NIST Creates New Aproach to 'Electronic Noses'
November 12, 2008 // Published as a news service by IHS
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Researchers at the National Institute of Standards and Technology (NIST) created a new approach for "electronic noses" that could be a potent tool for applications such as sniffing out nerve agents, environmental contaminants and trace indicators of disease, in addition to monitoring industrial processes and aiding in space exploration.
Described in the October 15 issue of Analytical Chemistry, the electronic nose, which mimics the way animals recognize odors, is more adept than conventional methodologies at recognizing molecular features, even for chemicals it has not been trained to detect.
It's also robust enough to deal with the changes in sensor response that come with wear and tear.
In animals, odorant molecules in the air enter the nostrils and bind with sensory neurons in the nose that convert the chemical interactions into an electrical signal that the brain interprets as a smell.
In humans, there are about 350 types of sensory neurons and many copies of each type; dogs and mice have several hundred more types of sensory neurons.
Odor recognition proceeds in a step-by-step fashion where the chemical identity is gradually resolved: initial coarse information (such as ice cream is fruit-flavored vs. chocolate-flavored) is refined over time to allow finer discrimination (strawberry vs. raspberry). This biological approach inspired the researchers to develop a parallel "divide and conquer" method for use with the electronic nose.
The technology is based on interactions between chemical species and semiconducting sensing materials placed on top of microelectromechanical system (MEMS) microheater platforms.
The electronic nose employed in the current work is comprised of eight types of sensors in the form of oxide films deposited on the surfaces of 16 microheaters, with two copies of each material. Precise control of the individual heating elements allows the scientists to treat each of them as a collection of virtual sensors at 350 degree temperature increments between 150 C to 500 C, increasing the number of sensors to about 5,600.
The combination of the sensing films and the ability to vary the temperature gives the device the analytical equivalent of a snoot full of sensory neurons.
Much like the way people detect and remember many different smells and use that knowledge to generalize about smells they haven't encountered before, the electronic nose also needs to be trained to recognize the chemical signatures of different smells before it can deal with unknowns.
The great advantage of this system, according to NIST researchers Barani Raman and Steve Semancik, is that you don't need to expose the array to every chemical it could come in contact with in order to recognize and/or classify them. Breaking the identification process down into simple, small, discrete steps using the most information-rich data also avoids "noisy" portions of the sensor response, thereby incorporating robustness against the effects of sensor drift or aging.
NIST researchers say they are continuing to work on applications involving rapid identification of chemicals in unknown backgrounds or in a complex cocktail.
Source: National Institute of Standards and Technology (NIST).