Online Papers (PDF files)

  • [73] Evers, T.; Dahl, H.; Wriedt, T.: Extension of the program 3D MMP with 5th order Gaussian beam. Electronics Letters 32 (1996)15, 1356-1357.
  • [76] Doicu, A.; Wriedt, T.: Plane wave spectrum of electromagnetic beams. Optics Communications 135 (1997), 114-124.
  • [79] Doicu, A.; Wriedt, T.: Formulations of the extended boundary condition method for incident Gaussian beams using multiple multipole expansions. Journal of Modern Optics 44 (1997) 4, 785-801.
  • [81] Doicu, A.; Wriedt, T.: Extended boundary condition method with multipole sources located in the complex plane. Optics Communications 139 (1997), 85-91.
  • [83] Göbel, G.; Wriedt, T.; Bauckhage, K.: Periodic drag force and particle size measurement in a double ring electodynamic trap. Rev. Sci. Instrum. 68(1997) 8, 3046-3052.
  • [84] Rheims, J.; Wriedt, T.: Refractive-index measurements in the near-IR using an Abbe refractometer. Measurement Science and Technology 8 (1997), 601-605.
  • [85] Göbel, G.; Wriedt, T.; Bauckhage, K.: Micron and Sub-Micron Aerosol Sizing with a Standard Phase-Doppler Anemometer. Journal of Aerosol Science 29 (1998) 9, 1063-1073.
  • [86] G. Göbel, A. Lippek, T. Wriedt, K. Bauckhage: Monte Carlo Simulation of Light Scattering by Inhomogeneous Spheres. in M. Pinar Mengüc (Editor): Radiative Transfer - II, Proceedings of the Second International Symposium on Radiative Transfer, Kusadasi, Turkey, July 1997, Begell House, New York 1998.
  • [95] T. Wriedt: A Review of Elastic Light Scattering Theories. Part. Part. Syst. Charact. 15 (1998) 67-74.
  • [98] Dahl, H.; Metz, H.J.; Wriedt, T.: Light scattering of silver halogenide crystals. in Wriedt, T.; Eremin, Y. (Eds): Electromagnetic and Light Scattering - Theory and Applications III, Proceedings of the 3rd Workshop on Electromagnetic and Light Scattering. Bremen (1998), 51-58.
  • [104] T. Wriedt, U. Comberg: Comparison of computational scattering method. J. Quant. Spectrosc. Radiat. Transfer 60 (1998) 3, 411-423.
  • [105] Mitschke, M.; Wriedt, T. Bauckage, K.: Standard PDA for measuring the size of inhomogeneous droplets. Meas. Sci. Technol. 9 (1998), 197-209.
  • [106] Wriedt, T.; Doicu, A.: Formulation of the extended boundary condition method for three-dimensional scattering using the method of discrete sources. Journal of Modern Optics 45 (1998) 1, 199-213.
  • [107] Wriedt, T.; Doicu, A.: Scattering analysis of conducting axisymmetric particles using the extended boundary condition method with discrete sources. Journal of Modern Optics 45 (1998) 11, 2207-2215.
  • [108] Wriedt, T.; Doicu, A.: Light scattering from a particle on or near a surface. Optics Communications 152 (1998), 376-384.
  • [109] Doicu, A.; Göbel, G.; Wriedt, T.; Bauckhage, K.: Influence of Agglomerates of Conducting Spheres on the Response on the Response of a Phase-Doppler Anemometer. Part. Part. Syst. Charakt. 15 (1998), 225-229.
  • [110] Rheims, J.; Wriedt, T.; Bauckhage, K.: Working Principle and Experimental Results for a Differential Phase-Doppler Technique. Part. Part. Syst. Charakt. 15 (1998), 219-224.
  • [112] Rheims, J.; Wriedt, T.; Bauckhage, K.: Sizing of inhomogeneous particles by a differential laser Doppler anemometer. Meas. Sci. Technol. 10(1999), 68-75.
  • [114] A. Doicu, T. Wriedt: Calculation of the T-matrix in the null-field method with discrete sources. J. Opt. Soc. Am. A 16 (1999) 10, 2539-2544.
  • [115] Comberg, U.; Wriedt, T.: Comparison of scattering calculations for aggregated particles based on different models. Journal of Quantitative Spectroscopy & Radiative Transfer 63 (1999), 149-162
  • [116] Doicu, A.; Eremin, Yu.A.; Wriedt, T.: Convergence of the T-matrix method for light scattering from a particle on or near a surface. Optics Communications 159 (1999), 266-277.
  • [117] Doicu, A.; Eremin, Yu.A. Wriedt, T.: Projection schemes in the null field method. Journal of Quantitative Spectroscopy & Radiative Transfer 63 (1999), 175-189.
  • [118] A. Doicu, J. Köser, T. Wriedt, K. Bauckhage: Light scattering simulation and measurement of monodisperse spheroids using a Phase Doppler Anemometer. Part. Part. Syst. Charac. 15 (1999), 257-262.
  • [120] Ulmke, H.; Wriedt, T.; Lohner, H.; Bauckhage, K.: The Piezoelectric Droplet Generator: A Versatile Tool for Dispensing Applications and Calibration of Particle Sizing Instruments. Pat McKeown et al. (editor): Precision Engineering - Nanotechnology, Proceedings of the 1st International euspen Conference, Vol. 2, Shaker Verlag, Aachen 1999, page 290-293.
  • [124] Wriedt, T.: Extension of the Null Field Method with Discrete Sources for computation of the T-matrix of scatterers with large axial ratio. Proceedings 4th Conference on Electromagnetic and Light Scattering by Non-spherical Particles: Theory and Applications, Vigo, Spain, 20 + 21 Sep. 1999.
  • [127] A. Doicu, Y.A. Eremin, T. Wriedt: T- and D-matrix methods for electromagnetic scattering by impedance obstacles. Computer physics communications 124 (2000) 1, 19-27.
  • [128] T. Wriedt, A. Doicu, U. Comberg, H. Sagehorn, R. Schuh: Gaussian beam scattering using the discrete sources method. in G. Gousbet (Editor): Scattering of shaped light beams and applications. Research Signpost, Trivandrum, India, 2000, 125-147.
  • [132] T. Wriedt, A. Doicu: Novel software implementation of the T-matrix method for arbitrary configurations of single and clusters of composite nonspherical particles.5th Conference on Electromagnetic and Light Scattering by Nonspherical Particles: Theory, Measurements, and Applications,  August 28 -September 1, 2000, Dalhousie University, Halifax, Nova Scotia, Canada.
  • [133] Wriedt, T.; Doicu, A.: Comparison between various formulations of the extended boundary condition method. Optics Communications 142 (1997), 91-98.
  • [136] Doicu, A.; Eremin, Yu.; Wriedt, T.: Non-axisymmetric models for light scattering from a particle on or near a plane surface. Optics communications. 182 (2000), 4, 281-288.
  • [137] Wriedt T.; Doicu, A.: T-Matrix method for light scattering from particles on or near an infinite surface. in Moreno, F.; González, F. (Eds.): Light Scattering from Microstructures. Berlin: Springer 2000, 113-132.
  • [138] Doicu, A.; Eremin, Yu.; Wriedt, T.:Scattering of evanescent waves by a particle on or near a plane surface. Computer Physics Communications 134 (2001), 1-10.
  • [139] G. Göbel, A. Doicu, Wriedt, K. Bauckhage: Influence of surface roughness of conducting spheres on the response of a Phase-Doppler Anemometer. Particle & Particle Systems Characterization 14 (1997), 6, S. 283-289.
  • [140] Doicu, A.; Wriedt, T.: Null-field method with discrete sources to electromagnetic scattering from composite scatterers. Optics Commun. 190 (2001), 13-17.
  • [141] Doicu, A.; Wriedt, T.: Null-field method with discrete sources to electromagnetic scattering from layered scatterers. Comput. Phys. Commun., 138 (2001), 136–142.
  • [142] Doicu, A.; Wriedt, T.: T-matrix method for electromagnetic scattering from complex scatterers. J. Quant. Spect. Radiat. Trans., 70 (2001), 663 –673.
  • [143] Doicu, A.; Wriedt, T.: Equivalent refractive index of a sphere with multiple spherical inclusions. J. Opt. A: Pure Appl. Opt. 3 (2001), 204-209.
  • [144] Doicu, A.; Wriedt, T.: A light scattering model for analyzing inhomogeneous particles using a Phase Doppler Anemometer. Part. Part. Syst. Charact., eingereicht.
  • [145] Sagehorn, H.; List, J.; Wiegand, T.; Weichert, R.; Wriedt, T.: Characterization of airborne fibers via Fraunhofer theory: Examination of the validity of Fraunhofer theory with the exact scattering theory MMP. Part. Part. Syst. Char. 18 (2001) 2, 55-63.
  • [146] Schuh, R.; Wriedt, T.: Computer programs for light scattering by particles with inclusions. J. Quant. Spect. Radiat. Trans., 70 (2001), 715–723.
  • [147] Sagehorn, H.; Wriedt, T.; Bauckhage, K.: Detektion von lungengängigen Fasern. Härterei-Technische Mitteilungen 56 (2001) 2, 120-125.
  • [148] Doicu, A.; Eremin, Yu.; Wriedt, T.:Scattering of evanescent waves by a sensor tip near a plane surface. Optics Communications 190 (2001), 5-12.
  • [155] Wriedt, T.; Schuh, R.: The inclusion-concentration measurement of suspension droplets based on Monte Carlo ray tracing. Meas. Sci. Technol. 13 (2002), 276–279.
  • [156] Wriedt, T.: Using the T-Matrix method for light scattering computations by non-axisymmetric particles: Superellipsoids and realistically shaped particles. Part. Part. Syst. Charact 19 (2002) 4, 256-268.
  • [157] Eremin, Y.; Wriedt, T.: Large dielectric non-spherical particle in an evanescent wave field near a plane surface. Optics Communications 214 (2002) 39–45.
  • [158] Eremin, Y.; Wriedt, T.: Analysis of evanescent waves conversion by a non-spherical particle near a metal-coated glass prism via discrete sources method. Optics Communications 223 (2003) 221–232.
  • [159] Schuh, R.; Wriedt, T.: Light Scattering by Bent Cylindrical Fibers for Fiber Length and Diameter Characterization. Part. Part. Syst. Charact. 20 (2003), 243-249.
  • [160] Eremina, E.; Eremin, Y.; Wriedt, T.: Review of light scattering by fiber particles with a high aspect ratio. Recent Res. Devel. Optics 3 (2003), 297-318.
  • [161] Eremina, E.; Eremin, Y.; Wriedt, T.: Extension of the discrete sources method to light scattering by highly elongated finite cylinders. Journal of Modern Optics 51 (2004) 3, 423–435.
  • [173] J. Hellmers; T. Wriedt: Influence of particle shape models on T-Matrix light scattering simulation. Journal of Quantitative Spectroscopy and Radiative Transfer 89 (2004) 97-110.
  • [174] E. Eremina, T. Wriedt: Light scattering analysis by a particle of extreme shape via Discrete Sources Method. Journal of Quantitative Spectroscopy and Radiative Transfer 89 (2004) 67-77.
  • [175] N. Riefler, S. di Stasio, T. Wriedt: Structural Analysis of Clusters using Configurational and Orientational Averaging in Light Scattering Analysis. Journal of Quantitative Spectroscopy and Radiative Transfer 89 (2004) 323-342.
  • [176] E. Eremina, Y. Eremin, T. Wriedt: Analysis of light scattering by erythrocyte based on discrete sources method. Optics Communications 244 (2005) 15-23.
  • [178] S. Pulbere, Thomas Wriedt: Light Scattering by Cylindrical Fibers with High Aspect Ratio Using the Null-Field Method with Discrete Sources Part. Part. Syst. Charact. 21 (2004) 213 - 218.
  • [179] M.I. Mishchenko, G. Videen, V.A. Babenko, N. G. Khlebtsov, T. Wriedt: T-matrix theory of electromagnetic scattering by particles and its applications: a comprehensive reference database. Journal of Quantitative Spectroscopy & Radiative Transfer 88 (2004) 357-406.
  • [180] Y. Eremin, T. Wriedt: Discrete sources method model for evanescent waves scattering analysis. Journal of Quantitative Spectroscopy & Radiative Transfer 89 (2004) 53-65.
  • [181] E. Eremina, Y. Eremin, T. Wriedt: Discrete sources method for simulation of resonance spectra of nonspherical nanoparticles on a plane surface. Optics Communications 246 (2005) 405-413.
  • [182] E. Eremina, Y. Eremin, T. Wriedt: Discrete source method for spectroscopic analysis of nano-particles on a plane inferface. Journal of Optics A, 7 (2005) 706-710.
  • [183] J. Hellmers, E. Eremina, T. Wriedt: Simulation of light scattering by biconcave Cassini ovals using the nullfield method with discrete sources. Journal of Optics A, 8 (2006) 1-9.
  • [184] J. Hellmers, T. Wriedt, A. Doicu: Light scattering simulation by oblate disc spheres using the null field method with discrete sources located in the complex plane. Journal of Modern Optics 53 (2006) 3, 267–282.
  • [185] Laurent Helden, Elena Eremina, Norbert Riefler, Christopher Hertlein, Clemens Bechinger, Yuri Eremin, and Thomas Wriedt: Single-particle evanescent light scattering simulations for total internal reflection microscopy. Applied Optics 45 (2006) 28, 7299-7308.
  • [186] Elena Eremina, Natalia Grishina, Yuri Eremin, Laurent Helden and Thomas Wriedt: Total internal reflection microscopy with a multilayered interface: a light scattering model based on a discrete sources method. J. Opt. A: Pure Appl. Opt. 8 (2006) 999–1006.
  • [187] Elena Eremina, Yuri Eremin, Thomas Wriedt: Simulations of light scattering spectra of a nanoshell on plane interface based on the discrete sources method. Optics Communications 267 (2006), 524–529.
  • [188] Elena Eremina, Jens Hellmers, Yuri Eremin, Thomas Wriedt: Different shape models for erythrocyte: Light scattering analysis based on the discrete sources method. Journal of Quantitative Spectroscopy & Radiative Transfer 102 (2006), 3–10.
  • [189] Elena Eremina, Thomas Wriedt, Yuri Eremin: Discrete Sources Method for analysis of a light scattering by an air bubble on resist for immersion lithography. Journal of Quantitative Spectroscopy & Radiative Transfer 100 (2006), 131–136.
  • [190] Thomas Wriedt, Jens Hellmers, Elena Eremina, Roman Schuh: Light scattering by single erythrocyte: Comparison of different methods. Journal of Quantitative Spectroscopy & Radiative Transfer 100 (2006), 444–456.
  • [191] Thomas Wriedt: Studies of light scattering by complex particles using the null-field method with discrete sources. in Alexander A. Kokhanovsky (Editor): Light Scattering Reviews 2, Springer Praxis, Berlin 2007.
  • [192] Thomas Wriedt: Review of the null-field method with discrete sources. Journal of Quantitative Spectroscopy & Radiative Transfer 106 (2007) 535–545.
  • [193] Norbert Riefler, Elena Eremina, Christopher Hertlein, Laurent Helden, Yuri Eremin, Thomas Wriedt, Clemens Bechinger: Comparison of T-matrix method with discrete sources method
    applied for total internal reflection microscopy. Journal of Quantitative Spectroscopy & Radiative Transfer 106 (2007) 464–474.
  • [194] Elena Eremina, Yuri Eremin, Thomas Wriedt: Analysis of the light scattering properties of a gold nanorod on a plane surface via discrete sources method. Optics Communications 273 (2007) 278–285.
  • [195] Jens Hellmers, Thomas Wriedt: T-Matrix light scattering simulation of rough, non-symmetrical spherical particles. Journal of Quantitative Spectroscopy & Radiative Transfer 106 (2007) 90–103.
  • [196] Norbert Riefler, Roman Schuh and Thomas Wriedt: Investigation of a measurement technique to estimate concentration and size of inclusions in droplets. Meas. Sci. Technol. 18 (2007) 2209–2218.
  • [197] Michael I. Mishchenko, , Gorden Videen, Victor A. Babenko, Nikolai G. Khlebtsov, Thomas Wriedt: Comprehensive T-matrix reference database: A 2004–06 update. Journal of Quantitative Spectroscopy & Radiative Transfer 106 (2007) 304–324.
  • [198] Christopher Hertlein, Norbert Riefler, Elena Eremina, Thomas Wriedt, Yuri Eremin, Laurent Helden, and Clemens Bechinger: Experimental Verification of an Exact Evanescent Light Scattering Model for TIRM. Langmuir 24 (2008) 1, 1-4.
  • [199] Thomas Wriedt: Mie theory 1908, on the mobile phone 2008. Journal of Quantitative Spectroscopy & Radiative Transfer 109 (2008), 1543–1548. FnattLabME including Mie scattering application
  • [200] Thomas Wriedt, Jens Hellmers: New Scattering Information Portal for the light-scattering community. Journal of Quantitative Spectroscopy & Radiative Transfer 109 (2008), 1536–1542.
  • [201] Thomas Wriedt, Roman Schuh, Adrian Doicu: Scattering by Aggregated Fibres Using a Multiple Scattering T-Matrix Approach. Part. Part. Syst. Charact. 25 (2008), 74–83.
  • [202] Jens Hellmers, Norbert Riefler, Thomas Wriedt, Yuri A. Eremin: Light scattering simulation for the characterization of sintered silver nanoparticles. Journal of Quantitative Spectroscopy & Radiative Transfer 109 (2008), 1363–1373.
  • [203] Michael I. Mishchenko, Gorden Videen, Nikolai G. Khlebtsov, Thomas Wriedt, Nadia T. Zakharov: Comprehensive T-matrix reference database: A 2006–07 update. Journal of Quantitative Spectroscopy & Radiative Transfer 109 (2008), 1447–1460.
  • [204] NorbertRiefler, Thomas Wriedt: Generation of Monodisperse Micron-Sized Droplets using Free Adjustable Signals. Part. Part. Syst. Charact. 25 (2008), 176–182.
  • [205] Norbert Riefler and Thomas Wriedt: Intercomparison of Inversion Algorithms for Particle-Sizing using Mie Scattering. Part. Part. Syst. Charact. 25 (2008) in print.
  • [206] Elena Eremina, Yuri Eremin, Natalia Grishina, Thomas Wriedt:  Analysis of light scattering in the evanescent waves area by a cylindrical nanohole in a noble-metal film. Optics Communications xxx (2008), in print.