Electromagnetic forces for an arbitrary optical trapping of a spherical dielectric

Antonio A.R. Neves; Adriana Fontes; Liliana Y. De Pozzo; Andre A. De Thomaz; Enver Chillce; Eugenio Rodriguez; Luiz C. Barbosa; Carlos L. Cesar

doi:10.1364/OE.14.013101

Electromagnetic forces for an arbitrary optical trapping of a spherical dielectric

Antonio A.R. Neves, Adriana Fontes, Liliana Y. De Pozzo, Andre A. De Thomaz, Enver Chillce, Eugenio Rodriguez, Luiz C. Barbosa, Carlos L. Cesar

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

61 Citas (Scopus)

Resumen

A double tweezers setup was employed to perform ultra sensitive force measurements and to obtain the full optical force curve as a function of radial position and wavelength. The light polarization was used to select either the transverse electric (TE), or transverse magnetic (TM), or both, modes excitation. Analytical solution for optical trapping force on a spherical dielectric particle for an arbitrary positioned focused beam is presented in a generalized Lorenz-Mie diffraction theory. The theoretical prediction of the theory agrees well with the experimental results. The algorithm presented here can be easily extended to other beam geometries and scattering particles.

Idioma original	Inglés
Páginas (desde-hasta)	13101-13106
Número de páginas	6
Publicación	Optics Express
Volumen	14
N.º	26
DOI	https://doi.org/10.1364/OE.14.013101
Estado	Publicada - 25 dic. 2006
Publicado de forma externa	Sí

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abstract = "A double tweezers setup was employed to perform ultra sensitive force measurements and to obtain the full optical force curve as a function of radial position and wavelength. The light polarization was used to select either the transverse electric (TE), or transverse magnetic (TM), or both, modes excitation. Analytical solution for optical trapping force on a spherical dielectric particle for an arbitrary positioned focused beam is presented in a generalized Lorenz-Mie diffraction theory. The theoretical prediction of the theory agrees well with the experimental results. The algorithm presented here can be easily extended to other beam geometries and scattering particles.",

author = "Neves, {Antonio A.R.} and Adriana Fontes and {De Pozzo}, {Liliana Y.} and {De Thomaz}, {Andre A.} and Enver Chillce and Eugenio Rodriguez and Barbosa, {Luiz C.} and Cesar, {Carlos L.}",

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AU - Neves, Antonio A.R.

AU - Fontes, Adriana

AU - De Pozzo, Liliana Y.

AU - De Thomaz, Andre A.

AU - Chillce, Enver

AU - Rodriguez, Eugenio

AU - Barbosa, Luiz C.

AU - Cesar, Carlos L.

PY - 2006/12/25

Y1 - 2006/12/25

N2 - A double tweezers setup was employed to perform ultra sensitive force measurements and to obtain the full optical force curve as a function of radial position and wavelength. The light polarization was used to select either the transverse electric (TE), or transverse magnetic (TM), or both, modes excitation. Analytical solution for optical trapping force on a spherical dielectric particle for an arbitrary positioned focused beam is presented in a generalized Lorenz-Mie diffraction theory. The theoretical prediction of the theory agrees well with the experimental results. The algorithm presented here can be easily extended to other beam geometries and scattering particles.

AB - A double tweezers setup was employed to perform ultra sensitive force measurements and to obtain the full optical force curve as a function of radial position and wavelength. The light polarization was used to select either the transverse electric (TE), or transverse magnetic (TM), or both, modes excitation. Analytical solution for optical trapping force on a spherical dielectric particle for an arbitrary positioned focused beam is presented in a generalized Lorenz-Mie diffraction theory. The theoretical prediction of the theory agrees well with the experimental results. The algorithm presented here can be easily extended to other beam geometries and scattering particles.

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DO - 10.1364/OE.14.013101

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SP - 13101

EP - 13106

JO - Optics Express

JF - Optics Express

IS - 26

ER -

Electromagnetic forces for an arbitrary optical trapping of a spherical dielectric

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