Add to ORKGWe present a study of optically bound matter formation in a counter-propagating evanescent field, exploiting total internal reflection on a prism surface. Small ensembles of silica microspheres are assembled in a controlled manner using optical tweezers. The structures and dynamics of the resulting optically bound chains are interpreted using a simulation implementing generalized Lorentz-Mie theory. In particular, we observe enhancement of the scattering force along the propagation direction of the optically bound colloidal chains leading to a microscopic analogue of a driven pendulum which, at least superficially, resembles Newton's cradle
Sub-micron particles have been observed to spontaneously form regular two-dimensional structures in ...
<p> In this Letter, we demonstrate the formation of a stable two-dimensional lattice of colloidal p...
Optical binding has recently gained considerable attention because it enables the light-induced asse...
We present a study of optically bound matter formation in a counter-propagating evanescent field, ex...
It is known that light can be used to manipulate and trap colloidal microspheres. What is less known...
In this paper, we detail two techniques for standing wave evanescent field optical trapping utilizin...
We present an experimental and theoretical study of long distance optical binding effects acting upo...
Very high frequency oscillations of intense light fields interact with micron-size dielectric object...
Optical manipulation is of broad interest in physics, chemistry, and biology. In the literature, mos...
Optical trapping of colloidal microparticle arrays in evanescent fields is a relatively new area of ...
We experimentally demonstrate stable trapping and controlled manipulation of silica microspheres in ...
Optical binding refers to the light-induced organization and ordering of microparticles. In this pap...
In this Letter, we demonstrate stable optical binding of spherical microparticles in counter-propaga...
This thesis explores the structures and dynamics of optically confined matter, ranging from single p...
Recently a non-contact organization of sub-micron colloidal particles in the vicinity of liquid-soli...
Sub-micron particles have been observed to spontaneously form regular two-dimensional structures in ...
<p> In this Letter, we demonstrate the formation of a stable two-dimensional lattice of colloidal p...
Optical binding has recently gained considerable attention because it enables the light-induced asse...
We present a study of optically bound matter formation in a counter-propagating evanescent field, ex...
It is known that light can be used to manipulate and trap colloidal microspheres. What is less known...
In this paper, we detail two techniques for standing wave evanescent field optical trapping utilizin...
We present an experimental and theoretical study of long distance optical binding effects acting upo...
Very high frequency oscillations of intense light fields interact with micron-size dielectric object...
Optical manipulation is of broad interest in physics, chemistry, and biology. In the literature, mos...
Optical trapping of colloidal microparticle arrays in evanescent fields is a relatively new area of ...
We experimentally demonstrate stable trapping and controlled manipulation of silica microspheres in ...
Optical binding refers to the light-induced organization and ordering of microparticles. In this pap...
In this Letter, we demonstrate stable optical binding of spherical microparticles in counter-propaga...
This thesis explores the structures and dynamics of optically confined matter, ranging from single p...
Recently a non-contact organization of sub-micron colloidal particles in the vicinity of liquid-soli...
Sub-micron particles have been observed to spontaneously form regular two-dimensional structures in ...
<p> In this Letter, we demonstrate the formation of a stable two-dimensional lattice of colloidal p...
Optical binding has recently gained considerable attention because it enables the light-induced asse...