Title :
Trapping and Rotation of Nanowires Assisted by Surface Plasmons
Author :
Miao, Xiaoyu ; Wilson, Benjamin K. ; Cao, Guozhong ; Pun, Suzie H. ; Lin, Lih Y.
Author_Institution :
Dept. of Electr. Eng., Univ. of Washington, Seattle, WA, USA
Abstract :
We report long-range trapping of vanadium dioxide (VO2) and vanadium oxyhydroxide (H2V3O8) nanowires at a distance as large as 50 mum outside the laser spot using plasmonic tweezers and controlled rotation of the nanowires by combining trapping with microfluidic drag force. The plasmonic tweezers are built upon a self-assembled gold nanoparticle array platform. In addition to the long-range trapping and rotation capability, the required optical intensity for the plasmonic tweezers to initiate trapping is much lower (8 muW/mum2) than that required by conventional optical tweezers for similar nanowires. We also investigate possible mechanisms for the unique long-range trapping of nanowires through performing control experiments.
Keywords :
drag; gold; laser beams; micro-optomechanical devices; microfluidics; nanoparticles; nanophotonics; nanowires; plasmonics; radiation pressure; self-assembly; surface plasmons; vanadium compounds; Au; H2V3O8; VO2; long-range trapping; microfluidic drag force; nanowires; optical intensity; optical trapping; plasmonic tweezers; self-assembled gold nanoparticle array platform; surface plasmons; vanadium dioxide; vanadium oxyhydroxide; Nanostructures; optical manipulation; surface plasmons;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2009.2016983
