There are two commonly employed methods to sanitize and disinfect areas from bacteria and viruses: either using chemicals or exposure to ultraviolet radiation. This radiation is in the 200 to 300 nanometer range and known to destroy the virus, making it incapable of reproducing and infecting. Widespread adoption of this more efficient UV approach is much in demand in the current situation of a world-wide pandemic, but it requires UV radiation sources that emit sufficiently high doses of UV light. While those devices currently exist, the UV radiation source is typically an expensive mercury-containing gas discharge lamp, which requires high power, has a relatively short lifetime and a bulky form factor. The solution is to develop high performance UV light emitting diodes (LEDs), which would be far more portable, long-lasting, energy efficient and environmentally benign. While these LEDs exist, applying a current to them for light emission is complicated by the fact that the electrode material also has to be transparent to UV light.
“You have to ensure a sufficient UV light dose to kill all the viruses,” said Roman Engel-Herbert, Penn State associate professor of materials science, physics and chemistry. “This means you need a high-performance UV LED emitting a high intensity of UV light, which is currently limited by the transparent electrode material being used.”
While it has been a long-standing problem to find transparent electrode materials operating in the visible spectrum for displays, smartphones and LED lighting, the challenge is even more difficult for ultraviolet light.
“There is currently no good solution for an UV-transparent electrode,” said Joseph Roth, Ph.D. candidate in Materials Science and Engineering at Penn State. “Right now, the current material solution commonly employed for visible light application is used despite it being too absorbing in the UV range. There is simply no good material choice for a UV-transparent conductor material that has been identified.”
Finding a new material with the right composition is key to advancing UV LED performance. The Penn State team, in collaboration with materials theorist from the University of Minnesota, recognized early on that the solution for the problem might be found in a recently discovered new class of transparent conductors. When theoretical predictions pointed to the material strontium niobate, the researchers reached out to their Japanese collaborators to receive strontium niobate films and immediately tested their performance as UV transparent conductors. While these films held the promise of the theoretical predictions, a deposition method had to be found to integrate these films in a scalable way.
“We immediately tried to grow these films using the standard film-growth technique widely adopted in industry, called sputtering,” Roth said.
This a critical step towards technology maturation which makes it possible to integrate this new material into UV LEDs at low cost and high quantity. And this is what both believe is necessary during this crisis.
“While our first motivation in developing UV transparent conductors was to build an economic solution for water disinfection, we now realize that this breakthrough discovery potentially offers a solution to deactivate COVID-19 in aerosols that might be distributed in HVAC systems of building,” Roth explains. Other areas of application for virus disinfection are densely and frequently populated areas, such as theatres, sports arenas and public transportation vehicles, such as buses, subways and airplanes.
Their findings appear online today, June 1, in the Nature Group publication Physics Communications. Co-authors along with Roth and Engel-Herbert, are Yoonsang Park, Alexej Pogrebnyakov and Venkatraman Gopalan of Penn State, Daichi Oka of Tohoku University, Yasushi Hirose and Tetsuya Hasegawa of the University of Tokyo and Arpita Paul and Turan Birol of the University of Minnesota. The paper, titled “SrNbO3 as a transparent conductor in the visible and ultraviolet spectra,” is accessible online at no charge.
This work was supported by the National Science Foundation through the DMREF program and a Graduate Research Fellowship as well as the Japan Society for the Promotion of Science KAKENHI program.
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