Fano resonance-assisted all-dielectric array for enhanced near-field optical trapping of nanoparticles

Donato Conteduca; Saba N. Khan; Manuel A. Martínez Ruiz; Graham D. Bruce; Thomas F. Krauss; Kishan Dholakia

Fano resonance-assisted all-dielectric array for enhanced near-field optical trapping of nanoparticles

Donato Conteduca, Saba N. Khan, Manuel A. Martínez Ruiz, Graham D. Bruce, Thomas F. Krauss, Kishan Dholakia

Research output: Working paper › Preprint

Abstract

Near-field optics can overcome the diffraction limit by creating strong optical gradients to enable the trapping of nanoparticles. However, it remains challenging to achieve efficient stable trapping without heating and thermal effects. Dielectric structures have been used to address this issue, but they usually offer weak trap stiffness. In this work, we exploit the Fano resonance effect in an all-dielectric quadrupole nanostructure to realize a twenty-fold enhancement of trap stiffness, compared to the off-resonance case. This enables a high effective trap stiffness of 1.19 fN/nm for 100 nm diameter polystyrene nanoparticles with 3.5 mW/μm² illumination. Furthermore, we demonstrate the capability of the structure to simultaneously trap two particles at distinct locations within the nanostructure array.

Original language	English
Publisher	arXiv
Publication status	Published - 7 Aug 2023

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http://arxiv.org/abs/2308.03639Licence: Other

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Resonant and shaped photonics for under: Resonant and shaped photonics for understanding the physical and biomedical world
Dholakia, K. (PI) & Gather, M. C. (CoI)
1/08/17 → 31/07/22
Project: Standard

1 Article

Fano resonance-assisted all-dielectric array for enhanced near-field optical trapping of nanoparticles
Conteduca, D., Khan, S. N., Ruiz, M. A. M., Bruce, G. D., Krauss, T. F. & Dholakia, K., 14 Nov 2023, (E-pub ahead of print) In: ACS Photonics. Articles ASAP, 7 p.
Research output: Contribution to journal › Article › peer-review

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title = "Fano resonance-assisted all-dielectric array for enhanced near-field optical trapping of nanoparticles",

abstract = "Near-field optics can overcome the diffraction limit by creating strong optical gradients to enable the trapping of nanoparticles. However, it remains challenging to achieve efficient stable trapping without heating and thermal effects. Dielectric structures have been used to address this issue, but they usually offer weak trap stiffness. In this work, we exploit the Fano resonance effect in an all-dielectric quadrupole nanostructure to realize a twenty-fold enhancement of trap stiffness, compared to the off-resonance case. This enables a high effective trap stiffness of 1.19 fN/nm for 100 nm diameter polystyrene nanoparticles with 3.5 mW/μm2 illumination. Furthermore, we demonstrate the capability of the structure to simultaneously trap two particles at distinct locations within the nanostructure array.",

author = "Donato Conteduca and Khan, {Saba N.} and Ruiz, {Manuel A. Mart{\'i}nez} and Bruce, {Graham D.} and Krauss, {Thomas F.} and Kishan Dholakia",

note = "Funding: This work was supported by the UK Engineering and Physical Sciences Research Council (EP/P030017/1), and the Australian Research Council (grant DP220102303). ",

year = "2023",

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language = "English",

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T1 - Fano resonance-assisted all-dielectric array for enhanced near-field optical trapping of nanoparticles

AU - Conteduca, Donato

AU - Khan, Saba N.

AU - Ruiz, Manuel A. Martínez

AU - Bruce, Graham D.

AU - Krauss, Thomas F.

AU - Dholakia, Kishan

N1 - Funding: This work was supported by the UK Engineering and Physical Sciences Research Council (EP/P030017/1), and the Australian Research Council (grant DP220102303).

PY - 2023/8/7

Y1 - 2023/8/7

N2 - Near-field optics can overcome the diffraction limit by creating strong optical gradients to enable the trapping of nanoparticles. However, it remains challenging to achieve efficient stable trapping without heating and thermal effects. Dielectric structures have been used to address this issue, but they usually offer weak trap stiffness. In this work, we exploit the Fano resonance effect in an all-dielectric quadrupole nanostructure to realize a twenty-fold enhancement of trap stiffness, compared to the off-resonance case. This enables a high effective trap stiffness of 1.19 fN/nm for 100 nm diameter polystyrene nanoparticles with 3.5 mW/μm2 illumination. Furthermore, we demonstrate the capability of the structure to simultaneously trap two particles at distinct locations within the nanostructure array.

AB - Near-field optics can overcome the diffraction limit by creating strong optical gradients to enable the trapping of nanoparticles. However, it remains challenging to achieve efficient stable trapping without heating and thermal effects. Dielectric structures have been used to address this issue, but they usually offer weak trap stiffness. In this work, we exploit the Fano resonance effect in an all-dielectric quadrupole nanostructure to realize a twenty-fold enhancement of trap stiffness, compared to the off-resonance case. This enables a high effective trap stiffness of 1.19 fN/nm for 100 nm diameter polystyrene nanoparticles with 3.5 mW/μm2 illumination. Furthermore, we demonstrate the capability of the structure to simultaneously trap two particles at distinct locations within the nanostructure array.

M3 - Preprint

BT - Fano resonance-assisted all-dielectric array for enhanced near-field optical trapping of nanoparticles

PB - arXiv

ER -

Fano resonance-assisted all-dielectric array for enhanced near-field optical trapping of nanoparticles

Abstract

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Resonant and shaped photonics for under: Resonant and shaped photonics for understanding the physical and biomedical world

Research output

Fano resonance-assisted all-dielectric array for enhanced near-field optical trapping of nanoparticles

Cite this