AI Article Synopsis
- * It highlights the role of surface plasmon excitation near metal surfaces in enhancing or reducing optical forces for trapping particles, depending on the positioning of the laser beam.
- * A new anti-trapping effect is introduced, which could lead to advanced particle sorting techniques and improved control over motion at micro and nano scales using analytical theory.
Article Abstract
The ability to manipulate small objects with focused laser beams has opened a venue for investigating dynamical phenomena relevant to both fundamental and applied science. Nanophotonic and plasmonic structures enable superior performance in optical trapping via highly confined near-fields. In this case, the interplay between the excitation field, re-scattered fields and the eigenmodes of a structure can lead to remarkable effects; one such effect, as reported here, is particle trapping by laser light in a vicinity of metal surface. Surface plasmon excitation at the metal substrate plays a key role in tailoring the optical forces acting on a nearby particle. Depending on whether the illuminating Gaussian beam is focused above or below the metal-dielectric interface, an order-of-magnitude enhancement or reduction of the trap stiffness is achieved compared with that of standard glass substrates. Furthermore, a novel plasmon-assisted anti-trapping effect (particle repulsion from the beam axis) is predicted and studied. A highly accurate particle sorting scheme based on the new anti-trapping effect is analyzed. The ability to distinguish and configure various electromagnetic channels through the developed analytical theory provides guidelines for designing auxiliary nanostructures and achieving ultimate control over mechanical motion at the micro- and nano-scales.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6062188 | PMC |
| http://dx.doi.org/10.1038/lsa.2016.258 | DOI Listing |
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