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Space-based detection of missing sulfur dioxide sources of global air pollution

McLinden, C. A., V. E. Fioletov, M. W. Shephard, N. Krotkov, and C. Li (2016), Space-based detection of missing sulfur dioxide sources of global air pollution, Nature Geoscience, 9, 496, doi:10.1038/NGEO2724.

Randall V. Martin4,5, Michael D. Moran1 and Joanna Joiner2 Sulfur dioxide is designated a criteria air contaminant (or equivalent) by virtually all developed nations. When released into the atmosphere, sulfur dioxide forms sulfuric acid and fine particulate matter, secondary pollutants1 that have significant adverse effects on human health2–5 , the environment1 and the economy5 . The conventional, bottom-up emissions inventories used to assess impacts, however, are often incomplete or outdated, particularly for developing nations that lack comprehensive emission reporting requirements and infrastructure. Here we present a satellite-based, global emission inventory for SO2 that is derived through a simultaneous detection, mapping and emission-quantifying procedure, and thereby independent of conventional information sources. We find that of the 500 or so large sources in our inventory, nearly 40 are not captured in leading conventional inventories. These missing sources are scattered throughout the developing world—over a third are clustered around the Persian Gulf—and add up to 7 to 14 Tg of SO2 yr−1 , or roughly 6–12% of the global anthropogenic source. Our estimates of national total emissions are generally in line with conventional numbers, but for some regions, and for SO2 emissions from volcanoes, discrepancies can be as large as a factor of three or more. We anticipate that our inventory will help eliminate gaps in bottom-up inventories, independent of geopolitical borders and source types.

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Atmospheric Composition Modeling and Analysis Program (ACMAP)
Aura- OMI