|
Topic Name: Figuring out a fast, low-noise technique for translating small mechanical motions into reasonable electronic signals
Category: Mechanical
Research persons: Flowers-Jacobs and his colleagues
Location: JILA ,University of Colorado,Boulder CO 80309-0440, United States
Details
A key challenge in developing new nanotechnologies is figuring out a fast, low-noise technique for translating small mechanical
motions into reasonable electronic signals. Solving this problem will one day make it possible to build electronic signal processing
devices that are much more compact than their purely electronic counterparts. Much sooner, it will enable the design of advanced
scanning tunneling microscopes that operate hundreds to thousands of times faster than current models.
As exciting as these possibilities are, they aren't the primary driver for research by graduate student Nathan Flowers-Jacobs, former
research associate Dan Schmidt, and Fellow Konrad Lehnert on the properties of an atomic point contact displacement detector they designed
and built. The researchers want to understand the fundamental physics of the device, which operates in accordance with the laws of
quantum mechanics. To accomplish this, they've developed a microwave-based technique to efficiently measure its performance.
To make the displacement detector, the researchers used lithography tools to create a gold structure with a freely suspended nanomechanical
beam (100 nm thick) connected initially to an atomic point contact, as shown below. Then the researchers ran a current through the point,
creating an electron wind that shoved atoms aside, creating a tiny gap between the point and the beam. During this process, they measured
the resistance of the point contact, looking for a characteristic increase in resistance indicating that electrons had started to hop (tunnel)
across the gap. An artist's conception of the atom-sized gap between the atomic point contact and the freely suspended nanomechanical beam is
shown at the right.
Once the device was up and running, the researchers monitored the size of the atom-sized gap by measuring the current that flowed through
the atomic point contact. However, there was also shot noise in the current. This noise arises from the fact that current across the gap is
composed of individual, discreet tunneling electrons subject to the laws of quantum mechanics, i.e., tunneling is a random probabilistic event.
Even though the researchers could easily determine the average current, the nature of a tunneling current meant there would always be fluctuations
around this average, or shot noise. The shot noise limited how accurately the position of the freely suspended beam could be determined.
However, when more electrons traveled across the gap per second, less noise affected the displacement measurement. If shot noise were the only
issue in measuring tunneling current, then Flowers-Jacobs and his colleagues could simply have increased the average current through their device
until the displacement noise became as small as desired. Unfortunately, there was also a random force acting on the freely suspended beam due to
the measurement itself. Called backaction, this random force could noticeably shake the beam and move it more than the measurement uncertainty
due to shot noise. Naturally, the backaction got worse as the average current increased, creating a tradeoff between backaction and imprecision in
the measurements. The researchers decided their best strategy was to control the current through the atomic point contact such that the effects of
the shot noise and backaction were approximately equal. Their measurement was so sensitive it could detect the beam's random thermal motion at
temperatures as low as 250 mK and the precision was only 40-fold worse than the quantum mechanical limit.
To achieve this precision, Flowers-Jacobs and his colleagues used a very clever microwave measurement technique that was fast enough to detect
the freely suspended beam's resonant motion. To make the displacement measurement, the researchers hooked up their device to a microwave-frequency
tank circuit, which is a resonance circuit that stores electrical energy. They determined the size of the atomic point contact gap by measuring how
quickly electrical energy leaked out of the tank circuit. The rapid measurements possible with this system allowed them to "see" the freely
suspended beam wiggle more than 40 million times per second and quantify both the shot-noise-limited imprecision (2.3 fm/vHz) and the backaction
force (78 aN/vHz) .
Funded:
JILA funded this program which is
jointly operated by the University of Colorado (CU) and the National Institute
of Standards and Technology (NIST).
 
| Related research: |
Complex tangle of curves corresponding to two very different motions of particles in the flow., Leveraging learning for artificial respiration, NIST imaging system maps the mechanical properties of materials, Research team hopes Portable electricity, life-like prosthetics on the way, Researchers at Carnegie Mellon University has Developed Magnetic levitation that Gives Computer Users Sense of Touch, Researchers Successfully Unveiled Three-Dimensional Visualisation of Magnetic Fields Inside Solid, Non-Transparent Materials, Researchers work toward spark-free, fuel-efficient engines, Robotics and Control, Scientists are Trying to Amalgamate Magnetism and Magnetic Materials with Promising Electronic Materials such as Organic Semiconductors, USC Researchers Say Precision Hand Manipulation is the Result of a Complex Neuro-Motor-Mechanical Process Orchestrated, UW Researchers Design a New Camera in a Pill Offers Cheaper, Easier Window on Insides and more Comfortable for the Patient, Wind tunnel experimentation, Wireless solutions for precision agriculture
|
|
