Add to ORKGOptical trapping of colloidal microparticle arrays in evanescent fields is a relatively new area of study. Optically driven array formation is a complex and fascinating area of study, since light mediated interactions have been shown to cause significantly different behaviour for multiple particles when compared with the behaviour of a single particle in an optical field. Array formation was studied with interference fringes in the counterpropagating evanescent fields so as to investigate the effect of a periodic trapping potential. A subtle balance between optical trapping and optical binding forces is shown to produce modulated lines and arrays. Optically trapped colloidal arrays were also studied in the absence of interference fringes, b...
The invention of the laser in 1960 opened the door for a myriad of studies on the interactions betwe...
In this Letter, we demonstrate stable optical binding of spherical microparticles in counter-propaga...
AbstractWe investigate the manipulation of microscopic and nanoscopic particles using the evanescent...
Optical trapping of colloidal microparticle arrays in evanescent fields is a relatively new area of ...
Very high frequency oscillations of intense light fields interact with micron-size dielectric object...
Interaction of electromagnetic waves with small particles has been extensively investigated for dete...
We present an experimental and theoretical study of long distance optical binding effects acting upo...
Plasmonic nanoparticles, typically gold and silver colloids, can be trapped by a highly focused Gaus...
A tightly focused light beam can stably trap small objects in three dimensions. Using spatial light ...
Recently a non-contact organization of sub-micron colloidal particles in the vicinity of liquid-soli...
This thesis explores the structures and dynamics of optically confined matter, ranging from single p...
Optical trapping is an established field for movement of micron-size objects and cells. However, tra...
<p> In this Letter, we demonstrate the formation of a stable two-dimensional lattice of colloidal p...
We report on the trapping of micrometer colloids using the evanescent wave from a multimode cylindri...
We report optical trapping and assembling of colloidal particles at a glass/solution interface with ...
The invention of the laser in 1960 opened the door for a myriad of studies on the interactions betwe...
In this Letter, we demonstrate stable optical binding of spherical microparticles in counter-propaga...
AbstractWe investigate the manipulation of microscopic and nanoscopic particles using the evanescent...
Optical trapping of colloidal microparticle arrays in evanescent fields is a relatively new area of ...
Very high frequency oscillations of intense light fields interact with micron-size dielectric object...
Interaction of electromagnetic waves with small particles has been extensively investigated for dete...
We present an experimental and theoretical study of long distance optical binding effects acting upo...
Plasmonic nanoparticles, typically gold and silver colloids, can be trapped by a highly focused Gaus...
A tightly focused light beam can stably trap small objects in three dimensions. Using spatial light ...
Recently a non-contact organization of sub-micron colloidal particles in the vicinity of liquid-soli...
This thesis explores the structures and dynamics of optically confined matter, ranging from single p...
Optical trapping is an established field for movement of micron-size objects and cells. However, tra...
<p> In this Letter, we demonstrate the formation of a stable two-dimensional lattice of colloidal p...
We report on the trapping of micrometer colloids using the evanescent wave from a multimode cylindri...
We report optical trapping and assembling of colloidal particles at a glass/solution interface with ...
The invention of the laser in 1960 opened the door for a myriad of studies on the interactions betwe...
In this Letter, we demonstrate stable optical binding of spherical microparticles in counter-propaga...
AbstractWe investigate the manipulation of microscopic and nanoscopic particles using the evanescent...