COLLEGE PARK, Md. – A new University of Maryland-led study finds that China’s sulfur dioxide emissions have fallen by 75 percent since 2007, while India’s emissions increased by 50 percent. The results suggest that India is becoming, if it is not already, the world’s top emitter of sulfur dioxide, an air pollutant that causes acid rain, haze and many health-related problems. It is produced predominantly when coal is burned to generate electricity.
“The rapid decrease of sulfur dioxide emissions in China far exceeds expectations and projections,” said Can Li, an associate research scientist in UMD’s Earth System Science Interdisciplinary Center and first author on the study. “This suggests that China is implementing sulfur dioxide controls beyond what climate modelers have taken into account.”
Two maps compare total annual sulfur dioxide amounts for India and China during 2005 (left) and 2016 based on Ozone Monitoring Instrument measurements. Purple depicts the highest concentrations while white depicts the lowest. Note the decrease in size of the purple region over northeastern China. Photo credit: Chris McLinden, Environment and Climate Change Canada.
The study was published in the journal Scientific Reports on November 9, 2017.
Coal typically contains up to 3 percent sulfur. Most of these two countries’ sulfur dioxide emissions come from coal-fired power plants and coal-burning factories. In particular, Beijing suffers from severe haze problems because of the many coal-burning factories and power plants located nearby and upwind.
Starting in the early 2000s, China began implementing policies such as fining polluters, setting emission reduction goals and lowering emissions limits. According to the results of the current study, these efforts are paying off.
“Sulfur dioxide levels in China declined dramatically even though coal usage increased by approximately 50 percent and electricity generation grew by over 100 percent,” explained Li, who is also a research associate at NASA’s Goddard Space Flight Center. “This suggests that much of the reduction is coming from controlling emissions.”
Despite China’s 75 percent drop in sulfur dioxide emissions, recent work by other scientists has shown that the country’s air quality remains poor and continues to cause significant health problems. This may be because sulfur dioxide contributes to only approximately 10 to 20 percent of the air particles that cause haze, according to Li.
By contrast, India’s sulfur dioxide emissions increased by 50 percent over the past decade. The country opened its largest coal-fired power plant in 2012 and has yet to implement emission controls like China.
“Right now, India’s increased sulfur dioxide emissions are not causing as many health or haze problems as they do in China because the largest emission sources are not in the most densely populated area of India,” Li said. “However, as demand for electricity grows in India, the impact may worsen.”
The research team – composed of scientists from UMD, NASA Goddard, the U.S. National Oceanic and Atmospheric Administration, Air Quality Research Division, Environment and Climate Change Canada, the U.S. Argonne National Laboratory and Michigan Technological University – generated an accurate profile of emissions over India and China by combining emissions data generated by two different methods.
First, the researchers collected estimated emission amounts from inventories of the number of factories, power plants, automobiles and other contributors to sulfur dioxide emissions. These inventories, while important data sources, are often incomplete, outdated or otherwise inaccurate in developing countries. They also cannot account for changing conditions or unforeseen policies.
The researchers’ second data source was the Ozone Monitoring Instrument (OMI) on NASA’s Aura satellite, which detects a variety of atmospheric pollutants including sulfur dioxide. While OMI can collect up-to-date information and spot emission sources missing from the inventories, it can only detect relatively large emission sources. In addition, clouds or other atmospheric conditions can interfere with its measurements.
To overcome these challenges, the UMD and NASA scientists collaborated with researchers from Environment and Climate Change Canada to develop better algorithms to quantify emissions based on OMI data. In addition, UMD Department of Atmospheric and Oceanic Science Professors Russell Dickerson and Zhanqing Li, co-authors of the paper, used a weather aircraft to measure the concentrations of sulfur dioxide and other air pollutants over one of the most polluted regions in China. By comparing these measurements with OMI data, the researchers verified the satellite measurements.
By combining the OMI and inventory data, the researchers generated a more accurate estimate than either data source alone. Previously published studies, which relied on inventory data and published policies, projected that China’s sulfur dioxide emissions would not fall to current levels until 2030 at the earliest.
“Those studies did not reflect the true situation on the ground,” said Li, who is also a member of the U.S. OMI Science Team. “Our study highlights the importance of using satellite measurements to study air quality, especially in regions where conditions may change rapidly and unexpectedly.”
Li hopes the current study’s results can be used to improve climate and atmospheric models by providing more accurate input data.
Other study co-authors from UMD include Department of Atmospheric and Oceanic Science Assistant Research Professor Hao He and Research Scientist Xinrong Ren. Ren is also a research scientist at the National Oceanic and Atmospheric Administration (NOAA). Russell Dickerson and Zhanqing Li have joint appointments in the Earth System Science Interdisciplinary Center.
This work was performed in collaboration with Argonne National Laboratory, Environment and Climate Change Canada, Michigan Technological University and NOAA.This study used data from OMI, which is a Dutch/Finnish contribution to the NASA Aura mission and managed by the Royal Meteorological Institute of the Netherlands and the Netherlands Space Agency.
This work was supported by the NASA Earth Science Division Aura Science Team (Award No. 80NSSC17K0240), the National Science Foundation (Award No. 1558259), NASA’s Earth Science New Investigator Program (Award No. NNX14AI02G) and the National Natural Science Foundation of China (Award No. 91544217). The content of this article does not necessarily reflect the views of the organizations.
*Source: University of Maryland