Abstract
Optomechanical manipulation of plasmonic nanoparticles is an area of current interest, both fundamental and applied. However, no experimental method is available to determine the forward-directed scattering force that dominates for incident light of a wavelength close to the plasmon resonance. Here, we demonstrate how the scattering force acting on a single gold nanoparticle in solution can be measured. An optically trapped 80 nm particle was repetitively pushed from the side with laser light resonant to the particle plasmon frequency. A lock-in analysis of the particle movement provides a measured value for the scattering force. We obtain a resolution of less than 3 femtonewtons which is an order of magnitude smaller than any measurement of switchable forces performed on nanoparticles in solution with single beam optical tweezers to date. We compared the results of the force measurement with Mie simulations of the optical scattering force on a gold nanoparticle and found good agreement between experiment and theory within a few fN.
Highlights
Optomechanical manipulation of plasmonic nanoparticles is an area of current interest, both fundamental and applied
No experimental method is available to determine the forward-directed scattering force that dominates for incident light of a wavelength close to the plasmon resonance
We demonstrate how the scattering force acting on a single gold nanoparticle in solution can be measured
Summary
Optomechanical manipulation of plasmonic nanoparticles is an area of current interest, both fundamental and applied. Pushing nanoparticles with light — A femtonewton resolved measurement of optical scattering forces We demonstrate how the scattering force acting on a single gold nanoparticle in solution can be measured.
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