Discrete dipole approximation

Discrete dipole approximation
In discrete dipole approximation larger object is approximated in terms of discrete dipoles

The discrete dipole approximation (DDA) is a method for computing scattering of radiation by particles of arbitrary shape and by periodic structures. Given a target of arbitrary geometry, one seeks to calculate its scattering and absorption properties. Exact solutions to Maxwell's equations are known only for special geometries such as spheres, spheroids, or infinite cylinders, so approximate methods are in general required.

Contents

Basic concepts

The basic idea of the DDA was introduced in 1964 by DeVoe [1] who applied it to study the optical properties of molecular aggregates; retardation effects were not included, so DeVoe's treatment was limited to aggregates that were small compared with the wavelength. The DDA, including retardation effects, was proposed in 1973 by Purcell and Pennypacker [2] who used it to study interstellar dust grains. Simply stated, the DDA is an approximation of the continuum target by a finite array of polarizable points. The points acquire dipole moments in response to the local electric field. The dipoles of course interact with one another via their electric fields, so the DDA is also sometimes referred to as the coupled dipole approximation. [3] [4]

Nature provides the physical inspiration for the DDA: in 1909 Lorentz [5] showed that the dielectric properties of a substance could be directly related to the polarizabilities of the individual atoms of which it was composed, with a particularly simple and exact relationship, the Clausius-Mossotti (or Lorentz-Lorenz) relation, when the atoms are located on a cubic lattice. We may expect that, just as a continuum representation of a solid is appropriate on length scales that are large compared with the interatomic spacing, an array of polarizable points can accurately approximate the response of a continuum target on length scales that are large compared with the interdipole separation.

For a finite array of point dipoles the scattering problem may be solved exactly, so the only approximation that is present in the DDA is the replacement of the continuum target by an array of N-point dipoles. The replacement requires specification of both the geometry (location of the dipoles) and the dipole polarizabilities. For monochromatic incident waves the self-consistent solution for the oscillating dipole moments may be found; from these the absorption and scattering cross sections are computed. If DDA solutions are obtained for two independent polarizations of the incident wave, then the complete amplitude scattering matrix can be determined.

With the recognition that the polarizabilities may be tensors, the DDA can readily be applied to anisotropic materials. The extension of the DDA to treat materials with nonzero magnetic susceptibility is also straightforward, although for most applications magnetic effects are negligible.

Extensions

The method was improved by Draine, Flatau, and Goodman who applied Fast Fourier Transform and conjugate gradient method to calculate convolution problem arising in the DDA methodology which allowed to calculate scattering by large targets. They distributed discrete dipole approximation open source code DDSCAT. [6] [7] There are now several DDA implementations [8]. There are extensions to periodic targets [9] and light scattering problems on particles placed on surfaces. [10] Comparisons with exact technique were published.[11] The validity criteria of the discrete dipole approximation have been recently revised.[12] That work significantly extends the range of applicability of the DDA for the case of irregularly shaped particles.

Discrete Dipole Approximation Codes

Main article: Discrete dipole approximation codes

Gallery of shapes

  • Scattering by periodic structures such as slabs, grattings, of periodic cubes placed on a surface, can be solved in the discrete dipole approximation.

  • Scattering by infinite object (such as cylinder) can be solved in the discrete dipole approximation.

Notes and references

  1. ^ H. DeVoe, Optical properties of molecular aggregates. I. Classical model of electronic absorption and refraction, J. Chem. Phys. 41, 393-400 (1964).
  2. ^ E. M. Purcell and C. R. Pennypacker (1973). "Scattering and absorption of light by nonspherical dielectric grains". Astrophysical Journal 186: 705. Bibcode 1973ApJ...186..705P. doi:10.1086/152538. 
  3. ^ S. B. Singham and G. C. Salzman, Evaluation of the scattering matrix of an arbitrary particle using the coupled dipole approximation, J. Chem. Phys. 84, 2658-2667(1986).
  4. ^ S. B. Singham and C. F. Bohren, Light scattering by an arbitrary particle: a physical reformulation of the coupled dipoles method, Opt. Lett. 12, 10-12 (1987).
  5. ^ H. A. Lorentz, Theory of Electrons (Teubner, Leipzig, 1909)
  6. ^ Draine, B.T., and P.J. Flatau (1994). "Discrete dipole approximation for scattering calculations". J. Opt. Soc. Am. A 11: 1491–1499. Bibcode 1994JOSAA..11.1491D. doi:10.1364/JOSAA.11.001491. 
  7. ^ B. T. Draine and P. J. Flatau (2008). "The discrete dipole approximation for periodic targets: theory and tests.". J. Opt. Soc. Am. A 25. 
  8. ^ MA Yurkin & AG Hoekstra (2007). "The discrete dipole approximation: an overview and recent developments". Journal of Quantitative Spectroscopy and Radiative Transfer 106: 558–589. arXiv:0704.0038. Bibcode 2007JQSRT.106..558Y. doi:10.1016/j.jqsrt.2007.01.034. 
  9. ^ P. C. Chaumet, A. Rahmani, and G. W. Bryant, Generalization of the coupled dipole method to periodic structures, Phys. Rev. B 67, 165404 (2003).
  10. ^ R. Schmehl, B. M. Nebeker, and E. D. Hirleman, Discrete dipole approximation for scattering by features on surfaces by means of a two-dimensional fast Fourier transform technique, J. Opt. Soc. Am. A 14, 3026–3036 (1997).
  11. ^ A. Penttila, E. Zubko, K. Lumme, K. Muinonen, M. A. Yurkin, B. T. Draine, J. Rahola, A. G. Hoekstra, and Y. Shkuratov, Comparison between discrete dipole implementations and exact techniques, J. Quant. Spectrosc. Radiat. Transfer 106, 417-436 (2007).
  12. ^ E. Zubko, D. Petrov, Ye. Grynko, Yu. Shkuratov, H. Okamoto, K. Muinonen, T. Nousiainen, H. Kimura, T.Yamamoto, and G. Videen. Validity criteria of the discrete dipole approximation, Applied Optics 49, 1267-1279 (2010).

See also


Wikimedia Foundation. 2010.

Игры ⚽ Нужен реферат?

Look at other dictionaries:

  • Discrete dipole approximation codes — This article contains list of discrete dipole approximation codes and their applications. The discrete dipole approximation (DDA) is a flexible technique for computing scattering and absorption by targets of arbitrary geometry. Given a target of… …   Wikipedia

  • Computational electromagnetics — Computational electromagnetics, computational electrodynamics or electromagnetic modeling is the process of modeling the interaction of electromagnetic fields with physical objects and the environment. It typically involves using computationally… …   Wikipedia

  • Light scattering by particles — part of computational electromagnetics dealing with single particle scattering, single scattering albedo, and absorption of electromagnetic radiation.Maxwell s equations are the the basis of theoretical and computational methods. In case of… …   Wikipedia

  • Gans theory — or Mie Gans theory is the extension of Mie theory for the case of spheroidal particles. It gives the scattering characteristics of both oblate and prolate spheroidal particles much smaller than the excitation wavelength.Since it is a solution of… …   Wikipedia

  • Codes for electromagnetic scattering by spheres — this article list codes for electromagnetic scattering by a homogeneous sphere, layered sphere, and cluster of spheres. Some of the source codes may be available on [1]. Contents 1 Solution techniques 2 Classification …   Wikipedia

  • Rayleigh scattering — This article is about the optical phenomenon. For the magnetic phenomenon, see Rayleigh law. For the stochastic distribution, see Rayleigh distribution. For the wireless multipath propagation model, see Rayleigh fading. Rayleigh scattering causes …   Wikipedia

  • Sunrise — [ Dead Sea seen from Masada, Israel] Sunrise is the instant at which the upper edge of the Sun appears above the horizon in the east. Sunrise should not be confused with dawn, which is the (variously defined) point at which the sky begins to… …   Wikipedia

  • Sunset — Sunset, also called sundown in some American English dialects, is the instant when the trailing edge of the sun s disk disappears below the horizon in the west. It should not be confused with dusk, which is the point at which darkness falls, some …   Wikipedia

  • Mie theory — Mie theory, also called Lorenz Mie theory or Lorenz Mie Debye theory, is a complete analytical solution of Maxwell s equations for the scattering of electromagnetic radiation by spherical particles (also called Mie scattering). Mie solution is… …   Wikipedia

  • DDA — may stand for: Danish Design Award Data Dump Analysis Delhi Development Authority, the Planning Agency for Delhi, the capital of India. Dda (DNA dependent ATPase), a DNA helicase. Demand deposit account, the classification that checking accounts… …   Wikipedia

Share the article and excerpts

Direct link
Do a right-click on the link above
and select “Copy Link”