Litcius/Paper detail

Gain-Assisted Optomechanical Position Locking of Metal/Dielectric Nanoshells in Optical Potentials

P. Polimeno, Francesco Patti, Melissa Infusino, Jonathan Sánchez, Maria Antonia Iatı̀, Rosalba Saija, Giovanni Volpe, Onofrio M. Maragò, Alessandro Veltri

2020ACS Photonics19 citationsDOIOpen Access PDF

Abstract

We investigate gain-assisted optical forces on dye-enriched silver nanoshell in the quasi-static limit by means of a theoretical/numerical approach. We demonstrate the onset of nonlinear optical trapping of these resonant nanostructures in a counter-propagating Gaussian beam configuration. We study the optical forces and trapping behavior as a function of wavelength, particle gain level, and laser power. We support the theoretical analysis with Brownian dynamics simulations that show how particle position locking is achieved at high gains in extended optical trapping potentials. Finally, for wavelengths blue-detuned with respect to the plasmon-enhanced resonance, we observe particle channeling by the standing wave antinodes due to gradient force reversal. This work opens perspectives for gain-assisted optomechanics where nonlinear optical forces are finely tuned to efficiently trap, manipulate, channel, and deliver an externally controlled nanophotonic system.

Topics & Concepts

Optical tweezersOptomechanicsOptical forceNanoshellNanophotonicsPhysicsWavelengthOpticsTrappingSurface plasmon resonanceOptical switchOptical powerPlasmonOptoelectronicsMaterials scienceLaserNanoparticleBiologyResonatorQuantum mechanicsEcologyOrbital Angular Momentum in OpticsMicrofluidic and Bio-sensing TechnologiesMechanical and Optical Resonators