“Certain wavelengths of ultraviolet light have the ability to inactivate microorganisms, like fungi and viruses, by damaging their DNA or RNA so that they can no longer reproduce,” Bahnfleth said. “Our research question for this project asks how well different wavelengths work to deactivate, or kill, coronaviruses like COVID-19.”
Inside a cabinet-like reactor, Bahnfleth, Kuchipudi and collaborator Jim Freihaut, professor of architectural engineering at Penn State, will measure the degree of disinfection of coronavirus samples exposed to ultraviolet light of 254- or 365-nanometer wavelengths for different time periods of exposure. The researchers will use a surrogate human coronavirus similar to the COVID-19 virus in their tests, which will be provided by the Penn State Department of Veterinary and Biomedical Sciences. The testing will take place in a Biosafety Level 2 laboratory at Penn State University Park.
“When best-practice ultraviolet levels and exposure times are determined, ultraviolet-based disinfection devices can then be designed to deactivate airborne viruses in building air supply systems, room or equipment surfaces, facial masks and virus sampling equipment,” Freihaut said. “The same technology could be used, going forward, to also deactivate bacteria and other types of viruses, but the levels of ultraviolet light may need to be adjusted for each specific target contaminant.”
Ultimately, Freihaut said, stakeholders could apply those same capabilities in the HVAC systems of schools and conference rooms, which are significant hotbeds for the spread of flu viruses of all types.
In the second segment of the project, Penn State’s Donghyun Rim, assistant professor of architectural engineering, and Richard Mistrick, associate professor of architectural engineering, will work with Bahnfleth to apply the findings of the experimental part of the study to computational fluid dynamics modeling and lighting simulations. The simulations will serve to predict the effect of the germicidal irradiation system combined with ventilation and filtration efforts on the viability of coronavirus samples.
“We will develop a plan to control different elements that go into the spatial model, as well as the infection risk that moves around the air distribution space,” Rim said. “We also will model the typical air motion of a room, which is usually removed, cleaned and then recirculated in a space.”
Merging the test data from the reactor system and the simulations, the researchers will then compare the ultraviolet sensitivity factors to those that have been reported in the literature for other virus types, like the polio-causing virus or the H1N1 flu virus, according to Freihaut.
Bahnfleth emphasized the practical component of this study, or what will make it useful for future consumers and building developers. With successful findings, a lamp could be manufactured that has both germicidal and lighting elements, where the germicidal element could be switched off and on as easily as engaging a light switch.
“This is 100-year-old technology, but it has only had moderate penetration outside of specialized markets like health care,” Bahnfleth said. “However, many are now realizing it is a technology that has potential to protect people in many types of buildings from the SARS-CoV-2 virus that causes COVID-19 and other dangerous pathogens.”
Sez Atamturktur, Harry and Arlene Schell Professor and head of the Department of Architectural Engineering, emphasized how new research in architectural engineering – like what Bahnfleth, Freihaut, Rim and Mistrick are pursuing – is necessary to re-shape the future of building construction and design methods in the years to come.
“This research can serve to expedite the return back to shared building spaces like offices,” she said.