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ARS Home » Midwest Area » Urbana, Illinois » Global Change and Photosynthesis Research » Research » Publications at this Location » Publication #276303

Title: Ozone decreases soybean productivity and water use efficiency

item BETZELBERGER, A - University Of Illinois
item VANLOOCKE, A - University Of Illinois
item Bernacchi, Carl
item Ainsworth, Elizabeth - Lisa

Submitted to: American Geophysical Union
Publication Type: Abstract Only
Publication Acceptance Date: 12/2/2011
Publication Date: 12/5/2011
Citation: Betzelberger, A.M., Vanloocke, A.D., Bernacchi, C.J., Ainsworth, E.A. 2011. Ozone decreases soybean productivity and water use efficiency [abstract]. American Geophysical Union. PA33B-1822.

Interpretive Summary:

Technical Abstract: The combination of population growth and climate change will increase pressure on agricultural and water resources throughout this century. An additional consequence of this growth is an increase in anthropogenic emissions that lead to the formation of tropospheric ozone, which in concert with climate change, poses a significant threat to human health and nutrition. In addition to being an important greenhouse gas, O3 reduces plant productivity, an effect that has been particularly pronounced in soybean, which provides over half of the world’s oilseed production. Plant productivity is linked to feedbacks in the climate system, indirectly through the carbon cycle, as well as directly through the partitioning of radiation into heat and moisture fluxes. Soybean, along with maize, comprises the largest ecosystem in the contiguous U.S. Therefore, changes in productivity and water use under increasing O3 could impact human nutrition as well as the regional climate. Soybean response to increasing O3 concentrations was tested under open-air agricultural conditions at the SoyFACE research site. During the 2009 growing season, eight 20 m diameter FACE plots were exposed to different O3 concentrations, ranging from 40 to 200 ppb. Canopy growth (leaf area index) and physiological measurements of leaf photosynthesis and stomatal conductance were taken regularly throughout the growing season. Canopy fluxes of heat and moisture were measured using the residual energy balance micrometeorological technique. Our results indicate that as O3 increased over from 40 to 200 ppb, rates of photosynthesis and stomatal conductance decreased significantly, relative to the control. Further, the seed yield decreased by over 60%, while water use decreased by 30% and the water-use-efficiency (yield/water-use) declined by 50%. The growing season average canopy temperatures increased by 1°C and midday temperatures increased by 2°C compared to the control. Warmer and drier canopies may result in a positive feedback on O3 as temperature and humidity affect the production/destruction rate of O3. In order to broaden these experimental results, time series modeling is being used to evaluate the historical statistical relationship between soybean production and tropospheric O3 variations at the regional level. A multiple linear regression approach is being taken to understand the effects that O3 has had on soybean yields in Illinois, Iowa, and Indiana over the past 30 years. By combining county yield data with EPA and NASA O3 data, and controlling for variation in temperature and moisture, the O3-exposure relationship for the Midwestern U.S. will be determined. Together, these results indicate the critical need to understand the response of other crops to O3 and to put in place policies that mitigate the emissions of O3 precursors.