☆ 4.6 Article

Optically levitated conveyor belt based on polarization-dependent metasurface lens arrays

OPTICS LETTERS (2022)

Related references

Note: Only part of the references are listed.

Article Optics

Nanoparticle trapping by counter-surface plasmon polariton lens

Jingjing Hong et al.

Summary: A stable and manipulatable nanoparticle trapping method called Counter-Surface Plasmon Polariton Lens (CSPPL) is proposed in this paper. By adjusting the incident angle and phase difference, the optical potential depth and center position on CSPPL can be accurately controlled. This study promotes the development of integrated optical tweezers.

CHINESE OPTICS LETTERS (2022)

Add to Collection

Article Optics

Optical conveyor belt based on a plasmonic metasurface with polarization dependent hot spot arrays

Chi Zhang et al.

Summary: This Letter proposes a novel metasurface conveyor belt using arrays of gold plasmonic elliptical elements for trapping, transporting, and sorting particles. By switching the polarization of the excitation beam, the elements can be continuously lit, providing a larger trapping area. The design offers a new scheme for particle sorting in optofluidic applications.

OPTICS LETTERS (2021)

Add to Collection

Article Optics

Nonlinear modulation on optical trapping in a plasmonic bowtie structure

Wenjun Zhang et al.

Summary: By controlling the geometric parameters of micro- and nano-structures and using pulsed lasers with high peak power, optical forces and potential wells in surface plasmon optical tweezers based on gold bowtie structures can be dynamically modulated, offering a new approach for stable trapping and dynamic control of particles.

OPTICS EXPRESS (2021)

Add to Collection

Article Optics

All-dielectric silicon metalens for two-dimensiona particle manipulation in optical tweezers

Teanchai Chantakit et al.

PHOTONICS RESEARCH (2020)

Add to Collection

Article Optics

Integrated optofluidic micro-pumps in micro-channels with uniform excitation of a polarization rotating beam

Min Jiang et al.

OPTICS LETTERS (2019)

Add to Collection

Review Nanoscience & Nanotechnology

Plasmonic optical tweezers based on nanostructures: fundamentals, advances and prospects

Domna G. Kotsifaki et al.

NANOPHOTONICS (2019)

Add to Collection

Article Chemistry, Multidisciplinary

Optical Manipulation along an Optical Axis with a Polarization Sensitive Meta-Lens

Hen Markovich et al.

NANO LETTERS (2018)

Add to Collection

Article Optics

TE-polarized design for metallic slit lenses: a way to deep-subwavelength focusing over a broad wavelength range

Yechuan Zhu et al.

OPTICS LETTERS (2018)

Add to Collection

Article Optics

On-chip optical trapping of extracellular vesicles using box-shaped composite SiO2-Si3N4 waveguides

Gyllion Brian Loozen et al.

OPTICS EXPRESS (2018)

Add to Collection

Article Chemistry, Multidisciplinary

Trapping and Detection of Nanoparticles and Cells Using a Parallel Photonic Nanojet Array

Yuchao Li et al.

ACS NANO (2016)

Add to Collection

Article Optics

Nano-optical conveyor belt with waveguide-coupled excitation

Guanghui Wang et al.

OPTICS LETTERS (2016)

Add to Collection

Article Nanoscience & Nanotechnology

Enantioselective Optical Trapping of Chiral Nanoparticles with Plasmonic Tweezers

Yang Zhao et al.

ACS PHOTONICS (2016)

Add to Collection

Article Chemistry, Multidisciplinary

Nano-Optical Conveyor Belt, Part I: Theory

Paul Hansen et al.

NANO LETTERS (2014)

Add to Collection

Article Multidisciplinary Sciences

Trapping and rotating nanoparticles using a plasmonic nano-tweezer with an integrated heat sink

Kai Wang et al.

NATURE COMMUNICATIONS (2011)

Add to Collection

Article Chemistry, Multidisciplinary

Planar Lenses Based on Nanoscale Slit Arrays in a Metallic Film

Lieven Verslegers et al.

NANO LETTERS (2009)

Add to Collection

Article Biochemical Research Methods

High-resolution, long-term characterization of bacterial motility using optical tweezers

Taejin L. Min et al.

NATURE METHODS (2009)

Add to Collection

© Peeref 2019-2024. All rights reserved.