The Generalized Multipole Technique for Light Scattering

1. Front Matter

   Pages i-xvi

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2. Principal Modes of Maxwell’s Equations

   • Ben Hourahine, Duncan McArthur, Francesco Papoff

   Pages 1-33

3. The Invariant Imbedding T Matrix Approach

   • Adrian Doicu, Thomas Wriedt

   Pages 35-47

4. Methods for Electromagnetic Scattering by Large Axisymmetric Particles with Extreme Geometries

   • Adrian Doicu, Yuri Eremin, Dmitry S. Efremenko, Thomas Trautmann

   Pages 49-69

5. Fictitious Particle Approach for Light Scattering Investigation from the Line Features of a Substrate Based on the Discrete Sources Method

   • Yuri Eremin, Thomas Wriedt

   Pages 71-91

6. Convergent Fields Generated by Divergent Currents in the Method of Auxiliary Sources

   • George Fikioris, Nikolaos L. Tsitsas

   Pages 93-119

7. MMP Simulation of Plasmonic Particles on Substrate Under E-Beam Illumination

   • Ueli Koch, Jens Niegemann, Christian Hafner, Juerg Leuthold

   Pages 121-145

8. The Generalized Multipole Technique for the Simulation of Low-Loss Electron Energy Loss Spectroscopy

   • Lars Kiewidt, Mirza Karamehmedović

   Pages 147-167

9. Introduction to Yasuura’s Method of Modal Expansion with Application to Grating Problems

   • Akira Matsushima, Toyonori Matsuda, Yoichi Okuno

   Pages 169-220

10. Pole Location in GMT

    • James E. Richie

    Pages 221-246

11. Back Matter

    Pages 247-249

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This book presents the Generalized Multipole Technique as a fast and powerful theoretical and computation tool to simulate light scattering by nonspherical particles. It also demonstrates the considerable potential of the method.

In recent years, the concept has been applied in new fields, such as simulation of electron energy loss spectroscopy and has been used to extend other methods, like the null-field method, making it more widely applicable. The authors discuss particular implementations of the GMT methods, such as the Discrete Sources Method (DSM), Multiple Multipole Program (MMP), the Method of Auxiliary Sources (MAS), the Filamentary Current Method (FCM), the Method of Fictitious Sources (MFS) and the Null-Field Method with Discrete Sources (NFM-DS). The Generalized Multipole Technique is a surface-based method to find the solution of a boundary-value problem for a given differential equation by expanding the fields in terms of fundamental or other singular solutions of this equation. The amplitudes of these fundamental solutions are determined from the boundary condition at the particle surface.

Electromagnetic and light scattering by particles or systems of particles has been the subject of intense research in various scientific and engineering fields, including astronomy, optics, meteorology, remote sensing, optical particle sizing and electromagnetics, which has led to the development of a large number of modelling methods based on the Generalized Multipole Technique for quantitative evaluation of electromagnetic scattering by particles of various shapes and compositions. The book describes these methods in detail.

• Electron Energy Loss Spectroscopy
• Modes of Maxwell’s Equations
• Auxiliary Sources
• Yasuura's Method
• Light Scattering by Nonspherical Particles
• Null-field Method
• Discrete Sources Method
• Multiple Multipole Program

• Leibniz-Institut für Werkstofforientierte Technologien—IWT, Bremen, Germany

  Thomas Wriedt

• Faculty of Computational Mathematics and Cybernetics, Lomonosov Moscow State University, Moscow, Russia

  Yuri Eremin

Thomas Wriedt studied Electrical Engineering in Kiel and Bremen, Germany. He received his Dr.-Ing. degree in Microwave Engineering from the University of Bremen in 1986. From 1986 to 1989 he was a postdoc researcher at the University of Bremen's Department of Process Engineering, working on optical particle characterization. He has been the head of the Powder and Particle Measurement research group at the Stiftung Institut für Werkstofftechnik (IWT) (from January 2018: Leibniz-Institut für Werkstofforientierte Technologien (IWT) ), Bremen since 1989. His current research focuses on the Null-field method with Discrete Sources (NFM-DS) for simulation in optical particle characterization and generally light scattering by particles. He has authored and co-authored four books and 170 peer-reviewed papers.

Yuri A. Eremin graduated from the Physics Faculty of Lomonosov Moscow State University (MSU), Russia in 1972. He received his Ph.D. in Mathematical and Theoretical Physics from Lomonosov Moscow State University (MSU) in 1976. From 1975 to 1982 he was a research scientist at the Research Computing Center (RCC) of MSU. From 1982 to 1992 he was a senior researcher at the Computational Mathematics and Cybernetics Faculty of MSU. He obtained his Dr. Sci. degree in Mathematical Modeling from MSU in 1989. Since 1993 he has been the head of a research group at the Computational Mathematics and Cybernetics Faculty of MSU. His current interests are direct and inverse light scattering problems. He is the author of the Discrete Sources Method that enables the construction of effective computational models to simulate light scattering. He has authored more than 215 papers in scientific journals and four books.

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