论文信息 - Scattering from arbitrarily shaped particles: theory and experiment.

Scattering from arbitrarily shaped particles: theory and experiment.

A numerical implementation of the volume integral equation formulation of electromagnetic scattering is used to calculate the scattered intensity of various particles. The numerical method has the capability of determining the scattering by arbitrarily shaped and inhomogeneous scatterers. Results of calculations are presented for scatterers which have not only a size comparable to the wavelength of the incident radiation but are also irregular and inhomogeneous. The theoretical results are compared to microwave analog measurements performed at the microwave facility of the Space Astronomy Laboratory (ISST). It is found that experiment and theory agree well. The accuracy and versatility of the numerical method and the analog measurements are illustrated. Finally, the advantages and disadvantages of the numerical method are discussed.

[1] J. M. Greenberg,et al. From interstellar dust to comets - A unification of observational constraints , 1990 .

[2] Raj Mittra,et al. Method of conjugate gradients for the numerical solution of large-body electromagnetic scattering problems , 1985 .

[3] S. O'Brien,et al. Scattering by irregular inhomogeneous particles via the digitized Green's function algorithm. , 1988, Applied optics.

[4] J. Van Bladel,et al. Some remarks on green's dyadic for infinite space , 1961 .

[5] A. Yaghjian. Electric dyadic Green's functions in the source region , 1980 .

[6] J. M. Greenberg,et al. A model for the optical properties of porous grains , 1990 .

[7] J. Greenberg,et al. Microwave Analog to the Scattering of Light by Nonspherical Particles , 1961 .

[8] P. M. Berg. Iterative computational techniques in scattering based upon the integrated square error criterion , 1984 .

[9] H. Y. Chen,et al. Optical scattering and absorption by branched chains of aerosols. , 1989, Applied optics.

[10] Kun-mu Chen,et al. Electromagnetic Fields Induced Inside Arbitrarily Shaped Biological Bodies , 1974 .

[11] B. R. Johnson. Invariant imbedding T matrix approach to electromagnetic scattering. , 1988, Applied optics.

[12] B. Gustafson,et al. A Comet Fragment Model for Zodiacal Light Particles , 1979 .