| |
T a b l e o f
c o n t e n t s : |
| 1 |
SPHERICAL HOMOGENEOUS PARTICLES |
| 1.1 |
General works on light scattering. History |
| 1.1.1 |
General works on light scattering. Reviews |
| 1.1.2 |
History |
| 1.1.3 |
Old works (before 1950) |
| 1.2 |
Mie theory. Methodology |
| 1.2.1 |
Bessel functions |
| 1.2.2 |
Angular functions and their modifications |
| 1.2.3 |
Other methodological questions |
| 1.2.4 |
Integrals over Bessel and Legendre functions |
| 1.3 |
Mie theory. Calculations |
| 1.3.0 |
Calculations by Mie theory (single particle). Old papers |
| 1.3.1 |
Phase function asymmetry and scattering in solid angles |
| 1.4 |
Mie theory calculations for polydispersity |
| 1.5.0 |
Resonances in sphere |
| 1.5.0 |
Plane wave |
| 1.5.1 |
Beam |
| 1.5.2 |
Particles on substrate or fiber |
| 1.6 |
Asymptotic expressions for large particles |
| 1.7 |
Internal field and absorption of homogeneous sphere |
| 1.7.0 |
Internal field |
| 1.7.1 |
Absorption |
| 1.7.2 |
Absorption in selected region of sphere |
| 1.7.3 |
Internal and near field under beam irradiation |
| 1.7.4 |
Internal field in geometrical optics |
| 1.7.5 |
Angle-averaged internal field |
| 1.7.6 |
Description of absorption by plasmons, polaritrons, etc |
| 1.8 |
Near field of sphere |
| 1.9 |
Particles (not only spheres) of active materials |
| 1_10 |
Perfectly reflecting spheres |
| 1_11 |
Some mathematics |
| 1_11.0 |
Addition theorems |
| 1_11.1 |
Stokes vector. Mueller matrices for any particles |
| 1_12 |
Emissivity of particles (except for C) |
| 1_13 |
Integral formulation of scattering theory |
| 1_14 |
Propagation of EM waves in media |
| 1_14.1 |
Anisotropic, bianisotropic, chiral media |
| 1_14.2 |
Inhomogeneous media |
| 2 |
INHOMOGENEOUS SPHERES |
| 2.1 |
Core-mantle and multilayered spheres |
| 2.1.0 |
Calculations by exact theory (core-mantle) |
| 2.1.1 |
Multilayered sphere |
| 2.1.2 |
Methodology of calculation |
| 2.2 |
Sphere with smooth radial inhomogeneity |
| 2.3 |
Internal field and absorption in inhomogeneous sphere |
| 2.4 |
Morphological resonance for inhomogeneous sphere |
| 2.5 |
Sphere with chaotic internal inhomogeneity |
| 2.6 |
Rayleigh and RGD approximations for inhomogeneous sphere |
| 2.7 |
van de Hulst approximation for inhomogeneous sphere |
| 2.8 |
Sphere with nonconcentric core and inclusions |
| 2.9 |
Geometrical optics approximation for inhomogeneous sphere |
| 3 |
APPROXIMATIONS FOR HOMOGENEOUS SPHERES |
| 3.1 |
Geometrical optics approximation |
| 3.1.0 |
GO approximation and calculations for large spheres |
| 3.1.1 |
Kirchhoff diffraction |
| 3.2 |
Rayleigh and RGD approximations for homogeneous sphere |
| 3.3 |
van de Hulst approximation for homogeneous sphere |
| 3.4 |
Debye resonance |
| 3.5 |
Shifrin method for sphere |
| 3.6 |
Plasma resonance |
| 3.7 |
Eikonal approximation for sphere |
| 4 |
COMPLICATED PROBLEMS |
| 4.1 |
Sphere in absorbing medium. Evanescent wave |
| 4.2 |
Beam scattering |
| 4.2.1 |
Sphere |
| 4.2.2 |
Cylinder |
| 4.2.3 |
Spheroid and other forms |
| 4.2.4 |
Particle aggregate |
| 4.3 |
Scattering of impulse by particle |
| 4.4 |
Scattering by charged sphere and particle charging |
| 4.5 |
Scattering by rough particle |
| 4.6 |
Scattering by spatially dispersive sphere |
| 4.7 |
Scattering by anisotropic and chiral particles |
| 4.7.0 |
Anisotropic particles (not only spheres) |
| 4.7.1 |
Spherulites, crystallites |
| 4.7.2 |
Gyrotropic and chiral particles |
| 4.7.3 |
Liquid crystals |
| 4.7.4 |
RGD and AD for anisotropic particles |
| 4.7.5 |
Anisotropic ferrite particles |
| 4.7.6 |
Particle in anisotropic medium |
| 4.8 |
Some problems of diffraction theory |
| 4.9 |
Magnetic particles |
| 4_10 |
Scattering by optically nonlinear objects |
| 4_11 |
Scattering by particles on and near a surface |
| 4_11.1 |
Sphere |
| 4_11.2 |
Cylinder |
| 4_11.3 |
Other forms |
| 4_12 |
Scattering of several waves by a particle |
| 4_13 |
Moving particle |
| 5 |
CYLINDRICAL PARTICLES |
| 5.1 |
Circular infinite cylinder (normal incidence) |
| 5.2 |
Oblique incidence and orientation averaging |
| 5.3 |
Multilayered cylinders |
| 5.4 |
GO approximation for cylinders (incl. hexagonal ones) |
| 5.5 |
Cylinders with smooth radial inhomogeneity |
| 5.6 |
Gyrotropic, gyroelectric, anisotropic cylinders |
| 5.7 |
Internal and near fields of cylinder |
| 5.8 |
Experiments on cylinders |
| 5.9 |
Morphological resonances in cylinders |
| 5_10 |
Miscellaneous (including array) |
| 5_11 |
van de Hulst approximation for cylinders |
| 5_12 |
Rayleigh and RGD approximations for cylinders |
| 5_13 |
Noncircular infinite cylinders |
| 5_14 |
Circular cylinder of finite length and discs |
| 5_15 |
S-approximation (Perelman) and Hart-Montroll one for cylinders |
| 6 |
NONSPHERICAL OBJECTS |
| 6.0 |
Reviews and special issues |
| 6.1 |
T-matrix method |
| 6.1.0 |
T-matrix method in general |
| 6.1.1 |
T-matrix method for complex objects |
| 6.1.2 |
Orientation averaging and polydispersions |
| 6.1.3 |
Modifications of T-matrix method |
| 6.2 |
Separation of variables method (SVM) |
| 6.2.0 |
SVM for single spheroid |
| 6.2.1 |
SVM for complex objects |
| 6.2.2 |
Spheroidal functions |
| 6.3 |
Integral equation method (Usunoglu, Weil et al.) |
| 6.4 |
Point matching method (PMT, GPMT) |
| 6.5 |
Perturbation method |
| 6.6 |
DDA method (in wide sense) |
| 6.7 |
Some numerical methods |
| 6.7.0 |
Method of moments (MoM) and finite element method |
| 6.7.1 |
FDTD and FDFD methods |
| 6.7.2 |
Discretized Mie-formalism (DMF) |
| 6.7.3 |
Generalized multipole technique (GMT, MMP) |
| 6.7.4 |
Method of equivalent discrete sources |
| 6.7.5 |
Current filament method |
| 6.8 |
Other numerical methods |
| 6.9 |
Eyges, Nelson works and similar ones |
| 6_10 |
Chylek method |
| 6_11 |
GO approximation for nonspherical particles (except for cylinders) |
| 6_12 |
Rayleigh and RGD approximations for nonspherical particles |
| 6_13 |
Khlebtsov works |
| 6_14 |
Multiple scattering by nonspherical particles |
| 6_15 |
Stevenson method |
| 6_16 |
Experiments on nonspherical particles |
| 6_17 |
Some Russian works |
| 6_18 |
Miscellaneous |
| 6_19 |
Interaction with nonspherical particles |
| 6_19.0 |
Internal and near fields of nonspherical particles |
| 6_19.1 |
Morphological resonances in nonspherical objects |
| 6_20 |
Shifrin method for nonspherical objects |
| 6_21 |
Dyadic Green function (common works) |
| 6_22 |
van de Hulst approximation for nonspherical particles |
| 6_23 |
Inverse problems for nonspherical particles |
| 6_24 |
Scattering by several spheroids (theory) |
| 6_25 |
Nonspherical particle of random irregular shape |
| 6_26 |
Rayleigh hypothesis |
| 6_27 |
Perelman (S) and Hart-Montroll approximations |
| 6_28 |
WKB approximation |
| 6_29 |
Chew works |
| 7 |
SPECIFIC SCATTERING MEDIA |
| 7.1 |
Pigments |
| 7.2 |
Interstellar grains |
| 7.2.0 |
Composition |
| 7.2.1 |
Reviews, proceedings, etc |
| 7.2.2 |
Alignment of particles |
| 7.2.3 |
Polarization |
| 7.2.4 |
Scattering by particles |
| 7.2.5 |
Thermal effects and emission |
| 7.2.6 |
Optical constants |
| 7.2.7 |
Clusters and aggregates |
| 7.2.8 |
Radiation pressure on particles |
| 7.2.9 |
Laboratory investigations |
| 7.3 |
Marine particles |
| 7.4 |
Bubbles in water and glass |
| 7.5 |
Photolayers |
| 7.6 |
Clouds of Venus, Jupiter, etc |
| 7.7 |
Industrial exhausts |
| 7.8 |
Microbioobjects (laboratory) |
| 7.9 |
Macrobioobjects |
| 7_10 |
Oil-water emulsions |
| 7_11 |
Metallic zoles |
| 7_11.0 |
Metallic zoles in general |
| 7_11.1 |
Size effect in metallic particles |
| 7_11.2 |
Anomalous absorption in far IR |
| 7_11.3 |
Surface plasmon in metallic particles |
| 7_11.4 |
Colour of metallic zoles |
| 7_11.5 |
Silver |
| 7_11.6 |
Nonlinear effects |
| 7_11.7 |
Metallic nanoparticles |
| 7_12 |
Holograms |
| 7_13 |
Rough surfaces |
| 7_14 |
Combustion products (oxides of Al, Mg, etc) |
| 7_15 |
Powders |
| 7_16 |
Plasma objects |
| 7_17 |
Vegetation |
| 7_18 |
Volcanic ash |
| 8 |
CARBON |
| 8.1.1 |
Optical constants of C |
| 8.1.2 |
General information on carbon particles (size, etc) |
| 8.2 |
Scattering and extinction by C particles |
| 8.3 |
Interaction with C particles (combustion, breakdown, etc) |
| 8.4 |
Emissivity of C particles |
| 8.5 |
Soot in atmosphere, smokes, nuclear winter |
| 8.6 |
Slurry |
| 8.7 |
Fuel droplets |
| 9 |
ICE |
| 9.1 |
General information |
| 9.1.1 |
Optical, thermical and mechanical constants of ice |
| 9.1.2 |
Ice in atmosphere (not optics) |
| 9.2 |
Scattering by ice particles and crystals in general |
| 9.3 |
Halo, rainbow and other optical effects |
| 9.4 |
Snow |
| 9.5 |
Interaction of radiation with ice crystals |
| A0 |
WATER |
| A0.1 |
Optical constants of water |
| A0.2 |
Scattering by water particles (including those in clouds) |
| A0.3 |
Scattering by precipitates in cm-, mm-, and radio domains |
| A0.4 |
Condensational growth of water droplets. Size distribution |
| A0.5 |
Surface layer of a raindrop |
| A1 |
AGGLOMERATES, FRACTALS |
| A1.1 |
Scattering by two spheres and ensemble of spheres |
| A1.2 |
Scattering by agglomerates |
| A1.2.1 |
Common works on fractals |
| A1.2.2 |
Scattering by agglomerates, fractals, clusters |
| A1.2.3 |
Metallic clusters |
| A1.2.4 |
Carbon clusters |
| A1.3 |
MG and effective medium theories |
| A1.4 |
Cooperative effects. Close-packed particles |
| A1.5 |
Slab of random particles (weak localization, etc) |
| A1.6 |
Ordered structures (microlitography, particles on substrat.) |
| A1.7 |
Twersky works |
| A1.8 |
Films |
| A2 |
NONLINEAR AND MECHANICAL EFFECTS IN AEROSOLS |
| A2.0 |
Reviews on nonlinear phenomena |
| A2.1 |
Mechanical effects |
| A2.1.1 |
Levitation, trapping and radiation pressure |
| A2.1.2 |
Photophoresis |
| A2.1.3 |
Thermal elasticity |
| A2.2 |
Stimulated oscillations of particles and thermal modulation |
| A2.3 |
Photoelectron emission |
| A2.4 |
Raman-effect and luminescence |
| A2.5 |
SERS on surface of particles |
| A2.6 |
Aureole. Self-actions of beams |
| A2.7 |
Optical breakdown and plasma |
| A2.8 |
Laser spectral analysis of aerosols |
| A2.9 |
Laser effect on particles and order generation |
| A2_10 |
Optical bistability |
| A2_11 |
Measurement of particle temperature |
| A3 |
VAPORIZATION AND EXPLOSION OF PARTICLES (EXCEPT C AND ICE) |
| A3.1 |
General questions |
| A3.1.1 |
Thermal constants |
| A3.1.2 |
Grids. Mathematical questions |
| A3.2 |
Evaporation |
| A3.2.1 |
Single drop evaporation |
| A3.2.2 |
Channeling in evaporating medium |
| A3.3 |
Heating, evaporation of solid particles (except C, ice, metals) |
| A3.4 |
Heating and evaporation of nonspherical particles |
| A3.5 |
Heating and combustion of metallic particles |
| A3.6 |
Explosion of particles |
| A3.7 |
Thermal effects with core-mantle and layered particles |
| A4 |
ATMOSPHERIC AEROSOL |
| A4.1 |
Optical constants of atmospheric aerosol (except C) |
| A4.2 |
Scattering by atmospheric aerosol |
| A4.2.0 |
Scattering by atmospheric aerosol |
| A4.2.1 |
Relation of optical parameters with humidity |
| A4.2.2 |
Measurement of scattering matrix of atmospheric aerosol |
| A4.3 |
Stratospheric aerosol |
| A4.4 |
Aerosol influence on climate |
| A4.5 |
Physical processes in aerosol systems |
| A4.6 |
Size distributions |
| A5 |
OPTICAL CONSTANTS |
| A5.1 |
Common questions |
| A5.1.0 |
Experimental methods |
| A5.1.1 |
Reflection by absorbing media |
| A5.2 |
IR materials |
| A5.3 |
Minerals |
| A5.4 |
Quartz, silicon and its oxides |
| A5.5 |
Magnesium oxide |
| A5.6 |
Beryllium oxide |
| A5.7 |
Aluminium oxide |
| A5.8 |
Metals, their oxides and silicates |
| A5.8.1 |
Metals |
| A5.8.2 |
Oxides, silicates |
| A5.9 |
Optical constants in mm-domain |
| A5_10 |
Magnetic constants |
| A6 |
INVERSE PROBLEMS |
| A6.1 |
Regularization method |
| A6.2 |
Method of complete phase function |
| A6.3 |
Method of spectral turbidity |
| A6.4 |
Small-angle method |
| A6.5 |
Determination of particle sizes from scattering |
| A6.6 |
Determination of optical constants from scattering |
| A6.7 |
Determination of concentration |
| A6.8 |
Works of common interest |
| A6.9 |
Determination of particle size by Doppler technique |
| A7 |
LABORATORY EXPERIMENT |
| A7.1 |
Experimental equipment |
| A7.2 |
Experiments for single particle |
| A7.3 |
Synthesis of aerosols and zoles |
| A7.4 |
Methodology of laboratory experiment |
| A7.5 |
Particle counters |
| A7.6 |
Measurement of scattering matrix (not atmosphere) |
| A7.7 |
Dispersion filters |
| A7.8 |
Microwave experiment |
| A7.9 |
Microtargets for LTS |
| A7_10 |
LTS |
| A7_11 |
Biological effects of EM radiation (except lasers) |
| A7_12 |
Application of lasers in medicine and biology |
| A7_13 |
KRIO |
| A8 |
LASER REMOTE SENSING |
| A8.1 |
Theory of remote sensing in atmosphere |
| A8.2 |
Laser remote sensing (experiment) |
| A8.3 |
Remote sensing of aerosols over the ocean |
| A8.4 |
Scattering of solar radiation |
| A9 |
RADIATIVE TRANSFER |
| A9.1 |
Theory of radiative transfer |
| A9.2 |
Two- and many-flux methods (Kubelka-Munk) |
| A9.3 |
Speed of light in scattering media |
| B0 |
BOOKS, COLLECTIONS |
| B0.1 |
Books |
| B0.2 |
Collections and special issues |
| B0.3 |
Handbooks, tables |
| B0.4 |
Patents |
| B0.5 |
Dissertations |
| B0.6 |
Preprints |
| B0.7 |
Reports |