D. Guzatov and V. V. Klimov, “Chiral particles in a circularly polarised light field: new effects and applications,” Quantum Electron. 41, 526–533 (2011).

[CrossRef]

Y. L. Geng, C. W. Qiu, and N. Yuan, “Exact solution to electromagnetic scattering by an impedance sphere coated with a uniaxial anisotropic layer,” IEEE Trans. Antennas Propag. 57, 572–576 (2009).

[CrossRef]

A. Gomez, A. Lakhtakia, J. Margineda, G. J. Molina-Cuberos, M. J. Nuez, J. A. Saiz Ipina, A. Vegas, and M. A. Solano, “Full-wave hybrid technique for 3-D isotropic-chiral-material discontinuities in rectangular waveguides: theory and experiment,” IEEE Trans. Microwave Theor. Tech. 56, 2815–2825 (2008).

[CrossRef]

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

[CrossRef]

M. Hasanovic, M. Chong, J. R. Mautz, and E. Arvas, “Scattering from 3-D inhomogeneous chiral bodies of arbitrary shape by the method of moments,” IEEE Trans. Antennas Propag. 55, 1817–1825 (2007).

[CrossRef]

C. Mei, M. Hasanovic, J. K. Lee, and E. Arvas, “Electromagnetic scattering from an arbitrarily shaped three dimensional inhomogeneous bianisotropic body,” PIERS Online 3, 680–684 (2007).

[CrossRef]

L. Kuzu, V. Demir, A. Z. Elsherbeni, and E. Arvas, “Electromagnetic scattering from arbitrarily shaped chiral objects using the finite difference frequency domain method,” Progress Electromagn. Res. 67, 1–24 (2007).

[CrossRef]

M. Yuceer, J. R. Mautz, and E. Arvas, “Method of moments solution for the radar cross section of a chiral body of revolution,” IEEE Trans. Antennas Propag. 53, 1163–1167 (2005).

[CrossRef]

V. Demir, A. Elsherbeni, D. Worasawate, and E. Arvas, “A graphical user interface (GUI) for plane-wave scattering from a conducting, dielectric, or chiral sphere,” IEEE Antennas Propag. Mag. 46(5), 94–99 (2004).

[CrossRef]

D. Worasawate, J. R. Mautz, and E. Arvas, “Electromagnetic scattering from an arbitrarily shaped three-dimensional homogeneous chiral body,” IEEE Trans. Antennas Propag. 51, 1077–1084 (2003).

[CrossRef]

D. L. Jaggard and J. C. Liu, “The matrix Riccati equation for scattering from stratified chiral spheres,” IEEE Trans. Antennas Propag. 47, 1201–1207 (1999).

[CrossRef]

L. Li, Y. Dan, M. Leong, and J. Kong, “Electromagnetic scattering by an inhomogeneous chiral sphere of varying permittivity: a discrete analysis using multilayered model,” Prog. Electromagn. Res. 13, 1203–1206 (1999).

[CrossRef]

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

[CrossRef]

J. Munoz, M. Rojo, A. Parrefio, and J. Margineda, “Automatic measurement of permittivity and permeability at microwave frequencies using normal and oblique free-wave incidence with focused beam,” IEEE Trans. Instrum. Meas. 47, 886–892 (1998).

[CrossRef]

M. Hinders and B. Rhodes, “Electromagnetic-wave scattering from chiral spheres in chiral media,” Nuovo Cimento D 14, 575–583 (1992).

[CrossRef]

Z. S. Wu, and Y. P. Wang, “Electromagnetic scattering for multilayered sphere: recursive algorithms,” Radio Sci. 26, 1393–1401 (1991).

[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. Grehan, 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]

R. Bhandari, “Scattering coefficients for a multilayered sphere: analytic expressions and algorithms,” Appl. Opt. 24, 1960–1967 (1985).

[CrossRef]

A. Lakhtakia, V. K. Varadan, and V. V. Varadan, “Scattering and absorption characteristics of lossy dielectric, chiral, nonspherical objects,” Appl. Opt. 24, 4146–4154 (1985).

[CrossRef]

F. Bohren, “Light scattering by an optically active sphere,” Chem. Phys. Lett. 29, 458–462 (1974).

[CrossRef]

D. J. Gordon, “Mie scattering by optically active particles,” Biochemistry 11, 413–420 (1972).

[CrossRef]

J. V. Dave, “Scattering of electromagnetic radiation by a large, absorbing sphere,” IBM J. Res. Devel. 13, 302–313 (1969).

[CrossRef]

A. L. Aden, “Electromagnetic scattering from spheres with sizes comparable to the wavelength,” J. Appl. Phys. 22, 601–605 (1951).

[CrossRef]

A. L. Aden, and M. Kerker, “Scattering of electromagnetic wave from concentric sphere,” J. Appl. Phys. 22, 1242–1246 (1951).

[CrossRef]

L. Infeld, “The influence of the width of the gap upon the theory of antennas,” Q. Appl. Math. 5, 113–132 (1947).

A. L. Aden, and M. Kerker, “Scattering of electromagnetic wave from concentric sphere,” J. Appl. Phys. 22, 1242–1246 (1951).

[CrossRef]

A. L. Aden, “Electromagnetic scattering from spheres with sizes comparable to the wavelength,” J. Appl. Phys. 22, 601–605 (1951).

[CrossRef]

L. Kuzu, V. Demir, A. Z. Elsherbeni, and E. Arvas, “Electromagnetic scattering from arbitrarily shaped chiral objects using the finite difference frequency domain method,” Progress Electromagn. Res. 67, 1–24 (2007).

[CrossRef]

C. Mei, M. Hasanovic, J. K. Lee, and E. Arvas, “Electromagnetic scattering from an arbitrarily shaped three dimensional inhomogeneous bianisotropic body,” PIERS Online 3, 680–684 (2007).

[CrossRef]

M. Hasanovic, M. Chong, J. R. Mautz, and E. Arvas, “Scattering from 3-D inhomogeneous chiral bodies of arbitrary shape by the method of moments,” IEEE Trans. Antennas Propag. 55, 1817–1825 (2007).

[CrossRef]

M. Yuceer, J. R. Mautz, and E. Arvas, “Method of moments solution for the radar cross section of a chiral body of revolution,” IEEE Trans. Antennas Propag. 53, 1163–1167 (2005).

[CrossRef]

V. Demir, A. Elsherbeni, D. Worasawate, and E. Arvas, “A graphical user interface (GUI) for plane-wave scattering from a conducting, dielectric, or chiral sphere,” IEEE Antennas Propag. Mag. 46(5), 94–99 (2004).

[CrossRef]

D. Worasawate, J. R. Mautz, and E. Arvas, “Electromagnetic scattering from an arbitrarily shaped three-dimensional homogeneous chiral body,” IEEE Trans. Antennas Propag. 51, 1077–1084 (2003).

[CrossRef]

V. Demir, A. Z. Elsherbeni, and E. Arvas, “FDTD formulations for scattering from three dimensional chiral objects,” in The 20th Annual Review of Progress in Applied Computational Electromagnetics Society (ACES, 2004), record 577.

C. F. Bohren and D. R. Huffman, Absorption and Scattering of Light by Small Particles (Wiley, 1998).

F. Bohren, “Light scattering by an optically active sphere,” Chem. Phys. Lett. 29, 458–462 (1974).

[CrossRef]

M. Hasanovic, M. Chong, J. R. Mautz, and E. Arvas, “Scattering from 3-D inhomogeneous chiral bodies of arbitrary shape by the method of moments,” IEEE Trans. Antennas Propag. 55, 1817–1825 (2007).

[CrossRef]

L. Li, Y. Dan, M. Leong, and J. Kong, “Electromagnetic scattering by an inhomogeneous chiral sphere of varying permittivity: a discrete analysis using multilayered model,” Prog. Electromagn. Res. 13, 1203–1206 (1999).

[CrossRef]

J. V. Dave, “Scattering of electromagnetic radiation by a large, absorbing sphere,” IBM J. Res. Devel. 13, 302–313 (1969).

[CrossRef]

L. Kuzu, V. Demir, A. Z. Elsherbeni, and E. Arvas, “Electromagnetic scattering from arbitrarily shaped chiral objects using the finite difference frequency domain method,” Progress Electromagn. Res. 67, 1–24 (2007).

[CrossRef]

V. Demir, A. Elsherbeni, D. Worasawate, and E. Arvas, “A graphical user interface (GUI) for plane-wave scattering from a conducting, dielectric, or chiral sphere,” IEEE Antennas Propag. Mag. 46(5), 94–99 (2004).

[CrossRef]

V. Demir, A. Z. Elsherbeni, and E. Arvas, “FDTD formulations for scattering from three dimensional chiral objects,” in The 20th Annual Review of Progress in Applied Computational Electromagnetics Society (ACES, 2004), record 577.

V. Demir, A. Elsherbeni, D. Worasawate, and E. Arvas, “A graphical user interface (GUI) for plane-wave scattering from a conducting, dielectric, or chiral sphere,” IEEE Antennas Propag. Mag. 46(5), 94–99 (2004).

[CrossRef]

L. Kuzu, V. Demir, A. Z. Elsherbeni, and E. Arvas, “Electromagnetic scattering from arbitrarily shaped chiral objects using the finite difference frequency domain method,” Progress Electromagn. Res. 67, 1–24 (2007).

[CrossRef]

V. Demir, A. Z. Elsherbeni, and E. Arvas, “FDTD formulations for scattering from three dimensional chiral objects,” in The 20th Annual Review of Progress in Applied Computational Electromagnetics Society (ACES, 2004), record 577.

Y. L. Geng, C. W. Qiu, and N. Yuan, “Exact solution to electromagnetic scattering by an impedance sphere coated with a uniaxial anisotropic layer,” IEEE Trans. Antennas Propag. 57, 572–576 (2009).

[CrossRef]

A. Gomez, A. Lakhtakia, J. Margineda, G. J. Molina-Cuberos, M. J. Nuez, J. A. Saiz Ipina, A. Vegas, and M. A. Solano, “Full-wave hybrid technique for 3-D isotropic-chiral-material discontinuities in rectangular waveguides: theory and experiment,” IEEE Trans. Microwave Theor. Tech. 56, 2815–2825 (2008).

[CrossRef]

D. J. Gordon, “Mie scattering by optically active particles,” Biochemistry 11, 413–420 (1972).

[CrossRef]

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

[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. Grehan, 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]

D. Guzatov and V. V. Klimov, “Chiral particles in a circularly polarised light field: new effects and applications,” Quantum Electron. 41, 526–533 (2011).

[CrossRef]

D. Sarkar, and N. J. Halas, “General vector basis function solution of Maxwell’s equations,” Phys. Rev. E 56, 1102 (1997).

[CrossRef]

M. Hasanovic, M. Chong, J. R. Mautz, and E. Arvas, “Scattering from 3-D inhomogeneous chiral bodies of arbitrary shape by the method of moments,” IEEE Trans. Antennas Propag. 55, 1817–1825 (2007).

[CrossRef]

C. Mei, M. Hasanovic, J. K. Lee, and E. Arvas, “Electromagnetic scattering from an arbitrarily shaped three dimensional inhomogeneous bianisotropic body,” PIERS Online 3, 680–684 (2007).

[CrossRef]

M. Hinders and B. Rhodes, “Electromagnetic-wave scattering from chiral spheres in chiral media,” Nuovo Cimento D 14, 575–583 (1992).

[CrossRef]

C. F. Bohren and D. R. Huffman, Absorption and Scattering of Light by Small Particles (Wiley, 1998).

V. D. Hulst, Light Scattering by Small Particles (Wiley, 1957).

L. Infeld, “The influence of the width of the gap upon the theory of antennas,” Q. Appl. Math. 5, 113–132 (1947).

D. L. Jaggard and J. C. Liu, “The matrix Riccati equation for scattering from stratified chiral spheres,” IEEE Trans. Antennas Propag. 47, 1201–1207 (1999).

[CrossRef]

A. L. Aden, and M. Kerker, “Scattering of electromagnetic wave from concentric sphere,” J. Appl. Phys. 22, 1242–1246 (1951).

[CrossRef]

D. Guzatov and V. V. Klimov, “Chiral particles in a circularly polarised light field: new effects and applications,” Quantum Electron. 41, 526–533 (2011).

[CrossRef]

L. Li, Y. Dan, M. Leong, and J. Kong, “Electromagnetic scattering by an inhomogeneous chiral sphere of varying permittivity: a discrete analysis using multilayered model,” Prog. Electromagn. Res. 13, 1203–1206 (1999).

[CrossRef]

L. Kuzu, V. Demir, A. Z. Elsherbeni, and E. Arvas, “Electromagnetic scattering from arbitrarily shaped chiral objects using the finite difference frequency domain method,” Progress Electromagn. Res. 67, 1–24 (2007).

[CrossRef]

A. Gomez, A. Lakhtakia, J. Margineda, G. J. Molina-Cuberos, M. J. Nuez, J. A. Saiz Ipina, A. Vegas, and M. A. Solano, “Full-wave hybrid technique for 3-D isotropic-chiral-material discontinuities in rectangular waveguides: theory and experiment,” IEEE Trans. Microwave Theor. Tech. 56, 2815–2825 (2008).

[CrossRef]

A. Lakhtakia, V. K. Varadan, and V. V. Varadan, “Scattering and absorption characteristics of lossy dielectric, chiral, nonspherical objects,” Appl. Opt. 24, 4146–4154 (1985).

[CrossRef]

A. Lakhtakia, V. K. Varadan, and V. V. Varadan, Time-Harmonic Electromagnetic Fields in Chiral Media (Springer, 1989).

A. Lakhtakia, Beltrami Fields in Chiral Media (World Scientific, 1994), Vol. 2.

C. Mei, M. Hasanovic, J. K. Lee, and E. Arvas, “Electromagnetic scattering from an arbitrarily shaped three dimensional inhomogeneous bianisotropic body,” PIERS Online 3, 680–684 (2007).

[CrossRef]

L. Li, Y. Dan, M. Leong, and J. Kong, “Electromagnetic scattering by an inhomogeneous chiral sphere of varying permittivity: a discrete analysis using multilayered model,” Prog. Electromagn. Res. 13, 1203–1206 (1999).

[CrossRef]

L. Li, Y. Dan, M. Leong, and J. Kong, “Electromagnetic scattering by an inhomogeneous chiral sphere of varying permittivity: a discrete analysis using multilayered model,” Prog. Electromagn. Res. 13, 1203–1206 (1999).

[CrossRef]

D. L. Jaggard and J. C. Liu, “The matrix Riccati equation for scattering from stratified chiral spheres,” IEEE Trans. Antennas Propag. 47, 1201–1207 (1999).

[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. Grehan, 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]

A. Gomez, A. Lakhtakia, J. Margineda, G. J. Molina-Cuberos, M. J. Nuez, J. A. Saiz Ipina, A. Vegas, and M. A. Solano, “Full-wave hybrid technique for 3-D isotropic-chiral-material discontinuities in rectangular waveguides: theory and experiment,” IEEE Trans. Microwave Theor. Tech. 56, 2815–2825 (2008).

[CrossRef]

J. Munoz, M. Rojo, A. Parrefio, and J. Margineda, “Automatic measurement of permittivity and permeability at microwave frequencies using normal and oblique free-wave incidence with focused beam,” IEEE Trans. Instrum. Meas. 47, 886–892 (1998).

[CrossRef]

M. Hasanovic, M. Chong, J. R. Mautz, and E. Arvas, “Scattering from 3-D inhomogeneous chiral bodies of arbitrary shape by the method of moments,” IEEE Trans. Antennas Propag. 55, 1817–1825 (2007).

[CrossRef]

M. Yuceer, J. R. Mautz, and E. Arvas, “Method of moments solution for the radar cross section of a chiral body of revolution,” IEEE Trans. Antennas Propag. 53, 1163–1167 (2005).

[CrossRef]

D. Worasawate, J. R. Mautz, and E. Arvas, “Electromagnetic scattering from an arbitrarily shaped three-dimensional homogeneous chiral body,” IEEE Trans. Antennas Propag. 51, 1077–1084 (2003).

[CrossRef]

C. Mei, M. Hasanovic, J. K. Lee, and E. Arvas, “Electromagnetic scattering from an arbitrarily shaped three dimensional inhomogeneous bianisotropic body,” PIERS Online 3, 680–684 (2007).

[CrossRef]

A. Gomez, A. Lakhtakia, J. Margineda, G. J. Molina-Cuberos, M. J. Nuez, J. A. Saiz Ipina, A. Vegas, and M. A. Solano, “Full-wave hybrid technique for 3-D isotropic-chiral-material discontinuities in rectangular waveguides: theory and experiment,” IEEE Trans. Microwave Theor. Tech. 56, 2815–2825 (2008).

[CrossRef]

J. Munoz, M. Rojo, A. Parrefio, and J. Margineda, “Automatic measurement of permittivity and permeability at microwave frequencies using normal and oblique free-wave incidence with focused beam,” IEEE Trans. Instrum. Meas. 47, 886–892 (1998).

[CrossRef]

A. Gomez, A. Lakhtakia, J. Margineda, G. J. Molina-Cuberos, M. J. Nuez, J. A. Saiz Ipina, A. Vegas, and M. A. Solano, “Full-wave hybrid technique for 3-D isotropic-chiral-material discontinuities in rectangular waveguides: theory and experiment,” IEEE Trans. Microwave Theor. Tech. 56, 2815–2825 (2008).

[CrossRef]

J. Munoz, M. Rojo, A. Parrefio, and J. Margineda, “Automatic measurement of permittivity and permeability at microwave frequencies using normal and oblique free-wave incidence with focused beam,” IEEE Trans. Instrum. Meas. 47, 886–892 (1998).

[CrossRef]

Y. L. Geng, C. W. Qiu, and N. Yuan, “Exact solution to electromagnetic scattering by an impedance sphere coated with a uniaxial anisotropic layer,” IEEE Trans. Antennas Propag. 57, 572–576 (2009).

[CrossRef]

M. Hinders and B. Rhodes, “Electromagnetic-wave scattering from chiral spheres in chiral media,” Nuovo Cimento D 14, 575–583 (1992).

[CrossRef]

J. Munoz, M. Rojo, A. Parrefio, and J. Margineda, “Automatic measurement of permittivity and permeability at microwave frequencies using normal and oblique free-wave incidence with focused beam,” IEEE Trans. Instrum. Meas. 47, 886–892 (1998).

[CrossRef]

A. Gomez, A. Lakhtakia, J. Margineda, G. J. Molina-Cuberos, M. J. Nuez, J. A. Saiz Ipina, A. Vegas, and M. A. Solano, “Full-wave hybrid technique for 3-D isotropic-chiral-material discontinuities in rectangular waveguides: theory and experiment,” IEEE Trans. Microwave Theor. Tech. 56, 2815–2825 (2008).

[CrossRef]

D. Sarkar, and N. J. Halas, “General vector basis function solution of Maxwell’s equations,” Phys. Rev. E 56, 1102 (1997).

[CrossRef]

A. Gomez, A. Lakhtakia, J. Margineda, G. J. Molina-Cuberos, M. J. Nuez, J. A. Saiz Ipina, A. Vegas, and M. A. Solano, “Full-wave hybrid technique for 3-D isotropic-chiral-material discontinuities in rectangular waveguides: theory and experiment,” IEEE Trans. Microwave Theor. Tech. 56, 2815–2825 (2008).

[CrossRef]

A. Lakhtakia, V. K. Varadan, and V. V. Varadan, “Scattering and absorption characteristics of lossy dielectric, chiral, nonspherical objects,” Appl. Opt. 24, 4146–4154 (1985).

[CrossRef]

A. Lakhtakia, V. K. Varadan, and V. V. Varadan, Time-Harmonic Electromagnetic Fields in Chiral Media (Springer, 1989).

A. Lakhtakia, V. K. Varadan, and V. V. Varadan, “Scattering and absorption characteristics of lossy dielectric, chiral, nonspherical objects,” Appl. Opt. 24, 4146–4154 (1985).

[CrossRef]

A. Lakhtakia, V. K. Varadan, and V. V. Varadan, Time-Harmonic Electromagnetic Fields in Chiral Media (Springer, 1989).

A. Gomez, A. Lakhtakia, J. Margineda, G. J. Molina-Cuberos, M. J. Nuez, J. A. Saiz Ipina, A. Vegas, and M. A. Solano, “Full-wave hybrid technique for 3-D isotropic-chiral-material discontinuities in rectangular waveguides: theory and experiment,” IEEE Trans. Microwave Theor. Tech. 56, 2815–2825 (2008).

[CrossRef]

Z. S. Wu, and Y. P. Wang, “Electromagnetic scattering for multilayered sphere: recursive algorithms,” Radio Sci. 26, 1393–1401 (1991).

[CrossRef]

V. Demir, A. Elsherbeni, D. Worasawate, and E. Arvas, “A graphical user interface (GUI) for plane-wave scattering from a conducting, dielectric, or chiral sphere,” IEEE Antennas Propag. Mag. 46(5), 94–99 (2004).

[CrossRef]

D. Worasawate, J. R. Mautz, and E. Arvas, “Electromagnetic scattering from an arbitrarily shaped three-dimensional homogeneous chiral body,” IEEE Trans. Antennas Propag. 51, 1077–1084 (2003).

[CrossRef]

Z. S. Wu, and Y. P. Wang, “Electromagnetic scattering for multilayered sphere: recursive algorithms,” Radio Sci. 26, 1393–1401 (1991).

[CrossRef]

Y. L. Geng, C. W. Qiu, and N. Yuan, “Exact solution to electromagnetic scattering by an impedance sphere coated with a uniaxial anisotropic layer,” IEEE Trans. Antennas Propag. 57, 572–576 (2009).

[CrossRef]

M. Yuceer, J. R. Mautz, and E. Arvas, “Method of moments solution for the radar cross section of a chiral body of revolution,” IEEE Trans. Antennas Propag. 53, 1163–1167 (2005).

[CrossRef]

A. Lakhtakia, V. K. Varadan, and V. V. Varadan, “Scattering and absorption characteristics of lossy dielectric, chiral, nonspherical objects,” Appl. Opt. 24, 4146–4154 (1985).

[CrossRef]

W. J. Lentz, “Generating Bessel functions in Mie scattering calculations using continued fractions,” Appl. Opt. 15, 668–671 (1976).

[CrossRef]

W. J. Wiscombe, “Improved Mie scattering algorithms,” Appl. Opt. 19, 1505–1509 (1980).

[CrossRef]

G. W. Kattawar, and G. N. Plass, “Electromagnetic scattering from absorbing spheres,” Appl. Opt. 6, 1377–1382 (1967).

[CrossRef]

O. B. Toon, and T. P. Ackerman, “Algorithms for the calculation of scattering by stratified spheres,” Appl. Opt. 20, 3657–3660 (1981).

[CrossRef]

R. Bhandari, “Scattering coefficients for a multilayered sphere: analytic expressions and algorithms,” Appl. Opt. 24, 1960–1967 (1985).

[CrossRef]

G. Gouesbet, G. Grehan, 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]

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]

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

[CrossRef]

D. J. Gordon, “Mie scattering by optically active particles,” Biochemistry 11, 413–420 (1972).

[CrossRef]

F. Bohren, “Light scattering by an optically active sphere,” Chem. Phys. Lett. 29, 458–462 (1974).

[CrossRef]

J. V. Dave, “Scattering of electromagnetic radiation by a large, absorbing sphere,” IBM J. Res. Devel. 13, 302–313 (1969).

[CrossRef]

V. Demir, A. Elsherbeni, D. Worasawate, and E. Arvas, “A graphical user interface (GUI) for plane-wave scattering from a conducting, dielectric, or chiral sphere,” IEEE Antennas Propag. Mag. 46(5), 94–99 (2004).

[CrossRef]

D. L. Jaggard and J. C. Liu, “The matrix Riccati equation for scattering from stratified chiral spheres,” IEEE Trans. Antennas Propag. 47, 1201–1207 (1999).

[CrossRef]

D. Worasawate, J. R. Mautz, and E. Arvas, “Electromagnetic scattering from an arbitrarily shaped three-dimensional homogeneous chiral body,” IEEE Trans. Antennas Propag. 51, 1077–1084 (2003).

[CrossRef]

M. Yuceer, J. R. Mautz, and E. Arvas, “Method of moments solution for the radar cross section of a chiral body of revolution,” IEEE Trans. Antennas Propag. 53, 1163–1167 (2005).

[CrossRef]

M. Hasanovic, M. Chong, J. R. Mautz, and E. Arvas, “Scattering from 3-D inhomogeneous chiral bodies of arbitrary shape by the method of moments,” IEEE Trans. Antennas Propag. 55, 1817–1825 (2007).

[CrossRef]

Y. L. Geng, C. W. Qiu, and N. Yuan, “Exact solution to electromagnetic scattering by an impedance sphere coated with a uniaxial anisotropic layer,” IEEE Trans. Antennas Propag. 57, 572–576 (2009).

[CrossRef]

J. Munoz, M. Rojo, A. Parrefio, and J. Margineda, “Automatic measurement of permittivity and permeability at microwave frequencies using normal and oblique free-wave incidence with focused beam,” IEEE Trans. Instrum. Meas. 47, 886–892 (1998).

[CrossRef]

A. Gomez, A. Lakhtakia, J. Margineda, G. J. Molina-Cuberos, M. J. Nuez, J. A. Saiz Ipina, A. Vegas, and M. A. Solano, “Full-wave hybrid technique for 3-D isotropic-chiral-material discontinuities in rectangular waveguides: theory and experiment,” IEEE Trans. Microwave Theor. Tech. 56, 2815–2825 (2008).

[CrossRef]

A. L. Aden, “Electromagnetic scattering from spheres with sizes comparable to the wavelength,” J. Appl. Phys. 22, 601–605 (1951).

[CrossRef]

A. L. Aden, and M. Kerker, “Scattering of electromagnetic wave from concentric sphere,” J. Appl. Phys. 22, 1242–1246 (1951).

[CrossRef]

M. F. R. Cooray and I. R. Ciric, “Wave scattering by a chiral spheroid,” J. Opt. Soc. Am. A 10, 1197–1203 (1993).

[CrossRef]

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

[CrossRef]

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

[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]

M. Hinders and B. Rhodes, “Electromagnetic-wave scattering from chiral spheres in chiral media,” Nuovo Cimento D 14, 575–583 (1992).

[CrossRef]

D. Sarkar, and N. J. Halas, “General vector basis function solution of Maxwell’s equations,” Phys. Rev. E 56, 1102 (1997).

[CrossRef]

C. Mei, M. Hasanovic, J. K. Lee, and E. Arvas, “Electromagnetic scattering from an arbitrarily shaped three dimensional inhomogeneous bianisotropic body,” PIERS Online 3, 680–684 (2007).

[CrossRef]

L. Li, Y. Dan, M. Leong, and J. Kong, “Electromagnetic scattering by an inhomogeneous chiral sphere of varying permittivity: a discrete analysis using multilayered model,” Prog. Electromagn. Res. 13, 1203–1206 (1999).

[CrossRef]

L. Kuzu, V. Demir, A. Z. Elsherbeni, and E. Arvas, “Electromagnetic scattering from arbitrarily shaped chiral objects using the finite difference frequency domain method,” Progress Electromagn. Res. 67, 1–24 (2007).

[CrossRef]

L. Infeld, “The influence of the width of the gap upon the theory of antennas,” Q. Appl. Math. 5, 113–132 (1947).

D. Guzatov and V. V. Klimov, “Chiral particles in a circularly polarised light field: new effects and applications,” Quantum Electron. 41, 526–533 (2011).

[CrossRef]

Z. S. Wu, and Y. P. Wang, “Electromagnetic scattering for multilayered sphere: recursive algorithms,” Radio Sci. 26, 1393–1401 (1991).

[CrossRef]

V. D. Hulst, Light Scattering by Small Particles (Wiley, 1957).

A. Lakhtakia, V. K. Varadan, and V. V. Varadan, Time-Harmonic Electromagnetic Fields in Chiral Media (Springer, 1989).

C. F. Bohren and D. R. Huffman, Absorption and Scattering of Light by Small Particles (Wiley, 1998).

A. Lakhtakia, Beltrami Fields in Chiral Media (World Scientific, 1994), Vol. 2.

V. Demir, A. Z. Elsherbeni, and E. Arvas, “FDTD formulations for scattering from three dimensional chiral objects,” in The 20th Annual Review of Progress in Applied Computational Electromagnetics Society (ACES, 2004), record 577.