Controlling photonic structures using optical forces
TLDR
A resonant structure is implemented whose optical response can be efficiently statically controlled using relatively weak attractive and repulsive optical forces, and a static mechanical deformation of up to 20 nanometres in a silicon nitride structure is demonstrated, using three milliwatts of continuous optical power.Abstract:
The use of optical forces to manipulate small objects is well known. Applications include the manipulation of living cells by optical tweezers and optical cooling in atomic physics. The miniaturization of optical systems (to the micro and nanoscale) has resulted in very compliant systems with masses of the order of nanograms, rendering them susceptible to optical forces. Optical forces have been exploited to demonstrate chaotic quivering of microcavities, optical cooling of mechanical modes, actuation of a tapered-fibre waveguide and excitation of the mechanical modes of silicon nano-beams. Despite recent progress in this field, it is challenging to manipulate the optical response of photonic structures using optical forces; this is because of the large forces that are required to induce appreciable changes in the geometry of the structure. Here we implement a resonant structure whose optical response can be efficiently statically controlled using relatively weak attractive and repulsive optical forces. We demonstrate a static mechanical deformation of up to 20 nanometres in a silicon nitride structure, using three milliwatts of continuous optical power. Because of the sensitivity of the optical response to this deformation, such optically induced static displacement introduces resonance shifts spanning 80 times the intrinsic resonance linewidth.read more
Citations
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References
More filters
Journal ArticleDOI
Cavity Opto-Mechanics
TL;DR: In this article, the consequences of back-action of light confined in whispering-gallery dielectric micro-cavities, and presents a unified treatment of its two manifestations: namely the parametric instability (mechanical amplification and oscillation) and radiation pressure backaction cooling.
Journal ArticleDOI
Optical Trapping and Manipulation of Viruses and Bacteria
Arthur Ashkin,J. M. Dziedzic +1 more
TL;DR: Trapping and manipulation of single live motile bacteria and Escherichia coli bacteria were demonstrated in a high-resolution microscope at powers of a few milliwatts.
Journal ArticleDOI
Cavity Optomechanics: Back-Action at the Mesoscale
TL;DR: Recent experiments have reached a regime where the back-action of photons caused by radiation pressure can influence the optomechanical dynamics, giving rise to a host of long-anticipated phenomena.
Journal ArticleDOI
Cooling of gases by laser radiation
TL;DR: In this article, it was shown that a low-density gas can be cooled by illuminating it with intense, quasi-monochromatic light confined to the lower-frequency half of a resonance line's Doppler width.
Journal ArticleDOI
A picogram- and nanometre-scale photonic-crystal optomechanical cavity
TL;DR: Measurements of an optical system consisting of a pair of specially patterned nanoscale beams in which optical and mechanical energies are simultaneously localized to a cubic-micron-scale volume and for which large per-photon optical gradient forces are realized enable the exploration of cavity optomechanical regimes.