What question did this study set out to answer?

This research aims to explore the potential of lensed single-mode fibers for the optical trapping of silicon nanoparticles.

March 1, 2026

Modeling Particle Trapping Using Focused Radiation of an Optical Fiber Mode

Key Points

This research aims to explore the potential of lensed single-mode fibers for the optical trapping of silicon nanoparticles.
Conducted numerical simulations for optical trapping using lensed single-mode fibers
Analyzed the stability of trapping for particles up to 100 nm in radius
Proposed a design for optical tweezers using two opposing lensed fibers
Evaluated the sensitivity of trapping forces to fiber misalignment
Showed stable trapping for silicon nanoparticles with a radius up to 100 nm
Found that larger particles experience instability due to increased scattering forces
Proposed design enhances the range of particle sizes that can be trapped
Results indicate potential for compact optical tweezers in microfluidic applications

Abstract

The numerical simulation results for optical trapping of silicon nanoparticles using lensed single-mode fibers at a wavelength of 1550 nm are presented. A single lensed fiber is shown to provide stable trapping of particles with a radius of up to 100 nm, whereas for larger particle sizes trapping becomes unstable due to increasing scattering force. An optical tweezers design based on two opposing lensed fibers is proposed, which makes it possible to expand significantly the size range of trapped particles. The sensitivity of the trapping force to fiber misalignment is analyzed. The obtained results can be used in the design of compact fiber optical tweezers for manipulating dielectric nanostructures and micro-objects in microfluidic systems.

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Modeling Particle Trapping Using Focused Radiation of an Optical Fiber Mode

Key Points

Abstract

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