Loading ...
Sorry, an error occurred while loading the content.

Device allows naked eye to see motion of 10 nanometers

Expand Messages
  • forbes4nano@aol.com
    Breakthrough Motion Detector 1,000 Times More Sensitive Than Any Known Device allows naked eye to see motion of 10 nanometers A new class of very small
    Message 1 of 1 , Sep 30 4:21 PM
    • 0 Attachment
      Breakthrough Motion Detector 1,000 Times More Sensitive Than Any Known
      Device allows naked eye to see motion of 10 nanometers

      A new class of very small handheld devices can detect motion a thousand
      times more subtly than any tool known.
      "There was nothing in the [_optics_ (http://www.physorg.com/search/optics) ]
      literature to predict that this would happen," says Sandia National
      Laboratories researcher Dustin Carr of his group's device, which reflects a bright
      light from a very small moving object.
      Sandia is a National Nuclear Security Administration laboratory.

      Carr, who earlier gained fame as a graduate student at Cornell for his
      creation of a nanoguitar, was selected this week by MIT's science magazine
      Technology Review as one of the year's top 100 researchers under the age of 35.

      The patent-applied-for device will be the subject of an invited talk at the
      SPIE Optics East convention in Philadelphia in October, delivered by Sandia
      team member Bianca Keeler.

      Like shadow pictures projected onto a wall by shining light through the
      fingers of one hand moving over the fingers of the other, the relatively simple
      measuring device depends upon a formerly unrecognized property of optics:
      light diffracted from very small gratings that move very small lateral distances
      undergoes a relatively big, and thus easily measurable, change in
      reflection. A motion of 10 nanometers can be seen by the naked eye, says Carr.

      A nanometer is one-thousandth of a micron, which is one millionth of a
      meter.

      As for the device, size matters and small is crucial. "In standard MEMS
      [microelectromechanical] applications, though the devices are small, very few
      things that sell are dominated by a search for further miniaturization. There's
      not a motivation in MEMS to make things still smaller as a matter of cost.
      Economics of scale for integrated circuits just don't apply to MEMS. But our
      device couldn't exist unless you made it this small," he says. Features are in
      the 100-200 nanometer range, with 300 nm between top and bottom combs and 600
      to 900 nm between comb teeth.

      Sub-wavelength interference effects cause the visual display.

      "Making use of the effect is fairly obvious once you realize it happens," he
      says.

      Fabricated out of polysilicon by standard lithography techniques like those
      used to make MEMS devices, the Sandia system uses two tiny comb-like
      structures (instead of fingers) laid one over each other. The bottom comb is locked
      rigidly in place. The top comb is secured only by horizontal springs. Any
      tiny motion sends the top comb skittering over the bottom comb, laterally
      deforming the grating. A very tiny disturbance changes by an unexpectedly large
      amount the amplitude of light - in the visible to near-infrared range -
      diffracted from a tiny laser beam shining upon the apparatus.

      The measuring device, still in the laboratory stage, is in effect a kind of
      accelerometer, about the size of the inexpensive microelectromechanical
      devices that open automobile air bags. Fabricated by the same processes that
      mass-produce silicon computer chips, the device has multiple possible uses.

      "If you can make very sensitive detectors very cheaply and very small, there
      are huge applications," says Carr. "Made small, synchronized, cheap, and
      placed on every block, we could take data from all these sensors at once and
      measure the motion of the earth when there's not an earthquake. So we could
      learn what leads up to one."

      Another use would be for skid and traction control in cars, detecting if the
      back end of the car is moving in a different direction from the front end.

      "Such devices also could take the place of inertial navigation systems,"
      Carr says. These typically require large gyroscopes to keep commercial airplanes
      moving on a preset course. "We could have handheld-sized devices on
      Volkswagens that would work even in a tunnel."

      Other defense applications are possible, he says.

      He sees a time frame of three to five years before the devices are available
      for use.

      Says James Walker, former Director of Advanced Technologies at Tellium,
      Inc., former manager of the MEMS Network Element Sub-systems Group at Lucent,
      Bell Laboratories, and now an independent consultant and patent agent, "To my
      understanding, it is the first time anyone has tried to manipulate the optical
      near-field region in order to affect changes to the far-field characteristics
      of a grating. The ability to do this is a direct result of the nano-scale
      nature of the device. Due to its high responsivity-to-displacement ratio, I see
      it having significant, far-reaching application in areas as diverse as
      chemical sensing, infrared imaging, accelerometry, and displays."

      Sandia is a multiprogram laboratory operated by Sandia Corporation, a
      Lockheed Martin company, for the U.S. Department of Energy's National Nuclear
      Security Administration. With main facilities in Albuquerque, N.M., and
      Livermore, Calif., Sandia has major R&D responsibilities in national security, energy
      and environmental technologies, and economic competitiveness.

      Source: DOE/Sandia National Laboratories


      [Non-text portions of this message have been removed]
    Your message has been successfully submitted and would be delivered to recipients shortly.