Near-field optical manipulation has been widely used for guiding and trapping nanoscale
objects close to an optical-active interface. This near-field manipulation opens opportunities …

Gentle manipulation of micrometer-sized dielectric objects with optical forces has found
many applications in both life and physical sciences. To further extend optical trapping …

Localized surface plasmon resonance (LSPR) with a sharp field gradient and extremely
strong field intensity is very attractive for near-field optical nano-tweezers manipulating tiny …

Optical trapping using plasmonic nanoapertures has proven to be an effective means for the
contactless manipulation of nanometer-sized particles under low optical intensities. These …

The precise noninvasive optical manipulation of nanometer-sized particles by evanescent
fields, instead of the conventional optical tweezers, has recently awaken an increasing …

We experimentally demonstrated the use of random plasmonic nano-islands for optical
trapping and assembling of particles and live cells into highly organized pattern with low …

Plasmonics, a rapidly emerging subdiscipline of nanophotonics, is aimed at exploiting
surface plasmons for important applications, including sensing, waveguiding, and imaging …

Plasmonic nanocavities have proved to confine electromagnetic fields into deep
subwavelength volumes, implying their potentials for enhanced optical trapping and sensing …

The optomechanical interaction between a plasmonic nanocavity and a gold nanorod
through optical forces is demonstrated. It is revealed that strong localized plasmon …

Optical trapping with plasmonic double nanohole (DNH) apertures has proven to be an
efficient method for trapping sub-50 nm particles due to their suppressed plasmonic heating …