF, Hartree-Fock DFT, density functional theory BSSE, basis set superposition error DME, dimethyl ether MTG, methanol to gasoline. [Pg.1]

Spin does not appear in the Schrodinger treatment, and essentially has to be postulated. There are more sophisticated versions of quantum theory where electron spin appears naturally, and where the magnetic dipole appears with the correct magnitude. I want to spend time discussing electron spin in more detail, before moving to the topic of electron spin resonance. [Pg.305]

A recent book on physical chemistry,5 written by a scientist6 and aimed primarily at other scientists, contains substantial historical information on the beginnings of physical chemistry and on various topics, such as chemical spectroscopy, electrochemistry, chemical kinetics, colloid and surface chemistry, and quantum chemistry. The book also discusses more general topics, such as the development of the physical sciences and the role of scientific journals in scientific communication. The same author has written a brief account of the development of physical chemistry after 1937,7 emphasizing the application of quantum theory and the invention of new experimental methods stopped-flow techniques (1940), nuclear magnetic resonance... [Pg.135]

As already pointed out, terms such as wave function, electron orbit, resonance, etc., with which we describe the formulations and results of wave mechanics, are borrowed from classical mechanics of matter in which concepts occur which, in certain respects at least, show a correspondence to the wave mechanical concepts in question. The same is the case with the electron spin. In Bohr s quantum theory, Uhlenbeck and Goudsmit s hypothesis meant the introduction of a fourth quantum number j, which can only take on the values +1/2 and —1/2- In wave mechanics it means that the total wave function, besides the orbital function, contains another factor, the spin function. This spin function can be represented by a or (3, whereby, for example, a describes the state j = +1/2 and P that with s = —1/2. The correspondence with the mechanical analogy, the top, from which the name spin has been borrowed, is appropriate in so far that the laevo and dextro rotatory character, or the pointing of the top in the + or — direction, can be connected with it. A magnetic moment and a... [Pg.144]

March Advanced Organic Chemistry Reactions, Mechanisms, and Structure Memory Quantum Theory of Magnetic Resonance Parameters Pitzer and Brewer (Revision of Lewis and Randall) Thermodynamics Plowman Enzyme Kinetics... [Pg.612]

See other pages where Magnetic resonance quantum theory is mentioned: [Pg.576]    [Pg.6]    [Pg.198]    [Pg.135]    [Pg.236]    [Pg.527]    [Pg.214]    [Pg.331]    [Pg.235]    [Pg.1621]    [Pg.515]    [Pg.254]    [Pg.142]    [Pg.3]    [Pg.3588]    [Pg.331]    [Pg.112]    [Pg.37]    [Pg.825]    [Pg.66]    [Pg.94]    [Pg.18]    [Pg.122]    [Pg.195]    [Pg.523]    [Pg.251]    [Pg.136]    [Pg.152]    [Pg.66]    [Pg.955]    [Pg.183]    [Pg.3587]   


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