Tunable optical traps over nonreciprocal surfaces

Paul, N. K.; Gómez‐Díaz, J. S.

doi:10.1364/oe.476269

Cited by 4 publications

(1 citation statement)

References 56 publications

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“…Substantial work has been devoted to manipulating targets with beams [1][2][3][4], and Nobel prizes have been conferred for related work to commend its progressiveness and breakthrough capabilities. Ashkin first utilized laser beams to trap particles [5,6].…”

Section: Introductionmentioning

confidence: 99%

A Review of Optical Tweezers with Metasurfaces

Shen

Huang

2023

Photonics

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Optical tweezers (OTs) have made significant progress in recent years, realizing the non-contact optical manipulation of target objects through the interaction between light and matter. In addition to trapping particles with the intensity gradient of the beam, a series of complex optical elements are required to properly modulate the beams to expand the operation of optical manipulation. The development of metasurfaces alleviates this problem. Due to the merits of miniaturization, planarization, multi-function, and integration of metasurfaces, these kinds of novel devices have been applied in OT systems. Metasurface devices have been used to replace traditional objective lenses, achieving device integration and even obtaining multi-function of OTs with unique optical properties in applications. OTs with metasurfaces have developed rapidly, and a great deal of work has been carried out on OTs with metasurfaces, as well as discussions on their practical applications. In this review, we regard the latest progress in the field of OTs with metasurfaces. We classify OTs with metasurface and summarize the new impetus brought by metasurfaces for the development of OTs.

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Section: Introductionmentioning

confidence: 99%

A Review of Optical Tweezers with Metasurfaces

Shen

Huang

2023

Photonics

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Switchable Optical Trapping of Mie‐Resonant Phase‐Change Nanoparticles

Mao,

Toftul,

Balendhran

et al. 2024

Laser & Photonics Reviews

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Optical tweezers revolutionized the manipulation of nanoscale objects. Typically, tunable manipulations of optical tweezers rely on adjusting either the trapping laser beams or the optical environment surrounding the nanoparticles. Here, tunable and switchable trapping using nanoparticles made of a phase‐change material (vanadium dioxide or VO2) are achieved. By varying the intensity of the trapping beam, transitions of the VO2 between monoclinic and rutile phases are induced. Depending on the nanoparticles' sizes, they exhibit one of three behaviors: small nanoparticles (in the settings, radius wavelength ) remain always attracted by the laser beam in both material phases, large nanoparticles () remain always repelled. However, within the size range of , the phase transition of the VO2 switches optical forces between attractive and repulsive, thereby pulling/pushing them toward/away from the beam center. The effect is reversible, allowing the same particle to be attracted and repelled repeatedly. The phenomenon is governed by optical Mie modes of the nanoparticles and their alterations during the phase transition of the VO2. This work provides an alternative solution for dynamic optical tweezers and paves a way to new possibilities, including optical sorting, light‐driven optomechanics and single‐molecule biophysics.

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