Litcius/Paper detail

Dynamic optical tweezers for metallic particle manipulation via tunable plasmonic fields

Ying Wang, Shibiao Wei, Zhendong Ju, Changjun Min, Michael G. Somekh, Xiaocong Yuan

2024Photonics Research10 citationsDOI

Abstract

Optical trapping has revolutionized various scientific disciplines with its non-invasive, high-resolution manipulation capabilities. However, conventional optical tweezers face limitations in effectively manipulating metallic particles due to their high reflectivity and associated scattering forces. Plasmonic tweezers, harnessing surface plasmons in metallic nanostructures, offer a promising solution by confining light to deep subwavelength scales and enhancing optical forces. However, dynamically manipulating metallic particles with plasmonic tweezers without mechanical adjustments remains a significant challenge. In this paper, we propose a novel approach utilizing dynamic optical tweezers with tunable plasmonic fields for metallic particle manipulation. By dynamically tailoring plasmonic fields with holograms, metallic particles can be manipulated without mechanical adjustments. Finite-difference time-domain simulations and Maxwell stress tensor calculations demonstrate the effectiveness of this technique, which offers simplicity, precision, and motionlessness in metallic particle manipulation. This advancement holds promise for applications in surface-enhanced Raman scattering, biosensing, super-resolved detection, and nanoparticle assembly, opening new avenues in plasmonic tweezers technology.

Topics & Concepts

Optical tweezersPlasmonTweezersMaterials scienceOptical forceNanotechnologyParticle (ecology)OpticsOptoelectronicsPhysicsGeologyOceanographyOrbital Angular Momentum in OpticsMicrofluidic and Bio-sensing TechnologiesNear-Field Optical Microscopy