Basic Theory of Electromagnetic Scattering | p. 1 |
Maxwell's Equations and Constitutive Relations | p. 1 |
Incident Field | p. 9 |
Polarization | p. 9 |
Vector Spherical Wave Expansion | p. 15 |
Internal Field | p. 21 |
Anisotropic Media | p. 22 |
Chiral Media | p. 30 |
Scattered Field | p. 33 |
Stratton-Chu Formulas | p. 34 |
Far-Field Pattern and Amplitude Matrix | p. 40 |
Phase and Extinction Matrices | p. 44 |
Extinction, Scattering and Absorption Cross-Sections | p. 48 |
Optical Theorem | p. 53 |
Reciprocity | p. 54 |
Transition Matrix | p. 57 |
Definition | p. 58 |
Unitarity and Symmetry | p. 61 |
...>Randomly Oriented Particles | p. 66 |
Null-Field Method | p. 83 |
Homogeneous and Isotropic Particles | p. 84 |
General Formulation | p. 85 |
Instability | p. 89 |
Symmetries of the Transition Matrix | p. 93 |
Practical Considerations | p. 95 |
Surface Integral Equation Method | p. 97 |
Spherical Particles | p. 99 |
Homogeneous and Chiral Particles | p. 102 |
Homogeneous and Anisotropic Particles | p. 104 |
Inhomogeneous Particles | p. 105 |
Formulation with Addition Theorem | p. 106 |
Formulation without Addition Theorem | p. 112 |
Layered Particles | p. 115 |
General Formulation | p. 115 |
Practical Formulation | p. 118 |
Formulation with Discrete Sources | p. 120 |
Concentrically Layered Spheres | p. 122 |
Multiple Particles | p. 124 |
General Formulation | p. 124 |
Formulation for a System with N Particles | p. 131 |
Superposition T-matrix Method | p. 132 |
Formulation with Phase Shift Terms | p. 136 |
Recursive Aggregate T-matrix Algorithm | p. 137 |
Composite Particles | p. 139 |
General Formulation | p. 139 |
Formulation for a Particle with N Constituents | p. 143 |
Formulation with Discrete Sources | p. 145 |
Complex Particles | p. 146 |
Effective Medium Model | p. 148 |
T-matrix Formulation | p. 150 |
Generalized Lorentz-Lorenz Law | p. 159 |
Generalized Ewald-Oseen Extinction Theorem | p. 161 |
Pair Distribution Functions | p. 162 |
Particle on or near an Infinite Surface | p. 164 |
Particle on or near a Plane Surface | p. 164 |
Particle on or near an Arbitrary Surface | p. 173 |
Simulation Results | p. 183 |
T-matrix Program | p. 183 |
Complete Uniform Distribution Function | p. 185 |
Incomplete Uniform Distribution Function | p. 186 |
Electromagnetics Programs | p. 188 |
T-matrix Programs | p. 188 |
MMP Program | p. 189 |
DDSCAT Program | p. 192 |
CST Microwave Studio Program | p. 198 |
Homogeneous, Axisymmetric and Nonaxisymmetric Particles | p. 201 |
Axisymmetric Particles | p. 201 |
Nonaxisymmetric Particles | p. 212 |
Triangular Surface Patch Model | p. 216 |
Inhomogeneous Particles | p. 221 |
Layered Particles | p. 225 |
Multiple Particles | p. 230 |
Composite Particles | p. 238 |
Complex Particles | p. 242 |
Particle on or Near a Plane Surface | p. 245 |
Effective Medium Model | p. 246 |
Spherical Functions | p. 253 |
Spherical Bessel Functions | p. 254 |
Legendre Functions | p. 256 |
Wave Functions | p. 261 |
Scalar Wave Functions | p. 261 |
Vector Wave Functions | p. 265 |
Rotations | p. 270 |
Translations | p. 276 |
Computational Aspects in Effective Medium Theory | p. 289 |
Computation of the Integral I[Characters not reproducible] | p. 289 |
Computation of the Integral I[Characters not reproducible] | p. 292 |
Computation of the Terms S[Characters not reproducible] and S[Characters not reproducible] | p. 293 |
Completeness of Vector Spherical Wave Functions | p. 295 |
References | p. 303 |
Index | p. 317 |
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