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General Outline for Short Course on “Spin” I. Basic Physics Angular Momentum Vector Representation Magnetism Units Quantum aspects of spin Spin Hamiltonian/Operators/Basis functions Transition probabilities Two-level problem Level-crossing II. Magnetic Resonance Classical version Bloch equations Quantum version Density matrices/Heisenberg representation NMR Parameters Relaxation mechanisms Pulsed methods EPR Parameters Relaxation mechanisms Pulsed methods Double resonance DNP Overhauser Effect Cross-relaxation/Relaxivity Solid state and gas phase MR EPR of 1O2 NMR of H2 and D2 gas EPR of trapped radicals/triplets 1 III. Spin-dependent Chemistry and Physics Radical pairs CIDNP/CIDEP S-T mixing and photochemistry Radical-3O2 interactions CIDEP 1 O2 quenching oH2-pH2 conversion Effects of external fields Static Time-dependent FDMR/RYDMR Magnetic isotope effects IV. What do you want to learn from the course? Summary of topics about spin Explanation of theoretical and experimental aspects of spin Origin of NMR and EPR parameters Spectra-structure correlations BPP theory of relaxation Redfield/Bloch/Hubbard/Freed theories of relaxation Formulation of multiple-pulse methods Qualitative models for spin phenomena Vector models Energy level diagrams Quantitative analysis and modeling of spin phenomena Extraction of structure and dynamics from relaxation data Modeling of CIDNP and CIDEP spectra Simulation of powder and single-crystal spectra RGL-Oct 2008 2