Position locking of a resonant gain-assisted metallic/dielectric nano-shell in Optical Tweezers

P. Polimeno; F. Patti; M. Infusino; J. Sánchez; M. A. Iatì; R. Saija; G. Volpe; O. M. Maragò; A. Veltri

doi:10.1393/ncc/i2021-21113-7

Position locking of a resonant gain-assisted metallic/dielectric nano-shell in Optical Tweezers

P. Polimeno, F. Patti, M. Infusino, J. Sánchez, M. A. Iatì, R. Saija, G. Volpe, O. M. Maragò, A. Veltri

Física

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Abstract

We calculate optical forces on dye-enriched resonant nano-shells in dual-beam Optical Tweezers. We investigate the non-linear gain-assisted enhancement of their optomechanics and study their behaviour through Brownian dynamics simulations. When the wavelength is red detuned with respect to the plasmon resonance, we observe that the particles are efficiently trapped at the laser beam intensity maxima of the dual beam standing wave. Conversely, for blue-detuned wavelengths the nano-shells are channelled through the standing wave antinodes due to the sign reversal of the optical force. This open perspectives for gain-assisted optomechanics where non-linear optical forces are finely tuned to manipulate controlled nano-photonic systems.

Original language	English
Article number	113
Journal	Nuovo Cimento della Societa Italiana di Fisica C
Volume	44
Issue number	4-5
DOIs	https://doi.org/10.1393/ncc/i2021-21113-7
State	Published - Jul 2021

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title = "Position locking of a resonant gain-assisted metallic/dielectric nano-shell in Optical Tweezers",

abstract = "We calculate optical forces on dye-enriched resonant nano-shells in dual-beam Optical Tweezers. We investigate the non-linear gain-assisted enhancement of their optomechanics and study their behaviour through Brownian dynamics simulations. When the wavelength is red detuned with respect to the plasmon resonance, we observe that the particles are efficiently trapped at the laser beam intensity maxima of the dual beam standing wave. Conversely, for blue-detuned wavelengths the nano-shells are channelled through the standing wave antinodes due to the sign reversal of the optical force. This open perspectives for gain-assisted optomechanics where non-linear optical forces are finely tuned to manipulate controlled nano-photonic systems.",

author = "P. Polimeno and F. Patti and M. Infusino and J. S{\'a}nchez and Iat{\`i}, {M. A.} and R. Saija and G. Volpe and Marag{\`o}, {O. M.} and A. Veltri",

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T1 - Position locking of a resonant gain-assisted metallic/dielectric nano-shell in Optical Tweezers

AU - Polimeno, P.

AU - Patti, F.

AU - Infusino, M.

AU - Sánchez, J.

AU - Iatì, M. A.

AU - Saija, R.

AU - Volpe, G.

AU - Maragò, O. M.

AU - Veltri, A.

PY - 2021/7

Y1 - 2021/7

N2 - We calculate optical forces on dye-enriched resonant nano-shells in dual-beam Optical Tweezers. We investigate the non-linear gain-assisted enhancement of their optomechanics and study their behaviour through Brownian dynamics simulations. When the wavelength is red detuned with respect to the plasmon resonance, we observe that the particles are efficiently trapped at the laser beam intensity maxima of the dual beam standing wave. Conversely, for blue-detuned wavelengths the nano-shells are channelled through the standing wave antinodes due to the sign reversal of the optical force. This open perspectives for gain-assisted optomechanics where non-linear optical forces are finely tuned to manipulate controlled nano-photonic systems.

AB - We calculate optical forces on dye-enriched resonant nano-shells in dual-beam Optical Tweezers. We investigate the non-linear gain-assisted enhancement of their optomechanics and study their behaviour through Brownian dynamics simulations. When the wavelength is red detuned with respect to the plasmon resonance, we observe that the particles are efficiently trapped at the laser beam intensity maxima of the dual beam standing wave. Conversely, for blue-detuned wavelengths the nano-shells are channelled through the standing wave antinodes due to the sign reversal of the optical force. This open perspectives for gain-assisted optomechanics where non-linear optical forces are finely tuned to manipulate controlled nano-photonic systems.

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JO - Nuovo Cimento della Societa Italiana di Fisica C

JF - Nuovo Cimento della Societa Italiana di Fisica C

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ER -

Position locking of a resonant gain-assisted metallic/dielectric nano-shell in Optical Tweezers

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