Add to ORKGABSTRACT Optical tweezers1 have enabled a number of microscale processes such as single cell handling2, flow-cytometry,3 directed assembly,4,5 and optical chromatography.6,7 To extend this functionality to the nanoscale, a number of near-field approaches have been developed that yield much higher optical forces by confining light to subwavelength volumes.8-10 At present, these techniques are limited in both the complexity and precision with which handling can be performed. Here, we present a new class of nanoscale optical trap exploiting optical resonance in one-dimensional silicon photonic crystals. The trapping of 48 nm and 62 nm dielectric nanoparticles is demonstrated along with the ability to transport, trap, and manipulate larger nano...
Gentle manipulation of micrometer-sized dielectric objects with optical forces has found many applic...
We demonstrate, for the first time, the trapping and manipulation of individual Si nanowires by ligh...
The ability to controllably handle the smallest materials is a fundamental enabling technology for n...
International audienceFourteen years ago, optical lattices and holographic tweezers were considered ...
The ability to optically trap nanoscale particles in a reliable and noninvasive manner is emerging a...
On-chip optical tweezers based on evanescent fields overcome the diffraction limit of the free-space...
International audienceParticles manipulation with optical forces is known as optical tweezing. While...
The ability to optically trap nanoscale particles in a reliable and noninvasive manner is emerging a...
We demonstrate that silicon (Si) nanoparticles with scattering properties exhibiting strong dielectr...
© 2016 American Chemical Society. We demonstrate that silicon (Si) nanoparticles with scattering pro...
Recent advances in nanotechnologies have prompted the need for tools to accurately and non-invasivel...
Gentle manipulation of micrometer-sized dielectric objects with optical forces has found many applic...
We show that the photonic confinement induced by a photonic crystal can be exploited to trap nanopar...
In recent years, optical micromachines based on forces exerted by strongly focused beams of light ha...
Gentle manipulation of micrometer-sized dielectric objects with optical forces has found many applic...
We demonstrate, for the first time, the trapping and manipulation of individual Si nanowires by ligh...
The ability to controllably handle the smallest materials is a fundamental enabling technology for n...
International audienceFourteen years ago, optical lattices and holographic tweezers were considered ...
The ability to optically trap nanoscale particles in a reliable and noninvasive manner is emerging a...
On-chip optical tweezers based on evanescent fields overcome the diffraction limit of the free-space...
International audienceParticles manipulation with optical forces is known as optical tweezing. While...
The ability to optically trap nanoscale particles in a reliable and noninvasive manner is emerging a...
We demonstrate that silicon (Si) nanoparticles with scattering properties exhibiting strong dielectr...
© 2016 American Chemical Society. We demonstrate that silicon (Si) nanoparticles with scattering pro...
Recent advances in nanotechnologies have prompted the need for tools to accurately and non-invasivel...
Gentle manipulation of micrometer-sized dielectric objects with optical forces has found many applic...
We show that the photonic confinement induced by a photonic crystal can be exploited to trap nanopar...
In recent years, optical micromachines based on forces exerted by strongly focused beams of light ha...
Gentle manipulation of micrometer-sized dielectric objects with optical forces has found many applic...
We demonstrate, for the first time, the trapping and manipulation of individual Si nanowires by ligh...
The ability to controllably handle the smallest materials is a fundamental enabling technology for n...