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200 1 $aAppunti di antropologia$fAngelo De Blasio
205   $a5. ed.
210   $aNapoli$cF. Lubrano$d1920
215   $a262 p.$d24 cm
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101 0 $aeng
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181   $2rdacontent
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200 00$aAdvances in chemical physics$hVolume 161 /$fedited by Stuart A. Rice and Aaron R. Dinner
210  1$aHoboken, New Jersey :$cWiley,$d2016.
210  4$dİ2016
215   $a1 online resource (577 p.)
225 1 $aAdvances in Chemical Physics ;$vVolume 161
300   $aDescription based upon print version of record.
311   $a1-119-29094-5 
320   $aIncludes bibliographical references at the end of each chapters and index.
327   $aTitle Page ; Copyright Page ; Contents ; Contributors to Volume 161 ; Preface to the Series ; Chapter 1 Structural Analysis by X-ray Intensity Angular Cross Correlations  ; I. Introduction ; II. Theory ; A. Scattering from a Disordered System of Reproducible Particles ; B. 2D Disordered Systems ; 1. Dilute Systems ; 2. Dense Systems ; C. 3D Disordered Systems ; D. Two- and Three-Point Angular CCFs and Their Fourier Decomposition ; 1. General Definitions ; 2. Analysis of Disordered Systems by Angular CCFs ; III. Applications ; A. Single-Particle Structure Recovery from FXS
327   $a1. 2D Structure Determination 2. 3D Structure Determination ; B. Correlations in Disordered and Partially Ordered Phases ; 1. Local Structure of Colloidal Systems ; 2. BO Order in Liquid Crystals ; 3. Structural Inhomogeneities in Semicrystalline Polymers ; 4. Short-Range and Medium-Range Order in Metallic Glasses ; 5. Emergent Rotational Symmetries and Domain Memory in Magnetic Multilayers ; IV. Conclusions and Outlook ; Acknowledgments ; References ; Chapter 2 Spin Relaxation in Phase Space  ; I. Introduction
327   $aII. Density Matrix and Phase Space Formulations of Relaxation Phenomena in Spin Systems A. Density Matrix Formulation of Spin Relaxation and Resonance ; 1. General Equations ; 2. Collision Kernel in the Markovian Approximation ; 3. Time-dependent Hamiltonian ; 4. Method of Statistical Moments ; B. Quasiprobability Distribution Functions for Particles ; 1. The Wigner Distribution Function for Particles ; 2. Application to Transition-State Theory ; 3. Application to Quantum Brownian Motion ; C. Quasiprobability Distribution Functions for Spins ; 1. Spin Phase-Space Distribution Functions
327   $a2. Weyl Symbols of Some Spin Operators 3. Master Equation and Statistical Moment Equations for Spin Relaxation in Phase Space  ; D. Equilibrium Phase Space Distribution Functions for Spins ; 1. Spins in a Uniform External Field ; 2. Uniaxial Nanomagnet in an External Field ; 3. Uniaxial Nanomagnet in a Transverse Field ; 4. Biaxial Anisotropy ; 5. Cubic Anisotropy ; 6. TST Reversal Time ; 7. Switching Field Curves ; 8. Discussion ; III. Master Equation in Phase Space for Axially Symmetric Systems ; A. Master Equation for a Uniaxial Nanomagnet Subjected to a dc Magnetic Field
327   $a1. Explicit Form of the Master Equation 2. Differential Recurrence Relations for the Statistical Moments ; B. Spin Relaxation in a dc Magnetic Field ; 1. Basic Equations ; 2. Quantum Analog of the Magnetic Langevin Equation ; 3. Exact Solution of the Master Equation for Longitudinal Relaxation ; 4. Nonlinear Longitudinal Relaxation Time ; 5. Linear Response ; 6. Single-Mode Approximation ; C. Longitudinal Relaxation of Uniaxial Nanomagnets ; 1. Calculation of the Observables ; 2. Analytic Equations for the Characteristic Relaxation Timesand Dynamic Susceptibility
327   $a3. Nonlinear Longitudinal Relaxation in Superimposed ac and dc Magnetic Fields
410  0$aAdvances in chemical physics ;$vVolume 161.
606   $aChemistry, Physical and theoretical
606   $aSpintronics
606   $aPhotochemistry$xResearch
608   $aElectronic books.
615  0$aChemistry, Physical and theoretical.
615  0$aSpintronics.
615  0$aPhotochemistry$xResearch.
676   $a541
702   $aRice$b Stuart A.
702   $aDinner$b Aaron R.
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801  2$bMiAaPQ
906   $aBOOK
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