Newswise — WASHINGTON, D.C., NOVEMBER 6, 2018 -- Many of today’s methods of purifying water rely on filters and chemicals that need regular replenishing or maintenance. Millions of people, however, live in areas with limited access to such materials, leading the research community to explore new options of purifying water in using plasmas. Many plasma-based approaches are expensive, but a new class of plasma devices may change that. 

Researchers at the University of Alabama in Huntsville have been studying a new type of plasma generator for water purification. The new generator pulses voltage signals to ionize gas at atmospheric pressure and produce many useful byproducts, including hydroxyl radicals, which cause a cascade of reactions that lead to purer water samples. 

“We’re finding ways to speed up the purification process,” said Ryan Gott, a doctoral candidate in aerospace engineering at UAH who will present the research next week at the American Physical Society 71st Annual Gaseous Electronics Conference and the 60th Annual meeting of the APS Division of Plasma Physics, which will take place Nov. 5-9 at the Oregon Convention Center in Portland. 

“In theory, if this technology can be developed in a real-world, practical system, it would be able to purify water at lower costs than current methods can,” Gott said. 

While the term “plasma” conjures images of superhot solar jets traveling through space, most plasma-based water purification approaches work through plasma’s ability to generate reactive free radicals, rendering many compounds in the water inert. The plasma and ensuing chemical reactions release energy and chemical species that can kill even tough microcystin bacteria, one culprit in algal blooms that lurk in our water supply. 

“The pulses are so fast that it doesn’t change the temperature of the water,” Gott said. “You can touch our plasma jet with your hand.” 

Unlike more common, ozone-producing plasma purifiers, the new device relies on the production of hydroxyl radicals. This method will hopefully sidestep some of the hurdles that have hampered ozone-based counterparts, namely high power consumption and challenges keeping excessive heat in check. 

Using optical emission spectroscopy, the UAH researchers have been able to compare how different factors play a role in producing more hydroxyl radicals from their plasma device. Increasing voltage, for example, appears to have the biggest effect on output, followed by increasing the frequency of the pulses. 

Right now, the device is limited to 10 kilovolts, but the researchers are hoping to see what higher voltage could mean down the road. 

Gott said after the group continues to better understand the mechanisms behind how the plasma interacts with water, he hopes to scale up the technology for point-of-use applications. 

“The end goal is to develop something that can be mass-produced and distributed to places that need it the most,” he said. 

### 

Presentation #ET4.6, "Optical Measurements of OH in an Atmospheric Plasma Jet for Plasma-Based Water Purification" by Ryan Gott and Kunning Xu will be Tuesday, Nov. 6, 11:00 a.m. in Room A107-A109 of the Oregon Convention Center. Abstract: http://meetings.aps.org/Meeting/GEC18/Session/ET4.6 

This material is based upon work supported by the NSF EPSCoR RII-Track-1 Cooperative Agreement OIA-1655280. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the National Science Foundation. 

### 

----------------------- MORE MEETING INFORMATION ----------------------- 

USEFUL LINKS 

Main meeting website: http://www.apsgec.org/gec2018/
Meeting abstracts: http://meetings.aps.org/Meeting/GEC18/APS_epitome
Hotel information: http://www.apsgec.org/gec2018/housing.php 

PRESS REGISTRATION 

We will grant free registration to credentialed journalists and professional freelance journalists. If you are a reporter and would like to attend, contact Rhys Leahy or the AIP Media Line ([email protected], 301-209-3090). We can also help with setting up interviews and obtaining images, sound clips, or background information. 

ABOUT GEC 

GEC is a special meeting of the Division of Atomic, Molecular and Optical Physics (DAMOP) of the American Physical Society. GEC promotes invaluable exchange of scientific information, viewpoints, and approaches (experimental, theoretical, modeling, and numerical simulation) to understanding the physical and chemical processes occurring in partially ionized, collisional plasmas and between the atoms, molecules, charged particles, photons, waves, and fields. More: http://www.apsgec.org/gec2018/index.php 

ABOUT DAMOP 

The Division of Atomic, Molecular and Optical Physics (DAMOP) was founded in 1943, and it was the first division of the American Physical Society. Its central focus is fundamental research on atoms, simple molecules, electrons and light, and their interactions. More: https://www.aps.org/units/damop/index.cfm 

ABOUT APS 

The American Physical Society (APS) is a nonprofit membership organization working to advance the knowledge of physics. More: https://www.aps.org 

###