Environmental scientists led by the Virginia Tech College of Science have discovered that the burning of coal produces incredibly small particles of a highly unusual form of titanium oxide.
When inhaled, these nanoparticles can enter the lungs and potentially the bloodstream.
The particulates -- known as titanium suboxide nanoparticles -- are unintentionally produced as coal is burned, creating these tiniest of particles, as small as 100 millionths of a meter, said the Virginia Tech-led team. When the particles are introduced into the air -- unless captured by high-tech particle traps -- they can float away from power plant stacks and travel on air currents locally, regionally, and even globally.
As an example of this, these nanoparticles were found on city streets, sidewalks, and in standing water in Shanghai, China.
The findings are published in the latest issue of Nature Communications under team leader Michael F. Hochella Jr., University Distinguished Professor of Geosciences with the College of Science, and Yi Yang, a professor at East China Normal University in Shanghai. Other study participants include Duke University, the University of Kentucky, and Laurentian University in Canada.
"The problem with these nanoparticles is that there is no easy or practical way to prevent their formation during coal burning," Hochella said, adding that in nations with strong environmental regulations, such as the United States, most of the nanoparticles would be caught by particle traps. Not so in Africa, China, or India, where regulations are lax or nonexistent, with coal ash and smoke entering the open air.
"Due to advanced technology used at U.S.-based coal burning power plants, mandated by the Clean Air Act and the Environmental Protection Agency, most of these nanoparticles and other tiny particles are removed before the final emission of the plant's exhaust gases," Hochella said. "But in countries where the particles from the coal burning are not nearly so efficiently removed, or removed at all, these titanium suboxide nanoparticles and many other particle types are emitted into the atmosphere, in part resulting in hazy skies that plague many countries, especially in China and India."
Hochella and his team found these previously unknown nanoparticles not only in coal ash from around the world and in the gaseous waste emissions of coal plants, but on city streets, in soils and storm water ponds, and at wastewater treatment plants.
"I could not believe what I have found at the beginning, because they had been reported so extremely rarely in the natural environment," said Yang, who once worked as a visiting professor in Virginia Tech's Department of Geosciences with Hochella. "It took me several months to confirm their occurrence in coal ash samples."
The newly found titanium suboxide -- called Magnéli phases -- was once thought rare, found only sparingly on Earth in some meteorites, from a small area of rock formations in western Greenland, and occasionally in moon rocks. The findings by Hochella and his team indicate that these nanoparticles are in fact widespread globally. They are only now being studied for the first time in natural environments using powerful electron microscopes.
Why did the discovery occur now? According to the report, nearly all coal contains traces of the minerals rutile and/or anatase, both "normal," naturally occurring, and relatively inert titanium oxides, especially in the absence of light. When those minerals are burned in the presence of coal, research found they easily and quickly converted to these unusual titanium suboxide nanoparticles. The nanoparticles then become entrained in the gases that leave the power plant.
When inhaled, the nanoparticles enter deep into the lungs, potentially all the way into the air sacs that move oxygen into our bloodstream during the normal breathing process. While human lung toxicity of these particles is not yet known, a preliminary biotoxicity test by Hochella and Richard Di Giulio, professor of environmental toxicology, and Jessica Brandt, a doctoral candidate, both at Duke University, indicates that the particles do indeed have toxicity potential.
According to the team, further study is clearly needed, especially biotoxicity testing directly relevant to the human lung.
Source: Virginia Tech College of Science