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Aug 20th, 2013
 
Squeezed light created on-chip
 
A microchip-based way to create squeezed light could assist a range of precision measurements and provide a viable route toward real-world on-chip sensor applications and technology.
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Fig 1: SEM image of the silicon micromechanical resonator.
Fig 1: SEM image of the silicon micromechanical resonator.

Monitoring a mechanical object’s motion, even with a touch as gentle as that of light, fundamentally alters its dynamics. Squeezed light, with its quantum fluctuations below that of the vacuum field, was proposed nearly three decades ago as a way of overcoming the standard quantum limits in precision force measurements.

The generation of squeezed light was recently demonstrated in a system of ultracold gas-phase atoms, but the new system, engineered at the California Institute of Technology (Caltech), is a solid-state, optomechanical system fabricated from a silicon microchip and composed of a micromechanical resonator coupled to a nanophotonic cavity.

Fig 1: (a) SEM image of the silicon micromechanical resonator used to generate squeezed light. Light is coupled into the device using a narrow waveguide and reflects off a back mirror formed by a linear array of etched holes. Upon reflection, the light interacts with a pair of double-nanobeams (micromechanical resonator/optical cavity), which are deflected in a way that tends to cancel fluctuations in the light. (b) Numerical model of the differential in-plane motion of the nanobeams. Courtesy of Caltech/Amir Safavi-Naeini, Simon Groeblacher and Jeff Hill

"We work with a material that's very plain in terms of its optical properties," said graduate student Amir Savavi-Naeini. "We make it special by engineering or punching holes into it, making these mechanical structures that respond to light in a very novel way."  

A waveguide feeds laser light into a cavity created by two tiny silicon beams in the new system. Once there, the light bounces back and forth because of the engineered holes, which in effect turn the beams into mirrors. When photons strike the beams, the beams vibrate. The particulate nature of the light introduces quantum fluctuations that affect those vibrations.

Typically, such fluctuations mean that, to get a good signal reading, you would have to increase the power of the light to overcome the noise. But increasing power introduces other problems, such as excess heat. The new system has been engineered so that the light and beams interact strongly with each other — so strongly that the beams impart the quantum fluctuations they experience back on the light.

To read  more: http://www.photonics.com


 
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