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G. Gouesbet, J. J. Wang, and Y. P. Han, “Transformations of spherical beam shape coefficients in general Lorenz–Mie theories through rotations of coordinate system: III. Special values of Euler angles,” Opt. Commun. 283, 3235–3243 (2010).

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G. Gouesbet, J. J. Wang, and Y. P. Han, “Transformations of spherical beam shape coefficients in general Lorenz–Mie theories through rotations of coordinate system: IV. Plane waves,” Opt. Commun. 283, 3244–3254 (2010).

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F. Xu, J. A. Lock, G. Gouesbet, and C. Tropea, “Optical stress on the surface of a particle: I. Homogeneous sphere,” Phys. Rev. A 79, 053808 (2009).

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L. Méès, G. Gouesbet, and G. Gréhan, “Transient internal and scattered fields from a multi-layered sphere illuminated by a pulsed laser,” Opt. Commun. 282, 4189–4193 (2009).

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G. X. Han and Y. P. Han, “Radiation force of a sphere with an eccentric inclusion illuminated by a laser beam,” Acta Phys. Sinica 58, 6167–6173 (2009).

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H. Y. Li and Z. S. Wu, “Electromagnetic scattering by multi-layered spheres in a 2D Gaussian beam,” Acta Phys. Sinica 57, 833–838 (2008).

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G. X. Han, Y. P. Han, J. Y. Liu, and Y. Zhang, “Scattering of an eccentric sphere arbitrarily located in a shaped beam,” J. Opt. Soc. Am. B 25, 2064–2072 (2008).

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F. Xu, K. F. Ren, and X. S. Cai, “Expansion of an arbitrarily oriented, located, and shaped beam in spheroidal coordinates,” J. Opt. Soc. Am. A 24, 109–118 (2007).

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F. Xu, K. F. Ren, G. Gouesbet, G. Gréhan, and X. Cai, “Generalized Lorenz–Mie theory for an arbitrarily oriented, located and shaped beam scattering by a homogeneous spheroid,” J. Opt. Soc. Am. A 24, 119–131 (2007).

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Y. P. Han, H. Zhang, and G. Han, “The expansion coefficients of arbitrary shaped beam in oblique illumination,” Opt. Express 15, 735–746 (2007).

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Y. P. Han, L. Mees, G. Gouesbet, Z. S. Wu, and G. Gréhan, “Resonant spectra of a deformed spherical microcavity,” J. Opt. Soc. Am. B 23, 1390–1397 (2006).

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A. A. R. Neves, A. Fontes, L. A. Padilha, E. Rodriguez, C. H de Brito Cruz, L. C. Barbosa, and C. L. Cesar, “Exact partial wave expansion of optical beams with respect to an arbitrary origin,” Opt. Lett. 31, 2477–2479 (2006).

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Y. P. Han, L. Mees, K. F. Ren, G. Gréhan, Z. S. Wu, and G. Gouesbet, “Far scattered field from a spheroid under a femtosecond pulsed illumination in a generalized Lorenz–Mie theory framework,” Opt. Commun. 231, 71–77 (2004).

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J. A. Lock, “Calculation of the radiation trap force for laser tweezers by use of generalized Lorenz–Mie theory: I. Localized model description of an on-axis tightly focused laser beam with spherical aberration,” Appl. Opt. 43, 2532–2544(2004).

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Y. P. Han, L. Mees, K. F. Ren, G. Gouesbet, S. Z. Wu, and G. Gréhan, “Scattering of light by spheroids: the far field case,” Opt. Commun. 210, 1–9 (2002).

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L. Méès, G. Gouesbet, and G. Gréhan, “Numerical predictions of microcavity internal fields created by femtosecond pulses, with emphasis on whispering gallery modes,” J. Opt. A 4, 8150–8153 (2002).

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G. Gouesbet, S. Meunier-Guttin-Cluzel, and G. Gréhan, “Morphologydependent resonances and/or whispering gallery modes for a two-dimensional dielectric cavity with an eccentrically located spherical inclusion, a Hamiltonian point of view with Hamiltonian (optical) chaos,” Opt. Commun. 201, 223–242 (2002).

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H. Polaert, G. Gouesbet, and G. Gréhan, “Laboratory determination of beam shape coefficients for use in generalized Lorenz–Mie theory,” Appl. Opt. 40, 1699–1706 (2001).

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Y. P. Han and Z. S. Wu, “Scattering of a spheroidal particle illuminated by a Gaussian beam,” Appl. Opt. 40, 2501–2509 (2001).

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L. Méès, G. Gouesbet, and G. Gréhan, “Scattering of laser pulses (plane wave and focused Gaussian beams) by spheres,” Appl. Opt. 40, 2546–2550 (2001).

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L. Méès, G. Gréhan, and G. Gouesbet, “Time-resolved scattering diagrams for a sphere illuminated by plane wave and focused short pulses,” Opt. Commun. 194, 59–65 (2001).

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L. Méès, G. Gouesbet, and G. Gréhan, “Interaction between femtosecond pulses and a spherical microcavity: internal fields,” Opt. Commun. 199, 33–38 (2001).

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G. Gouesbet, S. Meunier-Guttin-Cluzel, and G. Gréhan, “Generalized Lorenz–Mie theory for a sphere with an eccentrically located spherical inclusion, and optical chaos,” Part. Part. Syst. Charact. 18, 190–195 (2001).

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G. Gouesbet, S. Meunier-Guttin-Cluzel, and G. Gréhan, “Periodic orbits in Hamiltonian chaos of the annular billiard,” Phys. Rev. E 65, 016212 (2001).

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Y. P. Han and Z. S. Wu, “The expansion coefficients of a spheroidal particle illuminated by Gaussian beam,” IEEE Trans. Antennas Propag. 49, 615–620 (2001).

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G. Gouesbet and G. Gréhan, “Generic formulation of a generalized Lorenz–Mie theory for a particle illuminated by laser pulses,” Part. Part. Syst. Charact. 17, 213–224 (2000).

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G. Gouesbet, L. Mees, G. Gréhan, and K. F. Ren, “Description of arbitrary shaped beams in elliptical cylinder coordinates by using a plane wave spectrum approach,” Opt. Commun. 161, 63–78 (1999).

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G. Gouesbet, “Validity of the cylindrical localized approximation for arbitrary shaped beams in generalized Lorenz–Mie theory for circular cylinders,” J. Mod. Opt. 46, 1185–1200 (1999).

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G. Gouesbet and A. Berlemont, “Eulerian and Lagrangian approaches for predicting the behaviour of discrete particles in turbulent flows,” Prog. Energy Combust. Sci. 25, 133–159(1999).

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L. Méès, K. F. Ren, G. Gréhan, and G. Gouesbet, “Scattering of a Gaussian beam by an infinite cylinder with arbitrary location and arbitrary orientation: numerical results,” Appl. Opt. 38, 1867–1876 (1999).

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G. Gouesbet and L. Méès, “Generalized Lorenz–Mie theory for infinitely long elliptical cylinders,” J. Opt. Soc. Am. A 16, 1333–1341 (1999).

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G. Gouesbet and L. Méès, “Validity of the elliptical cylinder localized approximation for arbitrary shaped beams in generalized Lorenz–Mie theory for elliptical cylinders,” J. Opt. Soc. Am. A 16, 2946–2958 (1999).

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G. Gouesbet, L. Méès, and G. Gréhan, “Partial-wave description of shaped beams in elliptical-cylinder coordinates,” J. Opt. Soc. Am. A 15, 3028–3038 (1998).

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H. Polaert, G. Gréhan, and G. Gouesbet, “Forces and torques exerted on a multilayered spherical particle by a focused Gaussian beam,” Opt. Commun. 155, 169–179 (1998).

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G. Gouesbet, “Measurements of beam shape coefficients in generalized Lorenz–Mie theory and the density-matrix approach: II. The density matrix approach,” Part. Part. Syst. Charact. 14, 88–92 (1997).

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K. F. Ren, G. Gréhan, and G. Gouesbet, “Scattering of a Gaussian beam by an infinite cylinder in the framework of a GLMT, formulation and numerical results,” J. Opt. Soc. Am. A 14, 3014–3025 (1997).

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Z. S. Wu, L. X. Guo, K. F. Ren, G. Gouesbet, and G. Gréhan, “Improved algorithms for electromagnetic scattering of plane waves and shaped beams by multilayered spheres,” Appl. Opt. 36, 5188–5198 (1997).

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R. P. Ratowsky, L. Yang, R. J. Deri, K. W. Chang, J. S. Kallman, and G. Trott, “Laser diode to single-mode fiber ball lens coupling efficiency: full-wave calculation and measurements,” Appl. Opt. 36, 3435–3438 (1997).

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A. Doicu and T. Wriedt, “Computation of the beam-shape-coefficients in the generalized Lorenz–Mie theory by using the translational addition theorem for spherical vector wave functions,” Appl. Opt. 36, 2971–2978 (1997).

[CrossRef]

G. Gouesbet, C. Letellier, K. F. Ren, and G. Gréhan, “Discussion of two quadrature methods of evaluating beam shape coefficients in generalized Lorenz–Mie theory,” Appl. Opt. 35, 1537–1542 (1996).

[CrossRef]

G. Gouesbet, “Partial wave expansions and properties of axisymmetric light beams,” Appl. Opt. 35, 1543–1555(1996).

[CrossRef]

J. A. Lock and J. T. Hodges, “Far-field scattering of an axisymmetric laser beam of arbitrary prole by an on-axis spherical particle,” Appl. Opt. 35, 4283–4290 (1996).

[CrossRef]

G. Gouesbet, “Exact description of arbitrary shaped beams for use in light scattering theories,” J. Opt. Soc. Am. A 13, 2434–2440 (1996).

[CrossRef]

Y. Harada and T. Asakura,” Radiation forces on a dielectric sphere in the Rayleigh scattering regime,” Opt. Commun. 124, 529–541 (1996).

[CrossRef]

E. Lenglart and G. Gouesbet, “The separability ‘theorem’ in terms of distributions with discussion of electromagnetic scattering theory,” J. Math. Phys. 37, 4705–4710 (1996).

[CrossRef]

A. Mekis, J. U. Nöckel, G. Chen, A. D. Stone, and R. K. Chang, “Ray chaos and Q spoiling in lasing droplets,” Phys. Rev. Lett. 75, 2682–2685 (1995).

[CrossRef]

G. Gouesbet, “ The separability theorem revisited with applications to light scattering theory,” J. Opt. 26, 123–135 (1995).

[CrossRef]

G. Gouesbet, “Interaction between Gaussian beams and infinite cylinders, by using the theory of distributions,” J. Opt. 26, 225–239 (1995).

[CrossRef]

J. A. Lock, “Improved Gaussian beam-scattering algorithm,” Appl. Opt. 34, 559–570 (1995).

[CrossRef]

J. T. Hodges, G. Gréhan, G. Gouesbet, and C. Presser, “Forward scattering of a Gaussian beam by a nonabsorbing sphere,” Appl. Opt. 34, 2120–2132 (1995).

[CrossRef]

G. Gouesbet, J. A. Lock, and G. Gréhan, “Partial wave representations of laser beams for use in light scattering calculations,” Appl. Opt. 34, 2133–2143 (1995).

[CrossRef]

F. Onofri, G. Gréhan, and G. Gouesbet, “Electromagnetic scattering from a multilayered sphere located in an arbitrary beam,” Appl. Opt. 34, 7113–7124 (1995).

[CrossRef]

P. Torok, P. Varga, Z. Laczik, and G. R. Booker, “Electromagnetic diffraction of light focused through a planar interface between materials of mismatched refractive indices: An integral representation,” J. Opt. Soc. Am. A 12, 325–332 (1995).

[CrossRef]

P. Torok, R. Varga, and G. R. Booker, “Electromagnetic diffraction of light focused through a planar interface between materials of mismatched refractive indices: Structure of the electromagnetic field. I,” J. Opt. Soc. Am. A 12, 2136–2144 (1995).

[CrossRef]

R. P. Ratowsky, L. Yang, R. J. Deri, J. S. Kallman, and G. Trott, “Ball lens reflections by direct solution of Maxwell’s equations,” Opt. Lett. 20, 2048–2050 (1995).

[CrossRef]

E. E. M. Khaled, S. C. Hill, and P. W. Barber, “Internal electric energy in a spherical particle illuminated with a plane wave or off-axis Gaussian beam,” Appl. Opt. 33, 524–532 (1994).

[CrossRef]

J. U. Nöckel, A. D. Stone, and R. K. Chang, “Q-spoiling and directionality in deformed ring cavities,” Opt. Lett. 19, 1693–1695 (1994).

[CrossRef]

J. A. Lock and G. Gouesbet, “Rigorous justication of the localized approximation to the beam shape coefficients in generalized Lorenz–Mie. I. On-axis beams,” J. Opt. Soc. Am. A 11, 2503–2515 (1994).

[CrossRef]

G. Gouesbet and J. A. Lock, “Rigorous justication of the localized approximation to the beam shape coefficients in generalized Lorenz–Mie theory. II. Off-axis beams,” J. Opt. Soc. Am. A 11, 2516–2525 (1994).

[CrossRef]

D. W. Mackowski, “Calculation of total cross sections of multiple-sphere clusters,” J. Opt. Soc. Am. A 11, 2851–2861 (1994).

[CrossRef]

K. A. Fuller, “Scattering and absorption cross sections of compound spheres. I. Theory for external aggregation,” J. Opt. Soc. Am. A 11, 3251–3260 (1994).

[CrossRef]

G. Gouesbet and G. Gréhan, “Interaction between shaped beams and an infinite cylinder, including a discussion of Gaussian beams,” Part. Part. Syst. Charact. 11, 299–308 (1994).

[CrossRef]

G. Gréhan, G. Gouesbet, A. Naqwi, and F. Durst, “Trajectory ambiguities in phase-Doppler systems: study of a near-forward and a near-backward geometry,” Part. Part. Syst. Charact. 11, 133–144 (1994).

[CrossRef]

G. Gréhan, K. F. Ren, G. Gouesbet, A. Naqwi, and F. Durst, “Evaluation of a particle sizing technique based on laser sheets,” Part. Part. Syst. Charact. 11, 101–106 (1994).

[CrossRef]

G. Gouesbet, “Generalized Lorenz–Mie theory and applications,” Part. Part. Syst. Charact. 11, 22–34 (1994).

[CrossRef]

K. F. Ren, G. Gréhan, and G. Gouesbet, “Electromagnetic field expression of a laser sheet and the order of approximation,” J. Opt. 25, 165–176 (1994).

[CrossRef]

K. F. Ren, G. Gréhan, and G. Gouesbet, “Laser sheet scattering by spherical particles,” Part. Part. Syst. Charact. 10, 146–151 (1993).

[CrossRef]

G. Gréhan, G. Gouesbet, A. Naqwi, and F. Durst, “Particle trajectory effects in phase-Doppler systems: computations and experiments,” Part. Part. Syst. Charact. 10, 332–338 (1993).

[CrossRef]

J. A. Lock, “Contribution of high-order rainbows to the scattering of a Gaussian laser beam by a spherical particle,” J. Opt. Soc. Am. A 10, 693–706 (1993).

[CrossRef]

J. M. Jensen, Chaotic scattering of light by a dielectric cylinder,” J. Opt. Soc. Am. A 10, 1204–1208 (1993).

[CrossRef]

V. Daniels, M. Vallières, and J. M. Yuan, “Chaotic scattering on a double well: periodic orbits, symbolic dynamics, and scaling,” Chaos 3, 475–485 (1993).

[CrossRef]

E. E. M. Khaled, S. C. Hill, and P. W. Barber, “Scattered and internal intensity of a sphere illuminated with a Gaussian beam,” IEEE Trans. Antennas Propag. 41, 295–303 (1993).

[CrossRef]

A. Ashkin, “Forces on a single-beam gradient laser trap on a dielectric sphere in the ray optics regime,” Biophys. J. 61, 569–582 (1992).

[CrossRef]

A. Wünsche, “Transition from the paraxial approximation to exact solutions of the wave equation and application to Gaussian beams,” J. Opt. Soc. Am. A 9, 765–774 (1992).

[CrossRef]

E. E. M. Khaled, S. C. Hill, P. W. Barber, and D. Q. Chowdhury, “Near-resonance excitation of dielectric spheres with plane waves and off-axis Gaussian beams,” Appl. Opt. 31, 1166–1169 (1992).

[CrossRef]

F. Corbin, G. Gréhan, and G. Gouesbet, “Top-hat beam technique: improvements and application to bubble measurements,” Part. Part. Syst. Charact. 8, 222–228 (1991).

[CrossRef]

S. R. Mishra, “A vector wave analysis of a Bessel beam,” Opt. Commun. 85159–161 (1991).

[CrossRef]

S. Bleher, C. Grebogi, and E. Ott, “Bifurcation to chaotic scattering,” Phys. D 46, 87–121 (1990).

[CrossRef]

G. Gouesbet, G. Gréhan, and B. Maheu, “A localized approximation to compute all the coefficients gnm in the generalized Lorenz–Mie theory,” J. Opt. Soc. Am. A 7, 998–1007 (1990).

[CrossRef]

J. B. Guidt, G. Gouesbet, and J. N. Le Toulouzan, “An accurate validation of visible infra-red double extinction simultaneous measurements of particle sizes and number-densities by using densely laden standard media,” Appl. Opt. 29, 1011–1022 (1990).

[CrossRef]

C. Jung and S. Pott, “Classical cross section for chaotic potential scattering,” J. Phys. A 22, 2925–2938 (1989).

[CrossRef]

J. P. Barton, D. R. Alexander, and S. A. Schaub, “Internal fields of a spherical particle illuminated by a tightly focused laser beam: focal point positioning effects at resonance,” J. Appl. Phys. 65, 2900–2906 (1989).

[CrossRef]

J. P. Barton, D. R. Alexander, and S. A. Schaub, “Theoretical determination of net radiation force and torque for a spherical particle illuminated by a focused laser beam,” J. Appl. Phys. 66, 4594–4602 (1989).

[CrossRef]

J. P. Barton, D. R. Alexander, and S. A. Schaub, “Internal and near-surface electromagnetic fields for a spherical particle irradiated by a focused laser beam,” J. Appl. Phys. 64, 1632–1639 (1988).

[CrossRef]

B. Maheu, G. Gouesbet, and G. Gréhan, “A concise presentation of the generalized Lorenz–Mie theory for arbitrary location of the scatterer in an arbitrary incident profile,” J. Opt. 19, 59–67 (1988).

[CrossRef]

G. Gouesbet, G. Gréhan, and B. Maheu, “Expressions to compute the coefficients gnm in the generalized Lorenz–Mie theory, using finite series,” J. Opt. 19, 35–48 (1988).

[CrossRef]

G. Gouesbet, B. Maheu, and G. Gréhan, “Light scattering from a sphere arbitrarily located in a Gaussian beam, using a Bromwich formulation,” J. Opt. Soc. Am. A 5, 1427–1443 (1988).

[CrossRef]

G. Gouesbet, G. Gréhan, and B. Maheu, “Computations of the gn coefficients in the generalized Lorenz–Mie theory using three different methods,” Appl. Opt. 27, 4874–4883 (1988).

[CrossRef]

G. Gréhan, B. Maheu, and G. Gouesbet, “Scattering of laser beams by Mie scatter centers: numerical results using a localized approximation,” Appl. Opt. 25, 3539–3548 (1986).

[CrossRef]

A. Ashkin, J. M. Dziedzic, J. E. Bjorkholm, and S. Chu, “Observation of a single beam gradient force optical trap for dielectric particles,” Opt. Lett. 11, 288–290 (1986).

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J. S. Kim and S. S. Lee, “Scattering of laser beam and the optical potential well for a homogeneous sphere,” J. Opt. Soc. Am. A 73, 303–312 (1983).

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J. H. Bruning and Y. T. Lo, “Multiple scattering of EM waves by spheres part 1—Multipole expansion and ray-optical solutions,” IEEE Trans. Antennas Propag. AP-19, 378–389 (1971).

[CrossRef]

Y. Yeh and H. Cummins, “Localized fluid flow measurements with a He–Ne laser spectrometer,” Appl. Phys. Lett. 4, 176–178 (1964).

[CrossRef]

C. Yeh, “The diffraction of waves by a penetrable ribbon,” J. Math. Phys. 4, 65–71 (1963).

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B. Richards and E. Wolf, “Electromagnetic diffraction in optical systems. II. Structure of the image field in an aplanatic system,” Proc. R. Soc. London Ser. A 253, 358–379 (1959).

[CrossRef]

L. C. Biedenharn and M. E. Rose, “Theory of angular correlations of nuclear radiations,” Rev. Mod. Phys. 25, 729–777 (1953).

[CrossRef]

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[CrossRef]

L. L. Foldy, “The multiple scattering of waves,” Phys. Rev. E 67, 107–119 (1945).

[CrossRef]

F. E. Borgnis, “Elektromagnetische Eigenschwingungen dielektrischer Raüme,” Ann. Phys. 35, 359–384 (1939).

[CrossRef]

T. J. Bromwich, “Electromagnetic waves,” Philos. Mag. 38, 143–164 (1919).

[CrossRef]

P. Debye, “Das elektromagnetische Feld um einen Zylinder und die Theorie des Regenbogens,” Phys. Zeitung 9, 775–778(1908).

H. E. Albrecht, M. Borys, N. Damaschke, and C. Tropea, Laser Doppler and Phase Doppler Measurement (Springer, 2003).

J. P. Barton, D. R. Alexander, and S. A. Schaub, “Internal fields of a spherical particle illuminated by a tightly focused laser beam: focal point positioning effects at resonance,” J. Appl. Phys. 65, 2900–2906 (1989).

[CrossRef]

J. P. Barton, D. R. Alexander, and S. A. Schaub, “Theoretical determination of net radiation force and torque for a spherical particle illuminated by a focused laser beam,” J. Appl. Phys. 66, 4594–4602 (1989).

[CrossRef]

J. P. Barton, D. R. Alexander, and S. A. Schaub, “Internal and near-surface electromagnetic fields for a spherical particle irradiated by a focused laser beam,” J. Appl. Phys. 64, 1632–1639 (1988).

[CrossRef]

L. A. Ambrosio and H. E. Hernandez-Figueroa, “Integral localized approximation description of ordinary Bessel beams and application to optical trapping forces,” Biomed. Opt. Express 2, 1893–1906 (2011).

[CrossRef]

L. A. Ambrosio and H. E. Hernandez-Figueroa, “Spin angular momentum transfer from TEM00 focused Gaussian beams to negative refractive index spherical particles,” Biomed. Opt. Express 2, 2354–2363 (2011).

[CrossRef]

L. A. Ambrosio and H. E. Hernandez-Figueroa, “Radiation pressure cross sections and optical forces over negative refractive index spherical particles by ordinary Bessel beams,” Appl. Opt. 50, 4489–4498 (2011).

[CrossRef]

L. A. Ambrosio and H. E. Hernandez-Figueroa, “Fundamentals of negative refractive index optical trapping: Forces and radiation pressures exerted by focused Gaussian beams using the generalized Lorenz–Mie theory,” Biomed. Opt. Express 1, 1284–1301 (2010).

[CrossRef]

Y. Harada and T. Asakura,” Radiation forces on a dielectric sphere in the Rayleigh scattering regime,” Opt. Commun. 124, 529–541 (1996).

[CrossRef]

H. Y. Li, Z. S. Wu, and L. Bai, “Scattering for charged multisphere structure located in plane wave/Gaussian beam,” J. Electromagn. Waves Appl. 24, 2037–2047 (2010).

S. Bakic, F. Xu, N. Damaschke, and C. Tropea, “Feasibility of extending rainbow refractometry to small particles using femtosecond laser pulses,” Part. Part. Syst. Charact. 26, 34–40 (2009).

[CrossRef]

S. Bakic, C. Heinisch, N. Damaschke, T. Tschudi, and C. Tropea, “Time integrated detection of femtosecond laser pulses scattered by small droplets,” Appl. Opt. 47, 523–530(2008).

[CrossRef]

E. E. M. Khaled, S. C. Hill, and P. W. Barber, “Internal electric energy in a spherical particle illuminated with a plane wave or off-axis Gaussian beam,” Appl. Opt. 33, 524–532 (1994).

[CrossRef]

E. E. M. Khaled, S. C. Hill, and P. W. Barber, “Scattered and internal intensity of a sphere illuminated with a Gaussian beam,” IEEE Trans. Antennas Propag. 41, 295–303 (1993).

[CrossRef]

E. E. M. Khaled, S. C. Hill, P. W. Barber, and D. Q. Chowdhury, “Near-resonance excitation of dielectric spheres with plane waves and off-axis Gaussian beams,” Appl. Opt. 31, 1166–1169 (1992).

[CrossRef]

C. W. Yeh, S. Colak, and P. W. Barber, “Scattering of sharply focused beam by arbitrarily shaped dielectric particles: an exact solution,” Appl. Opt. 21, 4426–4433 (1982).

[CrossRef]

A. A. R. Neves, A. Fontes, L. D. Y. Pozzo, A. A. de Thomas, E. Chillce, E. Rodriguez, L. C. Barbosa, and C. L. Cesar, “Electromagnetic forces for an arbitrary optical trapping of a spherical dielectric,” Opt. Express 14, 13101–13106 (2006).

[CrossRef]

A. A. R. Neves, A. Fontes, L. A. Padilha, E. Rodriguez, C. H de Brito Cruz, L. C. Barbosa, and C. L. Cesar, “Exact partial wave expansion of optical beams with respect to an arbitrary origin,” Opt. Lett. 31, 2477–2479 (2006).

[CrossRef]

A. A. R. Neves, L. A. Padilha, A. Fontes, E. Rodriguez, C. H. B. Cruz, L. C. Barbosa, and C. L. Cesar, “Analytical results for a Bessel function times Legendre polynomials class integrals, J. Phys. A 39, L293–L296 (2006).

[CrossRef]

J. P. Barton, “Internal and near-surface electromagnetic fields for an infinite cylinder illuminated by an arbitrary focused beam,” J. Opt. Soc. Am. A 16, 160–166(1999).

[CrossRef]

J. P. Barton, D. R. Alexander, and S. A. Schaub, “Theoretical determination of net radiation force and torque for a spherical particle illuminated by a focused laser beam,” J. Appl. Phys. 66, 4594–4602 (1989).

[CrossRef]

J. P. Barton, D. R. Alexander, and S. A. Schaub, “Internal fields of a spherical particle illuminated by a tightly focused laser beam: focal point positioning effects at resonance,” J. Appl. Phys. 65, 2900–2906 (1989).

[CrossRef]

J. P. Barton, D. R. Alexander, and S. A. Schaub, “Internal and near-surface electromagnetic fields for a spherical particle irradiated by a focused laser beam,” J. Appl. Phys. 64, 1632–1639 (1988).

[CrossRef]

G. Gouesbet and A. Berlemont, “Eulerian and Lagrangian approaches for predicting the behaviour of discrete particles in turbulent flows,” Prog. Energy Combust. Sci. 25, 133–159(1999).

[CrossRef]

L. C. Biedenharn and M. E. Rose, “Theory of angular correlations of nuclear radiations,” Rev. Mod. Phys. 25, 729–777 (1953).

[CrossRef]

S. Bleher, C. Grebogi, and E. Ott, “Bifurcation to chaotic scattering,” Phys. D 46, 87–121 (1990).

[CrossRef]

P. Torok, R. Varga, and G. R. Booker, “Electromagnetic diffraction of light focused through a planar interface between materials of mismatched refractive indices: Structure of the electromagnetic field. I,” J. Opt. Soc. Am. A 12, 2136–2144 (1995).

[CrossRef]

P. Torok, P. Varga, Z. Laczik, and G. R. Booker, “Electromagnetic diffraction of light focused through a planar interface between materials of mismatched refractive indices: An integral representation,” J. Opt. Soc. Am. A 12, 325–332 (1995).

[CrossRef]

F. E. Borgnis, “Elektromagnetische Eigenschwingungen dielektrischer Raüme,” Ann. Phys. 35, 359–384 (1939).

[CrossRef]

H. E. Albrecht, M. Borys, N. Damaschke, and C. Tropea, Laser Doppler and Phase Doppler Measurement (Springer, 2003).

L. Boyde, K. J. Chalut, and J. Guck, “Near- and far-field scattering from arbitrary three-dimensional aggregates of coated spheres using parallel computing,” Phys. Rev. E 83, 026701 (2011).

[CrossRef]

L. Boyde, K. J. Chalut, and J. Guck, “Exact analytical expansion of an off-axis Gaussian laser beam using the translation theorems for the vector spherical harmonics,” Appl. Opt. 50, 1023–1033 (2011).

[CrossRef]

T. J. Bromwich, “Electromagnetic waves,” Philos. Mag. 38, 143–164 (1919).

[CrossRef]

J. H. Bruning and Y. T. Lo, “Multiple scattering of EM waves by spheres part 1—Multipole expansion and ray-optical solutions,” IEEE Trans. Antennas Propag. AP-19, 378–389 (1971).

[CrossRef]

F. Xu, K. F. Ren, G. Gouesbet, G. Gréhan, and X. Cai, “Generalized Lorenz–Mie theory for an arbitrarily oriented, located and shaped beam scattering by a homogeneous spheroid,” J. Opt. Soc. Am. A 24, 119–131 (2007).

[CrossRef]

F. Xu, K. F. Ren, G. Gouesbet, X. Cai, and G. Gréhan, “Theoretical prediction of radiation pressure force exerted on a spheroid by an arbitrarily shaped beam,” Phys. Rev. E 75, 026613 (2007).

[CrossRef]

A. A. R. Neves, A. Fontes, C. L. Cesar, A. Camposeo, R. Cingolani, and D. Pisignano, “Axial optical trapping efficiency through a dielectric interface,” Phys. Rev. E 76, 061917 (2007).

[CrossRef]

A. A. R. Neves, A. Fontes, C. L. Cesar, A. Camposeo, R. Cingolani, and D. Pisignano, “Axial optical trapping efficiency through a dielectric interface,” Phys. Rev. E 76, 061917 (2007).

[CrossRef]

A. A. R. Neves, L. A. Padilha, A. Fontes, E. Rodriguez, C. H. B. Cruz, L. C. Barbosa, and C. L. Cesar, “Analytical results for a Bessel function times Legendre polynomials class integrals, J. Phys. A 39, L293–L296 (2006).

[CrossRef]

A. A. R. Neves, A. Fontes, L. A. Padilha, E. Rodriguez, C. H de Brito Cruz, L. C. Barbosa, and C. L. Cesar, “Exact partial wave expansion of optical beams with respect to an arbitrary origin,” Opt. Lett. 31, 2477–2479 (2006).

[CrossRef]

A. A. R. Neves, A. Fontes, L. D. Y. Pozzo, A. A. de Thomas, E. Chillce, E. Rodriguez, L. C. Barbosa, and C. L. Cesar, “Electromagnetic forces for an arbitrary optical trapping of a spherical dielectric,” Opt. Express 14, 13101–13106 (2006).

[CrossRef]

L. Boyde, K. J. Chalut, and J. Guck, “Exact analytical expansion of an off-axis Gaussian laser beam using the translation theorems for the vector spherical harmonics,” Appl. Opt. 50, 1023–1033 (2011).

[CrossRef]

L. Boyde, K. J. Chalut, and J. Guck, “Near- and far-field scattering from arbitrary three-dimensional aggregates of coated spheres using parallel computing,” Phys. Rev. E 83, 026701 (2011).

[CrossRef]

A. Kamor, F. Mauger, C. Chandre, and T. Uzer, “Annular billiard dynamics in a circularly polarized strong laser field,” Phys. Rev. E 85, 016204 (2012).

[CrossRef]

A. Mekis, J. U. Nöckel, G. Chen, A. D. Stone, and R. K. Chang, “Ray chaos and Q spoiling in lasing droplets,” Phys. Rev. Lett. 75, 2682–2685 (1995).

[CrossRef]

J. U. Nöckel, A. D. Stone, and R. K. Chang, “Q-spoiling and directionality in deformed ring cavities,” Opt. Lett. 19, 1693–1695 (1994).

[CrossRef]

A. Mekis, J. U. Nöckel, G. Chen, A. D. Stone, and R. K. Chang, “Ray chaos and Q spoiling in lasing droplets,” Phys. Rev. Lett. 75, 2682–2685 (1995).

[CrossRef]

L. P. Su, S. Y. Chen, W. J. Zhao, and D. M. Ren, “Scattering properties of ultrashort laser pulses by air bubbles in the sea water,” Proc. SPIE 8192, 81922K (2011).

[CrossRef]

A. A. R. Neves, A. Fontes, L. D. Y. Pozzo, A. A. de Thomas, E. Chillce, E. Rodriguez, L. C. Barbosa, and C. L. Cesar, “Electromagnetic forces for an arbitrary optical trapping of a spherical dielectric,” Opt. Express 14, 13101–13106 (2006).

[CrossRef]

A. A. R. Neves, A. Fontes, C. L. Cesar, A. Camposeo, R. Cingolani, and D. Pisignano, “Axial optical trapping efficiency through a dielectric interface,” Phys. Rev. E 76, 061917 (2007).

[CrossRef]

C. W. Yeh, S. Colak, and P. W. Barber, “Scattering of sharply focused beam by arbitrarily shaped dielectric particles: an exact solution,” Appl. Opt. 21, 4426–4433 (1982).

[CrossRef]

S. Colak, C. Yeh, and L. W. Casperson, “Scattering of focused beams by tenuous particles,” Appl. Opt. 18, 294–302(1979).

[CrossRef]

F. Corbin, G. Gréhan, and G. Gouesbet, “Top-hat beam technique: improvements and application to bubble measurements,” Part. Part. Syst. Charact. 8, 222–228 (1991).

[CrossRef]

A. A. R. Neves, L. A. Padilha, A. Fontes, E. Rodriguez, C. H. B. Cruz, L. C. Barbosa, and C. L. Cesar, “Analytical results for a Bessel function times Legendre polynomials class integrals, J. Phys. A 39, L293–L296 (2006).

[CrossRef]

Y. P. Han, Z. W. Cui, and G. Gouesbet, “Numerical simulation of Gaussian beam scattering by complex particles of arbitrary shape and structure,” J. Quant. Spectrosc. Radiat. Transfer 113, 1719–1727 (2012).

[CrossRef]

Y. Yeh and H. Cummins, “Localized fluid flow measurements with a He–Ne laser spectrometer,” Appl. Phys. Lett. 4, 176–178 (1964).

[CrossRef]

S. Bakic, F. Xu, N. Damaschke, and C. Tropea, “Feasibility of extending rainbow refractometry to small particles using femtosecond laser pulses,” Part. Part. Syst. Charact. 26, 34–40 (2009).

[CrossRef]

S. Bakic, C. Heinisch, N. Damaschke, T. Tschudi, and C. Tropea, “Time integrated detection of femtosecond laser pulses scattered by small droplets,” Appl. Opt. 47, 523–530(2008).

[CrossRef]

H. E. Albrecht, M. Borys, N. Damaschke, and C. Tropea, Laser Doppler and Phase Doppler Measurement (Springer, 2003).

V. Daniels, M. Vallières, and J. M. Yuan, “Chaotic scattering on a double well: periodic orbits, symbolic dynamics, and scaling,” Chaos 3, 475–485 (1993).

[CrossRef]

L. W. Davis, “Theory of electromagnetic beams,” Phys. Rev. 19, 1177–1179 (1979).

[CrossRef]

A. A. R. Neves, A. Fontes, L. D. Y. Pozzo, A. A. de Thomas, E. Chillce, E. Rodriguez, L. C. Barbosa, and C. L. Cesar, “Electromagnetic forces for an arbitrary optical trapping of a spherical dielectric,” Opt. Express 14, 13101–13106 (2006).

[CrossRef]

P. Debye, “Das elektromagnetische Feld um einen Zylinder und die Theorie des Regenbogens,” Phys. Zeitung 9, 775–778(1908).

R. P. Ratowsky, L. Yang, R. J. Deri, K. W. Chang, J. S. Kallman, and G. Trott, “Laser diode to single-mode fiber ball lens coupling efficiency: full-wave calculation and measurements,” Appl. Opt. 36, 3435–3438 (1997).

[CrossRef]

R. P. Ratowsky, L. Yang, R. J. Deri, J. S. Kallman, and G. Trott, “Ball lens reflections by direct solution of Maxwell’s equations,” Opt. Lett. 20, 2048–2050 (1995).

[CrossRef]

A. Doicu and T. Wriedt, “Plane wave spectrum of electromagnetic beams,” Opt. Commun. 136, 114–124 (1997).

[CrossRef]

A. Doicu and T. Wriedt, “Computation of the beam-shape-coefficients in the generalized Lorenz–Mie theory by using the translational addition theorem for spherical vector wave functions,” Appl. Opt. 36, 2971–2978 (1997).

[CrossRef]

A. Doicu, T. Wriedt, and Y. A. Eremin, Light Scattering by Systems of Particles (Springer, 2006).

L. E. Drain, The Laser Doppler Technique (Wiley, 1980).

Y. G. Du, Y. P. Han, G. X. Han, and J. J. Li, “Theoretical study on the rotation of particles driven by Gaussian beam,” Acta Phys. Sinica 60, 028702 (2011).

G. Gréhan, G. Gouesbet, A. Naqwi, and F. Durst, “Trajectory ambiguities in phase-Doppler systems: study of a near-forward and a near-backward geometry,” Part. Part. Syst. Charact. 11, 133–144 (1994).

[CrossRef]

G. Gréhan, K. F. Ren, G. Gouesbet, A. Naqwi, and F. Durst, “Evaluation of a particle sizing technique based on laser sheets,” Part. Part. Syst. Charact. 11, 101–106 (1994).

[CrossRef]

G. Gréhan, G. Gouesbet, A. Naqwi, and F. Durst, “Particle trajectory effects in phase-Doppler systems: computations and experiments,” Part. Part. Syst. Charact. 10, 332–338 (1993).

[CrossRef]

F. Durst, A. Melling, and J. H. Whitelaw, Principles and Practice of Laser-Doppler Anemometry (Academic, 1981).

A. Doicu, T. Wriedt, and Y. A. Eremin, Light Scattering by Systems of Particles (Springer, 2006).

C. Flammer, “Spheroidal Wave Functions (Dover, 2005).

L. L. Foldy, “The multiple scattering of waves,” Phys. Rev. E 67, 107–119 (1945).

[CrossRef]

A. A. R. Neves, A. Fontes, C. L. Cesar, A. Camposeo, R. Cingolani, and D. Pisignano, “Axial optical trapping efficiency through a dielectric interface,” Phys. Rev. E 76, 061917 (2007).

[CrossRef]

A. A. R. Neves, L. A. Padilha, A. Fontes, E. Rodriguez, C. H. B. Cruz, L. C. Barbosa, and C. L. Cesar, “Analytical results for a Bessel function times Legendre polynomials class integrals, J. Phys. A 39, L293–L296 (2006).

[CrossRef]

A. A. R. Neves, A. Fontes, L. A. Padilha, E. Rodriguez, C. H de Brito Cruz, L. C. Barbosa, and C. L. Cesar, “Exact partial wave expansion of optical beams with respect to an arbitrary origin,” Opt. Lett. 31, 2477–2479 (2006).

[CrossRef]

A. A. R. Neves, A. Fontes, L. D. Y. Pozzo, A. A. de Thomas, E. Chillce, E. Rodriguez, L. C. Barbosa, and C. L. Cesar, “Electromagnetic forces for an arbitrary optical trapping of a spherical dielectric,” Opt. Express 14, 13101–13106 (2006).

[CrossRef]

G. Gortzel, “Angular correlation of gamma rays,” Phys. Rev., Appendix 1 70, 897–909 (1946).

[CrossRef]

G. Gouesbet and J. J. Wang, “On the structures of some light scattering theories depending on whether or not the Bromwich formulation may be used, e.g., spherical versus spheroidal coordinates,” Opt. Commun. 285, 4200–4206 (2012).

[CrossRef]

Y. P. Han, Z. W. Cui, and G. Gouesbet, “Numerical simulation of Gaussian beam scattering by complex particles of arbitrary shape and structure,” J. Quant. Spectrosc. Radiat. Transfer 113, 1719–1727 (2012).

[CrossRef]

J. J. Wang and G. Gouesbet, “Note on the use of localized beam models for light scattering theories in spherical coordinates,” Appl. Opt. 51, 3832–3836 (2012).

[CrossRef]

J. J. Wang, G. Gouesbet, Y. P. Han, and G. Gréhan, “Study of scattering from a sphere with an eccentrically located spherical inclusion by generalized Lorenz–Mie theory: internal and external field distributions,” J. Opt. Soc. Am. A 28, 24–39 (2011).

[CrossRef]

G. Gouesbet, F. Xu, and Y. P. Han, “Expanded description of electromagnetic arbitrary shaped beam in spheroidal coordinates for use in light scattering theories: A review,” J. Quant. Spectrosc. Radiat. Transfer 112, 2249–2267 (2011).

[CrossRef]

G. Gouesbet, J. A. Lock, and G. Gréhan, “Generalized Lorenz–Mie theories and description of electromagnetic arbitrary shaped beams: localized approximations and localized beam models,” J. Quant. Spectrosc. Radiat. Transfer 112, 1–27 (2011).

[CrossRef]

G. Gouesbet, J. A. Lock, J. J. Wang, and G. Gréhan, “Transformations of spherical beam shape coefficients in general Lorenz–Mie theories through rotations of coordinate system: V. Localized beam models,” Opt. Commun. 284, 411–417 (2011).

[CrossRef]

J. J. Wang, G. Gouesbet, G. Gréhan, and S. Saengkaew, “Morphology-dependent resonances in an eccentrically layered sphere illuminated by a tightly focused off-axis Gaussian beam,” J. Opt. Soc. Am. A 28, 1849–1859 (2011).

[CrossRef]

G. Gouesbet, J. J. Wang, and Y. P. Han, “Transformations of spherical beam shape coefficients in general Lorenz–Mie theories through rotations of coordinate system. I General formulation,” Opt. Commun. 283, 3218–3225 (2010).

[CrossRef]

G. Gouesbet, J. J. Wang, and Y. P. Han, “Transformations of spherical beam shape coefficients in general Lorenz–Mie theories through rotations of coordinate system: III. Special values of Euler angles,” Opt. Commun. 283, 3235–3243 (2010).

[CrossRef]

G. Gouesbet, “T-matrix formulation and generalized Lorenz–Mie theories in spherical coordinates, “Opt. Commun. 283, 517–521 (2010).

[CrossRef]

G. Gouesbet, J. J. Wang, and Y. P. Han, “Transformations of spherical beam shape coefficients in general Lorenz–Mie theories through rotations of coordinate system: IV. Plane waves,” Opt. Commun. 283, 3244–3254 (2010).

[CrossRef]

J. J. Wang, G. Gouesbet, and Y. P. Han, “Transformations of spherical beam shape coefficients in general Lorenz–Mie theories through rotations of coordinate system: II. Axisymmetric beams,” Opt. Commun. 283, 3226–3234 (2010).

[CrossRef]

F. Xu, J. A. Lock, and G. Gouesbet, “Debye series for light scattering by a nonspherical particle,” Phys. Rev. A 81, 043824 (2010).

[CrossRef]

J. A. Lock and G. Gouesbet, “Generalized Lorenz–Mie theory and applications,” J. Quant. Spectrosc. Radiat. Transfer 110, 800–807 (2009).

[CrossRef]

L. Méès, G. Gouesbet, and G. Gréhan, “Transient internal and scattered fields from a multi-layered sphere illuminated by a pulsed laser,” Opt. Commun. 282, 4189–4193 (2009).

[CrossRef]

F. Xu, J. A. Lock, G. Gouesbet, and C. Tropea, “Optical stress on the surface of a particle: I. Homogeneous sphere,” Phys. Rev. A 79, 053808 (2009).

[CrossRef]

G. Gouesbet, “Generalized Lorenz–Mie theories, the third decade: a perspective,” J. Quant. Spectrosc. Radiat. Transfer 110, 1223–1238 (2009).

[CrossRef]

F. Xu, J. A. Lock, G. Gouesbet, and C. Tropea, “Radiation torque exerted on a spheroid: analytical solution,” Phys. Rev. A 78, 013843 (2008).

[CrossRef]

F. Xu, K. F. Ren, G. Gouesbet, X. Cai, and G. Gréhan, “Theoretical prediction of radiation pressure force exerted on a spheroid by an arbitrarily shaped beam,” Phys. Rev. E 75, 026613 (2007).

[CrossRef]

F. Xu, K. F. Ren, G. Gouesbet, G. Gréhan, and X. Cai, “Generalized Lorenz–Mie theory for an arbitrarily oriented, located and shaped beam scattering by a homogeneous spheroid,” J. Opt. Soc. Am. A 24, 119–131 (2007).

[CrossRef]

Y. P. Han, L. Mees, G. Gouesbet, Z. S. Wu, and G. Gréhan, “Resonant spectra of a deformed spherical microcavity,” J. Opt. Soc. Am. B 23, 1390–1397 (2006).

[CrossRef]

G. Gouesbet and L. Méès, “Generalized Lorenz–Mie theory for infinitely long cylinders with elliptical cross-sections. Erratum,” J. Opt. Soc. Am. A 22, 574–575 (2005).

[CrossRef]

Y. P. Han, L. Mees, K. F. Ren, G. Gréhan, Z. S. Wu, and G. Gouesbet, “Far scattered field from a spheroid under a femtosecond pulsed illumination in a generalized Lorenz–Mie theory framework,” Opt. Commun. 231, 71–77 (2004).

[CrossRef]

Y. P. Han, G. Gréhan, and G. Gouesbet, “Generalized Lorenz–Mie theory for a spheroidal particle with off-axis Gaussian beam illumination,” Appl. Opt. 42, 6621–6629 (2003).

[CrossRef]

G. Gouesbet, “Debye series formulation for generalized Lorenz–Mie theory with the Bromwich method,” Part. Part. Syst. Charact. 20, 382–386 (2003).

[CrossRef]

Y. P. Han, L. Mees, K. F. Ren, G. Gouesbet, S. Z. Wu, and G. Gréhan, “Scattering of light by spheroids: the far field case,” Opt. Commun. 210, 1–9 (2002).

[CrossRef]

L. Méès, G. Gouesbet, and G. Gréhan, “Numerical predictions of microcavity internal fields created by femtosecond pulses, with emphasis on whispering gallery modes,” J. Opt. A 4, 8150–8153 (2002).

G. Gouesbet, S. Meunier-Guttin-Cluzel, and G. Gréhan, “Morphologydependent resonances and/or whispering gallery modes for a two-dimensional dielectric cavity with an eccentrically located spherical inclusion, a Hamiltonian point of view with Hamiltonian (optical) chaos,” Opt. Commun. 201, 223–242 (2002).

[CrossRef]

L. Méès, J. P. Wolf, G. Gouesbet, and G. Gréhan, “Two-photon absorption and fluorescence in a spherical micro-cavity illuminated by using two laser pulses: numerical simulations,” Opt. Commun. 208, 371–375 (2002).

[CrossRef]

L. Méès, G. Gréhan, and G. Gouesbet, “Time-resolved scattering diagrams for a sphere illuminated by plane wave and focused short pulses,” Opt. Commun. 194, 59–65 (2001).

[CrossRef]

G. Gouesbet, S. Meunier-Guttin-Cluzel, and G. Gréhan, “Periodic orbits in Hamiltonian chaos of the annular billiard,” Phys. Rev. E 65, 016212 (2001).

[CrossRef]

G. Gouesbet, S. Meunier-Guttin-Cluzel, and G. Gréhan, “Generalized Lorenz–Mie theory for a sphere with an eccentrically located spherical inclusion, and optical chaos,” Part. Part. Syst. Charact. 18, 190–195 (2001).

[CrossRef]

L. Méès, G. Gouesbet, and G. Gréhan, “Scattering of laser pulses (plane wave and focused Gaussian beams) by spheres,” Appl. Opt. 40, 2546–2550 (2001).

[CrossRef]

H. Polaert, G. Gouesbet, and G. Gréhan, “Laboratory determination of beam shape coefficients for use in generalized Lorenz–Mie theory,” Appl. Opt. 40, 1699–1706 (2001).

[CrossRef]

L. Méès, G. Gouesbet, and G. Gréhan, “Interaction between femtosecond pulses and a spherical microcavity: internal fields,” Opt. Commun. 199, 33–38 (2001).

[CrossRef]

G. Gouesbet and G. Gréhan, “Generic formulation of a generalized Lorenz–Mie theory for a particle illuminated by laser pulses,” Part. Part. Syst. Charact. 17, 213–224 (2000).

[CrossRef]

G. Gouesbet and G. Gréhan, “Generalized Lorenz–Mie theories, from past to future,” Atomization Sprays 10, 277–333 (2000).

[CrossRef]

G. Gouesbet and G. Gréhan, “Generalized Lorenz–Mie theory for a sphere with an eccentrically located spherical inclusion,” J. Mod. Opt. 47, 821–837 (2000).

G. Gouesbet, C. Rozé, and S. Meunier-Guttin-Cluzel, “Instabilities by local heating below an interface, a review,” J. Nonequilib. Thermodyn. 25, 337–379 (2000).

[CrossRef]

G. Gouesbet, L. Mees, G. Gréhan, and K. F. Ren, “Description of arbitrary shaped beams in elliptical cylinder coordinates by using a plane wave spectrum approach,” Opt. Commun. 161, 63–78 (1999).

[CrossRef]

G. Gouesbet and A. Berlemont, “Eulerian and Lagrangian approaches for predicting the behaviour of discrete particles in turbulent flows,” Prog. Energy Combust. Sci. 25, 133–159(1999).

[CrossRef]

G. Gouesbet, “Validity of the cylindrical localized approximation for arbitrary shaped beams in generalized Lorenz–Mie theory for circular cylinders,” J. Mod. Opt. 46, 1185–1200 (1999).

G. Gouesbet and L. Méès, “Generalized Lorenz–Mie theory for infinitely long elliptical cylinders,” J. Opt. Soc. Am. A 16, 1333–1341 (1999).

[CrossRef]

L. Méès, K. F. Ren, G. Gréhan, and G. Gouesbet, “Scattering of a Gaussian beam by an infinite cylinder with arbitrary location and arbitrary orientation: numerical results,” Appl. Opt. 38, 1867–1876 (1999).

[CrossRef]

G. Gouesbet and G. Gréhan, “Generalized Lorenz–Mie theory for assemblies of spheres and aggregates,” J. Opt. A 1, 706–712 (1999).

[CrossRef]

G. Gouesbet, “Validity of the localized approximation for arbitrary shaped beams in generalized Lorenz–Mie theory for spheres,” J. Opt. Soc. Am. A 16, 1641–1650 (1999).

[CrossRef]

G. Gouesbet and L. Méès, “Validity of the elliptical cylinder localized approximation for arbitrary shaped beams in generalized Lorenz–Mie theory for elliptical cylinders,” J. Opt. Soc. Am. A 16, 2946–2958 (1999).

[CrossRef]

G. Gouesbet, “Theory of distributions and its application to beam parametrization in light scattering,” Part. Part. Syst. Charact. 16, 147–159 (1999).

[CrossRef]

K. F. Ren, G. Gouesbet, and G. Gréhan, “Integral localized approximation in generalized Lorenz–Mie theory,” Appl. Opt. 37, 4218–4225 (1998).

[CrossRef]

G. Gouesbet, L. Méès, and G. Gréhan, “Partial-wave description of shaped beams in elliptical-cylinder coordinates,” J. Opt. Soc. Am. A 15, 3028–3038 (1998).

[CrossRef]

H. Polaert, G. Gouesbet, and G. Gréhan, “Measurements of beam shape coefficients in the generalized Lorenz–Mie theory for the on-axis case: numerical simulations,” Appl. Opt. 37, 5005–5013 (1998).

[CrossRef]

H. Polaert, G. Gréhan, and G. Gouesbet, “Forces and torques exerted on a multilayered spherical particle by a focused Gaussian beam,” Opt. Commun. 155, 169–179 (1998).

[CrossRef]

G. Gouesbet, “Measurements of beam shape coefficients in generalized Lorenz–Mie theory and the density-matrix approach: II. The density matrix approach,” Part. Part. Syst. Charact. 14, 88–92 (1997).

Z. S. Wu, L. X. Guo, K. F. Ren, G. Gouesbet, and G. Gréhan, “Improved algorithms for electromagnetic scattering of plane waves and shaped beams by multilayered spheres,” Appl. Opt. 36, 5188–5198 (1997).

[CrossRef]

G. Gouesbet, “Interaction between an infinite cylinder and an arbitrary shaped beam,” Appl. Opt. 36, 4292–4304 (1997).

[CrossRef]

G. Gouesbet,” Measurements of beam shape coefficients in generalized Lorenz–Mie theory and the density-matrix approach: I. Measurements,” Part. Part. Syst. Charact. 14, 12–20 (1997).

K. F. Ren, G. Gréhan, and G. Gouesbet, “Scattering of a Gaussian beam by an infinite cylinder in the framework of a GLMT, formulation and numerical results,” J. Opt. Soc. Am. A 14, 3014–3025 (1997).

[CrossRef]

E. Lenglart and G. Gouesbet, “The separability ‘theorem’ in terms of distributions with discussion of electromagnetic scattering theory,” J. Math. Phys. 37, 4705–4710 (1996).

[CrossRef]

G. Gouesbet, “Exact description of arbitrary shaped beams for use in light scattering theories,” J. Opt. Soc. Am. A 13, 2434–2440 (1996).

[CrossRef]

G. Gouesbet, C. Letellier, K. F. Ren, and G. Gréhan, “Discussion of two quadrature methods of evaluating beam shape coefficients in generalized Lorenz–Mie theory,” Appl. Opt. 35, 1537–1542 (1996).

[CrossRef]

G. Gouesbet, “Partial wave expansions and properties of axisymmetric light beams,” Appl. Opt. 35, 1543–1555(1996).

[CrossRef]

F. Onofri, G. Gréhan, and G. Gouesbet, “Electromagnetic scattering from a multilayered sphere located in an arbitrary beam,” Appl. Opt. 34, 7113–7124 (1995).

[CrossRef]

G. Gouesbet, “Interaction between Gaussian beams and infinite cylinders, by using the theory of distributions,” J. Opt. 26, 225–239 (1995).

[CrossRef]

J. T. Hodges, G. Gréhan, G. Gouesbet, and C. Presser, “Forward scattering of a Gaussian beam by a nonabsorbing sphere,” Appl. Opt. 34, 2120–2132 (1995).

[CrossRef]

G. Gouesbet, J. A. Lock, and G. Gréhan, “Partial wave representations of laser beams for use in light scattering calculations,” Appl. Opt. 34, 2133–2143 (1995).

[CrossRef]

G. Gouesbet, “ The separability theorem revisited with applications to light scattering theory,” J. Opt. 26, 123–135 (1995).

[CrossRef]

G. Gouesbet, “Generalized Lorenz–Mie theory and applications,” Part. Part. Syst. Charact. 11, 22–34 (1994).

[CrossRef]

G. Gouesbet and G. Gréhan, “Interaction between shaped beams and an infinite cylinder, including a discussion of Gaussian beams,” Part. Part. Syst. Charact. 11, 299–308 (1994).

[CrossRef]

J. A. Lock and G. Gouesbet, “Rigorous justication of the localized approximation to the beam shape coefficients in generalized Lorenz–Mie. I. On-axis beams,” J. Opt. Soc. Am. A 11, 2503–2515 (1994).

[CrossRef]

K. F. Ren, G. Gréhan, and G. Gouesbet, “Electromagnetic field expression of a laser sheet and the order of approximation,” J. Opt. 25, 165–176 (1994).

[CrossRef]

G. Gouesbet and J. A. Lock, “Rigorous justication of the localized approximation to the beam shape coefficients in generalized Lorenz–Mie theory. II. Off-axis beams,” J. Opt. Soc. Am. A 11, 2516–2525 (1994).

[CrossRef]

G. Gréhan, K. F. Ren, G. Gouesbet, A. Naqwi, and F. Durst, “Evaluation of a particle sizing technique based on laser sheets,” Part. Part. Syst. Charact. 11, 101–106 (1994).

[CrossRef]

G. Gréhan, G. Gouesbet, A. Naqwi, and F. Durst, “Trajectory ambiguities in phase-Doppler systems: study of a near-forward and a near-backward geometry,” Part. Part. Syst. Charact. 11, 133–144 (1994).

[CrossRef]

K. F. Ren, G. Gréhan, and G. Gouesbet, “Laser sheet scattering by spherical particles,” Part. Part. Syst. Charact. 10, 146–151 (1993).

[CrossRef]

G. Gréhan, G. Gouesbet, A. Naqwi, and F. Durst, “Particle trajectory effects in phase-Doppler systems: computations and experiments,” Part. Part. Syst. Charact. 10, 332–338 (1993).

[CrossRef]

F. Corbin, G. Gréhan, and G. Gouesbet, “Top-hat beam technique: improvements and application to bubble measurements,” Part. Part. Syst. Charact. 8, 222–228 (1991).

[CrossRef]

J. B. Guidt, G. Gouesbet, and J. N. Le Toulouzan, “An accurate validation of visible infra-red double extinction simultaneous measurements of particle sizes and number-densities by using densely laden standard media,” Appl. Opt. 29, 1011–1022 (1990).

[CrossRef]

G. Gouesbet, G. Gréhan, and B. Maheu, “A localized approximation to compute all the coefficients gnm in the generalized Lorenz–Mie theory,” J. Opt. Soc. Am. A 7, 998–1007 (1990).

[CrossRef]

G. Gouesbet, G. Gréhan, and B. Maheu, “Expressions to compute the coefficients gnm in the generalized Lorenz–Mie theory, using finite series,” J. Opt. 19, 35–48 (1988).

[CrossRef]

G. Gouesbet, G. Gréhan, and B. Maheu, “Computations of the gn coefficients in the generalized Lorenz–Mie theory using three different methods,” Appl. Opt. 27, 4874–4883 (1988).

[CrossRef]

B. Maheu, G. Gouesbet, and G. Gréhan, “A concise presentation of the generalized Lorenz–Mie theory for arbitrary location of the scatterer in an arbitrary incident profile,” J. Opt. 19, 59–67 (1988).

[CrossRef]

G. Gouesbet, B. Maheu, and G. Gréhan, “Light scattering from a sphere arbitrarily located in a Gaussian beam, using a Bromwich formulation,” J. Opt. Soc. Am. A 5, 1427–1443 (1988).

[CrossRef]

G. Gréhan, B. Maheu, and G. Gouesbet, “Scattering of laser beams by Mie scatter centers: numerical results using a localized approximation,” Appl. Opt. 25, 3539–3548 (1986).

[CrossRef]

G. Gouesbet and G. Gréhan, “Sur la généralisation de la théorie de Lorenz–Mie,” J. Opt. 13, 97–103 (1982).

[CrossRef]

G. Gouesbet, “A scientific and sociological story of generalized Lorenz–Mie theories,” J. Quant. Spectrosc. Radiat. Transfer (to be published).

G. Gouesbet, L. Mees, and G. Gréhan, “Generic formulation of a generalized Lorenz–Mie theory for pulsed laser illumination,” in Laser Techniques for Fluid Mechanics, R. J. Adrian, D.F.G. Durao, Durst, M. V. Heitor, M. Maeda, C. Tropea, and J. H. Whitelaw, eds. (Springer, 2002), pp. 175–188.

G. Gouesbet, S. Meunier-Guttin-Cluzel, and O. Ménard, “Global reconstruction of equations of motion from data series, and validation techniques, a review,” in Chaos and Its Reconstruction (Novascience, 2003), pp. 1–160.

G. Gouesbet, G. Gréhan, and B. Maheu, “Generalized Lorenz–Mie theory and applications to optical sizing,” in Combustion Measurements, N. Chigier, ed. (Hemisphere, 1991), pp. 339–384.

G. Gouesbet and G. Gréhan, Generalized Lorenz–Mie Theories (Springer, 2011).

S. Bleher, C. Grebogi, and E. Ott, “Bifurcation to chaotic scattering,” Phys. D 46, 87–121 (1990).

[CrossRef]

J. J. Wang, G. Gouesbet, G. Gréhan, and S. Saengkaew, “Morphology-dependent resonances in an eccentrically layered sphere illuminated by a tightly focused off-axis Gaussian beam,” J. Opt. Soc. Am. A 28, 1849–1859 (2011).

[CrossRef]

G. Gouesbet, J. A. Lock, J. J. Wang, and G. Gréhan, “Transformations of spherical beam shape coefficients in general Lorenz–Mie theories through rotations of coordinate system: V. Localized beam models,” Opt. Commun. 284, 411–417 (2011).

[CrossRef]

G. Gouesbet, J. A. Lock, and G. Gréhan, “Generalized Lorenz–Mie theories and description of electromagnetic arbitrary shaped beams: localized approximations and localized beam models,” J. Quant. Spectrosc. Radiat. Transfer 112, 1–27 (2011).

[CrossRef]

J. J. Wang, G. Gouesbet, Y. P. Han, and G. Gréhan, “Study of scattering from a sphere with an eccentrically located spherical inclusion by generalized Lorenz–Mie theory: internal and external field distributions,” J. Opt. Soc. Am. A 28, 24–39 (2011).

[CrossRef]

L. Méès, G. Gouesbet, and G. Gréhan, “Transient internal and scattered fields from a multi-layered sphere illuminated by a pulsed laser,” Opt. Commun. 282, 4189–4193 (2009).

[CrossRef]

F. Xu, K. F. Ren, G. Gouesbet, X. Cai, and G. Gréhan, “Theoretical prediction of radiation pressure force exerted on a spheroid by an arbitrarily shaped beam,” Phys. Rev. E 75, 026613 (2007).

[CrossRef]

F. Xu, K. F. Ren, G. Gouesbet, G. Gréhan, and X. Cai, “Generalized Lorenz–Mie theory for an arbitrarily oriented, located and shaped beam scattering by a homogeneous spheroid,” J. Opt. Soc. Am. A 24, 119–131 (2007).

[CrossRef]

Y. P. Han, L. Mees, G. Gouesbet, Z. S. Wu, and G. Gréhan, “Resonant spectra of a deformed spherical microcavity,” J. Opt. Soc. Am. B 23, 1390–1397 (2006).

[CrossRef]

Y. P. Han, L. Mees, K. F. Ren, G. Gréhan, Z. S. Wu, and G. Gouesbet, “Far scattered field from a spheroid under a femtosecond pulsed illumination in a generalized Lorenz–Mie theory framework,” Opt. Commun. 231, 71–77 (2004).

[CrossRef]

Y. P. Han, G. Gréhan, and G. Gouesbet, “Generalized Lorenz–Mie theory for a spheroidal particle with off-axis Gaussian beam illumination,” Appl. Opt. 42, 6621–6629 (2003).

[CrossRef]

Y. P. Han, L. Mees, K. F. Ren, G. Gouesbet, S. Z. Wu, and G. Gréhan, “Scattering of light by spheroids: the far field case,” Opt. Commun. 210, 1–9 (2002).

[CrossRef]

G. Gouesbet, S. Meunier-Guttin-Cluzel, and G. Gréhan, “Morphologydependent resonances and/or whispering gallery modes for a two-dimensional dielectric cavity with an eccentrically located spherical inclusion, a Hamiltonian point of view with Hamiltonian (optical) chaos,” Opt. Commun. 201, 223–242 (2002).

[CrossRef]

L. Méès, G. Gouesbet, and G. Gréhan, “Numerical predictions of microcavity internal fields created by femtosecond pulses, with emphasis on whispering gallery modes,” J. Opt. A 4, 8150–8153 (2002).

L. Méès, J. P. Wolf, G. Gouesbet, and G. Gréhan, “Two-photon absorption and fluorescence in a spherical micro-cavity illuminated by using two laser pulses: numerical simulations,” Opt. Commun. 208, 371–375 (2002).

[CrossRef]

L. Méès, G. Gréhan, and G. Gouesbet, “Time-resolved scattering diagrams for a sphere illuminated by plane wave and focused short pulses,” Opt. Commun. 194, 59–65 (2001).

[CrossRef]

G. Gouesbet, S. Meunier-Guttin-Cluzel, and G. Gréhan, “Periodic orbits in Hamiltonian chaos of the annular billiard,” Phys. Rev. E 65, 016212 (2001).

[CrossRef]

L. Méès, G. Gouesbet, and G. Gréhan, “Scattering of laser pulses (plane wave and focused Gaussian beams) by spheres,” Appl. Opt. 40, 2546–2550 (2001).

[CrossRef]

G. Gouesbet, S. Meunier-Guttin-Cluzel, and G. Gréhan, “Generalized Lorenz–Mie theory for a sphere with an eccentrically located spherical inclusion, and optical chaos,” Part. Part. Syst. Charact. 18, 190–195 (2001).

[CrossRef]

L. Méès, G. Gouesbet, and G. Gréhan, “Interaction between femtosecond pulses and a spherical microcavity: internal fields,” Opt. Commun. 199, 33–38 (2001).

[CrossRef]

H. Polaert, G. Gouesbet, and G. Gréhan, “Laboratory determination of beam shape coefficients for use in generalized Lorenz–Mie theory,” Appl. Opt. 40, 1699–1706 (2001).

[CrossRef]

G. Gouesbet and G. Gréhan, “Generic formulation of a generalized Lorenz–Mie theory for a particle illuminated by laser pulses,” Part. Part. Syst. Charact. 17, 213–224 (2000).

[CrossRef]

G. Gouesbet and G. Gréhan, “Generalized Lorenz–Mie theories, from past to future,” Atomization Sprays 10, 277–333 (2000).

[CrossRef]

G. Gouesbet and G. Gréhan, “Generalized Lorenz–Mie theory for a sphere with an eccentrically located spherical inclusion,” J. Mod. Opt. 47, 821–837 (2000).

G. Gouesbet, L. Mees, G. Gréhan, and K. F. Ren, “Description of arbitrary shaped beams in elliptical cylinder coordinates by using a plane wave spectrum approach,” Opt. Commun. 161, 63–78 (1999).

[CrossRef]

L. Méès, K. F. Ren, G. Gréhan, and G. Gouesbet, “Scattering of a Gaussian beam by an infinite cylinder with arbitrary location and arbitrary orientation: numerical results,” Appl. Opt. 38, 1867–1876 (1999).

[CrossRef]

G. Gouesbet and G. Gréhan, “Generalized Lorenz–Mie theory for assemblies of spheres and aggregates,” J. Opt. A 1, 706–712 (1999).

[CrossRef]

H. Polaert, G. Gréhan, and G. Gouesbet, “Forces and torques exerted on a multilayered spherical particle by a focused Gaussian beam,” Opt. Commun. 155, 169–179 (1998).

[CrossRef]

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