| Preface |
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vii | |
| Introduction |
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ix | |
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1 | (40) |
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1.1 The Generalized Coordinates |
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1 | (4) |
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1.2 Quantization of an Electromagnetic Field |
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5 | (2) |
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1.3 Schrodinger's Equation for a Light Quantum |
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7 | (3) |
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1.4 Solving the Schrodinger's Equation for a Light Quantum |
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10 | (6) |
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16 | (1) |
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1.6 Normalization and Length of a Photon |
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17 | (2) |
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1.7 The Operator Form of the Schrodinger's Equation for a Light Quantum |
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19 | (2) |
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1.8 Photon in a Constant Homogeneous Gravitational Field |
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21 | (12) |
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1.9 Radiation of a Photon |
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33 | (3) |
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1.10 Transition of a Photon from One Medium to Another Medium |
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36 | (5) |
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Chapter 2 Elementary Particles: Reason for the Quarks Confinement in the Yang-Mills Field |
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41 | (14) |
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41 | (1) |
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2.2 The Yang-Mills Field Equations |
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42 | (5) |
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2.3 Solutions of the Yang-Mills Field Equations |
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47 | (8) |
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Chapter 3 Polarizing and Quantum Effects in Malus Law |
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55 | (64) |
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3.1 Polarization of Light |
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55 | (2) |
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3.2 Malus Law. The Classical Approach |
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57 | (9) |
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3.3 The Quantum-Relativistic Form of Malus Law |
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66 | (53) |
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Chapter 4 Annihilation: Positron-Emission Tomography |
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119 | (26) |
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4.1 Differential Effective Section a Positron and Electron in the Photon's Annihilation |
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119 | (13) |
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4.2 Angular and Power Distributions of the Annihilative Radiations |
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132 | (3) |
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4.3 The Reasons for an Angular and Power Distribution of the Annihilative Radiations |
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135 | (5) |
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4.4 Application of Annihilative Radiation in Positron-Emission Tomography |
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140 | (5) |
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Chapter 5 Braking Radiation |
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145 | (36) |
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5.1 The Analysis of Braking Radiation's Occurrence at the Movement of an Electron in a Substance. The Non-Relativistic Variant |
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146 | (11) |
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5.2 The Relativistic Analysis of a Threshold Process of the Electron's Braking in a Metal |
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157 | (5) |
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5.3 The Analysis of the Braking Radiation's Occurrence at the Movement of an Electron in a Substance. The Relativistic Variant |
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162 | (16) |
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5.4 Braking Radiation of the Electrons in an Electric Field of an Easy Nucleus |
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178 | (3) |
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Chapter 6 Optical Activity |
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181 | (42) |
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6.1 The Phenomenological Theory of Optical Activity |
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181 | (3) |
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6.2 Electrodynamics of Optical Activity |
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184 | (6) |
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6.3 The Classical Molecular Theory of Optical Activity |
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190 | (3) |
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6.4 Quantum Theory of Optical Activity: The Non-Relativistic Variant |
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193 | (13) |
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6.5 Spectral Dependences of an Optical Rotation and a Circular Dichroism |
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206 | (7) |
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6.6 Quantum Theory of an Optical Activity. The Relativistic Variant |
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213 | (10) |
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Chapter 7 Interaction of the Electromagnetic Field and a Spin: Magnetic-Resonant Tomography |
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223 | (16) |
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7.1 Magnetic-Resonant Tomography |
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224 | (3) |
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7.2 Quantum-Mechanical Analysis of the MRT-Signal Occurrence |
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227 | (12) |
| Conclusion |
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239 | (2) |
| References |
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241 | (4) |
| Author's Contact Information |
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245 | (2) |
| Index |
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247 | |
