Off Road Diesel Vehicles Contribute to Pollution
News Dec 11, 2017 | Original Story from the American Chemical Society.
Oil sands operations contribute more to regional pollution than previously thought, a study has found. Credit: Donny Ash/Shutterstock.com .
Wildfires, cigarette smoking and vehicles all emit a potentially harmful compound called isocyanic acid. The substance has been linked to several health conditions, including heart disease and cataracts. Scientists investigating sources of the compound have now identified off-road diesel vehicles in oil sands production in Alberta, Canada, as a major contributor to regional levels of the pollutant. Their report appears in ACS’ journal Environmental Science & Technology.
Recent studies on isocyanic acid pollution in the air measure the compound as a direct emission from biomass burning and on-road gasoline and diesel vehicles. But laboratory experiments simulating atmospheric conditions have shown that the substance can also be formed from off-road diesel exhaust through chemical reactions that occur as it mixes with the air during the day. Based on these findings, analyses suggest that these secondary isocyanic acid emissions could be up to four fold larger than the direct emissions from diesel vehicles. This is particularly important in areas downwind of heavy off-road diesel use. John Liggio and colleagues wanted to see how closely the laboratory-based estimates of secondary isocyanic acid might mirror real-world conditions.
The researchers sampled the air above the Athabasca Oil Sands region of Alberta that is home to what is estimated to be the third largest oil reserve in the world. Off-road diesel vehicles transport nearly half of the oil recovered in the oil sands. The team also analyzed the air downwind of the industrial operations. Their results showed that off-road diesel vehicles released about 6 kilograms of isocyanic acid per hour, while the oxidation of the vehicles’ exhaust added another 116 to 186 kilograms of the compound per hour. Further field-based calculations suggest that these secondary emissions could be up to 20 times higher than the primary emissions. Computer modeling estimates that for the city of Fort McMurray, which is near the Athabasca operations, more than half of the isocyanic acid in the air comes from the oil sands. The average concentration of about 25 parts per trillion was well below the threshold level (1,000 parts per trillion) at which the substance is considered harmful. But emission plumes from the oil sands could increase the levels by an order of magnitude to 250 to 600 parts per trillion. The results highlight the need to better understand isocyanic acid sources and how they might impact human health, the researchers say.
This article has been republished from materials provided by the American Chemical Society. Note: material may have been edited for length and content. For further information, please contact the cited source.
Liggio J, Stroud CA, Wentzell JJB, Zhang J, Sommers J, Darlington A, Liu PSK, Moussa SG, Leithead A, Hayden K, Mittermeier RL, Staebler R, Wolde M, Li SM. Quantifying the Primary Emissions and Photochemical Formation of Isocyanic Acid Downwind of Oil Sands Operations. Environ Sci Technol. 2017 Dec 6. doi: 10.1021/acs.est.7b04346. [Epub ahead of print] PubMed PMID: 29210280.
Sweet Spot of Activity in Immune System Key to Fighting CancerNews
Scientists have shown how stimulating a specific location on the surface of immune cells can be targeted with antibodies to help in their fight against cancer.READ MORE
Molecules Brilliantly IlluminatedNews
Researchers want to use brilliant infrared light to study molecular disease markers in much greater detail. The team has developed a powerful femtosecond light source which emits at wavelengths between 1.6 and 10.2 micrometers. This instrument should make it possible to detect organic molecules present in extremely low concentrations in blood or aspirated air.
Liquid Cell Transmission Electron Microscopy Gives Nanoscale InsightsNews
Scientists and engineers dug into the mechanisms that degrade sample quality in liquid cell transmission electron microscopy (LC-TEM). They developed an LC-TEM device that uses multiple windows and patterned features to explore the impacts of high-energy electron bombardment on nanoparticles and sensitive biological samples.READ MORE