Technologies
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WARF: P02042US

Spectroscopic Detection of Water Contaminants Using Glow Discharges from Liquid Microelectrodes


INVENTORS -

Yogesh Gianchandani, Chester Wilson

The Wisconsin Alumni Research Foundation (WARF) is seeking commercial partners interested in developing a system for on-site, real-time analysis of trace contaminants in liquids and gases.
OVERVIEWThreats to drinking water supplies from industrial and biochemical pollutants have created the need for rapid, on-site tools that detect and analyze trace contaminants in water. Current protocols for assessing water quality typically require transport of water samples to a laboratory for analysis with a plasma spectrometer. In plasma spectroscopy, a water sample is sprayed into a high-frequency, RF inductively-coupled plasma. Vaporized water droplets are then spectrally analyzed to determine the composition and quantity of impurities, such as heavy metals.
THE INVENTIONUW-Madison researchers have developed a micro-fabricated, on-chip spectroscopic system for on-site, real-time analysis of trace contaminants in liquids and gases. The system works as follows: Two microfluidic channels transport sampled water from two large reservoirs into two smaller pools, or liquid electrodes. A micro-glow discharge generated between the liquid electrodes sputters water molecules and impurity atoms into the discharge region. The resulting discharge emits discrete wavelengths of light that correspond to specific atomic transitions. By analyzing a spectrum of these wavelengths, the chemical composition of the water can be determined.
APPLICATIONS
  • Water impurity analysis
  • Gas detection for military applications
  • Localized detection of automobile emissions 
  • Wastewater analysis for compliance with environmental regulations
KEY BENEFITS
  • Small and portable, allowing real-time, on-site analysis of trace contaminants in water
  • Very inexpensive to manufacture compared to current large-scale plasma spectroscopy systems
  • Allows maintenance of a continuous glow discharge in air at atmospheric pressure, eliminating the need for a vacuum system
  • Electrodes are replenished by liquid flow, eliminating concern for electrode wear.
STAGE OF DEVELOPMENTDevice was shown to detect sodium impurities at concentrations of 10 ppm, and lead at concentrations of 5 ppm.
Contact Information
For current licensing status, please contact Mark Staudt at mstaudt@warf.org or 608-960-9845.
The WARF Advantage

Since its founding in 1925 as the patenting and licensing organization for the University of Wisconsin-Madison, WARF has been working with business and industry to transform university research into products that benefit society. WARF intellectual property managers and licensing staff members are leaders in the field of university-based technology transfer. They are familiar with the intricacies of patenting, have worked with researchers in relevant disciplines, understand industries and markets, and have negotiated innovative licensing strategies to meet the individual needs of business clients.