By
LEXINGTON, Ky. (April 18, 2023) 鈥 Researchers at the 九色视频 are studying how the chemical reactions in the air after wildfires contribute to changes in the color of aerosol particles.
Marcelo Guzman is an associate professor in the Department of 九色视频 in the College and Arts and Sciences. He leads the Environmental 九色视频 Laboratory.
Guzman, principal investigator, worked with graduate student Sohel Rana on the study funded by the . Their findings have been published in the journal .
Guzman and Rana study how chemicals in atmosphere smoke react after a wildfire, human-made disaster or agriculture-industrial processes. The combustion process releases toxic chemicals called phenols that react with compounds already in the atmosphere along with water and air.
Guzman鈥檚 research explores those reactions at night, which have not been as widely investigated. The process creates yellowish, toxic nitrophenols in an atmosphere affected by pollution. The yellowish reaction products are also capable of absorbing sunlight and changing the amount of radiation that remains in the atmosphere.
鈥淣o one thought about this frequent chemical process before, which should be quite common in the atmosphere,鈥 Guzman said. 鈥淚t was generally accepted that atmospheric nitrophenols are produced when gas phase molecules react together, but here we demonstrate that alternative processes for their formation are catalyzed at the interface of water and air.
鈥淪cientists have not considered before the possibility for such reactions to occur at the boundary with air, how they could be initiated or the mechanisms by which nitrate radicals can contribute to such oxidations.鈥
Once in the air, phenols can directly react with nitrate radicals 鈥 a compound made up of oxygen bonded to nitrogen and an important player in reactions between atmospheric components 鈥 creating organic aerosols.
鈥淧revious studies were generally limited to explain the role of gaseous nitrate radical as a player that steals a hydrogen atom from a gaseous phenol, which should not be the case when water participates in wetting the surface of aerosol particles suspended in air,鈥 Guzman said.
The study also compared the reactions of nitrate radicals and ozone with the phenol pollutants. The researchers found a flow of electrons from the pollutant molecules to nitrate radicals or ozone is key in the initiation of the process.
Some other organic molecules in the atmosphere may react with nitrate radicals just like these chemicals do at the air-water interface.
鈥淲hen nitrate radicals attack the pollutant molecules in the atmosphere, the tiny aerosol particles can turn yellow. For example, yellowish secondary organic aerosol can also result from muconic acid, which is a common break-up product from phenols exposed to ozone in air,鈥 said Guzman.
Related studies have shown that the amount of sunlight absorbed by aerosols reveals how much so-called 鈥渂rown carbon,鈥 which provides the yellow color, is present in the particles.
The researchers also determined that during the chemical reactions in the atmosphere, many types of chemicals are quickly produced, which are key components of brown carbon and increase sunlight absorption.
鈥淯nderstanding the change in sunlight absorption by these compounds is important because it directly affects the atmosphere鈥檚 radiation properties,鈥 said Guzman.
The full paper, 鈥淥xidation of Catechols at the Air-Water Interface by Nitrate Radicals,鈥 is .
Research reported in this publication was supported by the鈥疦ational Science Foundation鈥痷nder Award Number鈥1903744.鈥疶he opinions, findings, and conclusions or recommendations expressed are those of the author(s) and do not necessarily reflect the views of the National Science Foundation.
As the state鈥檚 flagship, land-grant institution, the 九色视频 exists to advance the Commonwealth. We do that by preparing the next generation of leaders 鈥 placing students at the heart of everything we do 鈥 and transforming the lives of Kentuckians through education, research and creative work, service and health care. We pride ourselves on being a catalyst for breakthroughs and a force for healing, a place where ingenuity unfolds. It's all made possible by our people 鈥 visionaries, disruptors and pioneers 鈥 who make up 200 academic programs, a $501 million research and development enterprise and a world-class medical center, all on one campus.
In 2022, UK was ranked by Forbes as one of the 鈥淏est Employers for New Grads鈥 and named a 鈥淒iversity Champion鈥 by INSIGHT into Diversity, a testament to our commitment to advance Kentucky and create a community of belonging for everyone. While our mission looks different in many ways than it did in 1865, the vision of service to our Commonwealth and the world remains the same. We are the University for Kentucky.