Study co-author Desirée Plata and colleagues revealed the results of their research at the national meeting of the American Chemical Society, describing their work as “totally new.”
While expressing concern about the possible health and environmental effects of nanotechnology by-products, Plata said the new data may be crucial as the nanotechnology industry seeks to avoid the kind of unanticipated health and environmental problems that have accompanied the emergence of other new technologies.
“Without this work, the environmental and health impacts of the carbon nanotube industry could be severe and costly to repair,” said Plata, a MIT doctoral student in chemical oceanography. “We would like to help it develop in an environmentally sustainable fashion.”
Plata did note that past analyses of the environmental impact of the emerging nanomaterials industry have been based on the toxicity of ingredients used in the recipes, rather than the actual pollutants formed while manufacturing CNT, which is expected to become the basis of multibillion-dollar industries in the 21st century. Carbon nanotubes, submicroscopic cylinders of carbon that are thousands of times smaller in diameter than the width a single human hair, possess characteristics not found in their larger counterparts, including enhanced strength and high electrical conductivity.
Human Health Risks of Carbon Nanotubes Unknown
Studies by other scientists have shown that carbon nanotubes, which come in many sizes and shapes, can damage the lungs of mice, but their exact risk to human health remains unknown. Even less is known about the potential effects of the byproducts of nanotube production, the researchers said.
To evaluate the emission products formed during nanotube production, Plata and her associates utilized a small-scale device to simulate “chemical vapor deposition,” one of the main methods for making CNTs. Using a carbon vapor source, the researchers produced CNTs and analyzed chemical byproducts from the reaction.
They found at least 15 aromatic hydrocarbons, including four different kinds of toxic polycyclic aromatic hydrocarbons (PAHs) similar to those found in cigarette smoke and automobile tailpipe emissions. The most harmful PAH identified was benzo[a]pyrene, a known human carcinogen, the researchers said. They also documented the release of other hydrocarbons that can contribute to smog formation and can trigger the formation of ozone in the lower atmosphere, which can in turn cause respiratory problems in humans, Plata said.
“If nanotubes are produced in the tons, there will also be tons of PAHs produced,” Plata notes. She said that the key solution to the problem may also be to employ special filters or "scrubbers" in the production process to reduce the formation of harmful by-products.
Another possible solution is to develop new nanotube manufacturing processes that produce fewer toxins, said Plata, who notes that the research team currently is currently working with four of the major nanotube producers in the United States to help develop strategies to make production more environmentally friendly.
CNTs already are produced on a small industrial scale, and the researchers plan to measure actual emissions at several industrial sites in the near future to get a clearer picture of real-world pollutant emissions.