Controlling Plasmas for a Cleaner World
New findings indicate that ionized plasmas like those in neon lights and plasma TVs can be used to sterilize water, making it antimicrobial for as long as a week after treatment.
The Science
Researchers at the University of California, Berkeley have revealed conditions under which Plasma-Activated Water created via indirect air dielectric barrier discharge can maintain antibacterial effectiveness for a period of up to 7 days.
The Impact
Plasmas interacting with water can be controlled to create antibacterial compounds, creating a useful disinfectant for up to seven days, and a potential improvement over traditional heat and chemical methods for sterilization of medical equipment and wounds.
Summary
When water is exposed to air adjacent to dielectric-barrier-discharge generated plasma, various chemical compounds including hydrogen peroxides and nitrites arise in the water that have the ability to kill bacteria. This water is known as Plasma-Activated Water (PAW). Work at the University of California at Berkeley partially funded by the Office of Science Fusion Energy Sciences program through its Center for Predictive Control of Plasma Kinetics has shown that the PAW can stay antibacterial for up to seven days. Suspensions of E. coli were exposed to PAW for various durations over a 7-day period; samples exposed for longer times showed a significant decrease in the E. coli population. Because of its anti-bacterial capacity, PAW has the potential for a multitude of applications such as sterilization of medical equipment and the treatment of wounds. While further research remains before PAW can be used in clinical settings, these early results are promising.
Contact
Douglas S. Clark
clark@berkeley.edu
David B. Graves
graves@berkeley.edu
Funding
Office of Science Fusion Energy Sciences (FES) program, UC Berkeley, and Department of Homeland Security (DHS) Scholarship and Fellowship Program administered by ORISE.
Publications
Matthew J Traylor et al.“Long-term antibacterial efficacy of air plasma-activated water,” J. Phys. D: Appl. Phys. 44 472001 (2011). [doi:10.1088/0022-3727/44/47/472001]
Matthew J Pavlovich et al. “Effects of discharge parameters and surface characteristics on ambient gas plasma disinfection,” Plasma Processes and Polymers. 9, in press (2012).
Related Links
http://graves-lab.cchem.berkeley.edu
http://iopscience.iop.org/0022-3727/44/47/472001
Highlight Categories
Program: FES
Performer: University
Additional: Technology Impact