Abstract
Meeting the projected 50% increase in global grain demand by 2030 without further environmental degradation poses a major challenge for agricultural production. Because surface ozone (O3) has a significant negative impact on crop yields, one way to increase future production is to reduce O3-induced agricultural losses. We present two strategies whereby O3 damage to crops may be reduced. We first examine the potential benefits of an O3 mitigation strategy motivated by climate change goals: gradual emission reductions of methane (CH4), an important greenhouse gas and tropospheric O3 precursor that has not yet been targeted for O3 pollution abatement. Our second strategy focuses on adapting crops to O3 exposure by selecting cultivars with demonstrated O3 resistance. We find that the CH4 reductions considered would increase global production of soybean, maize, and wheat by 23–102 Mt in 2030 – the equivalent of a ∼2–8% increase in year 2000 production worth $3.5–15 billion worldwide (USD2000), increasing the cost effectiveness of this CH4 mitigation policy. Choosing crop varieties with O3 resistance (relative to median-sensitivity cultivars) could improve global agricultural production in 2030 by over 140 Mt, the equivalent of a 12% increase in 2000 production worth ∼$22 billion. Benefits are dominated by improvements for wheat in South Asia, where O3-induced crop losses would otherwise be severe. Combining the two strategies generates benefits that are less than fully additive, given the nature of O3 effects on crops. Our results demonstrate the significant potential to sustainably improve global agricultural production by decreasing O3-induced reductions in crop yields.
Highlights
From 2010 to 2030 the demand for grain is expected to increase globally by 50% (Food & Agriculture Organization of the United Nations, 2006; World Bank, 2007) due to an increase in global population of roughly 1.4 billion people (US Census Bureau, 2010), a shift to a more diverse, animal protein-rich diet associated with rising living standards, and the expansion of global biofuel production
Global average AOT40 and W126 over land, and crop production (CP)-weighted average AOT40 and W126, during crop growing seasons are listed in Table 1 for year 2005 and 2030 for the current legislation’ (CLE) and CH4-red scenarios
For all three crops, simulated global average landbased AOT40 is higher than the European standard for the protection of agriculture in 2005 (3 ppmh, which is associated with a 5% reduction in crop yields)
Summary
From 2010 to 2030 the demand for grain is expected to increase globally by 50% (Food & Agriculture Organization of the United Nations, 2006; World Bank, 2007) due to an increase in global population of roughly 1.4 billion people (US Census Bureau, 2010), a shift to a more diverse, animal protein-rich diet associated with rising living standards, and the expansion of global biofuel production. One way to improve agricultural production without negative environmental consequences is by reducing the damage – and associated yield reductions – caused by crop exposure to surface ozone (O3). O3 reductions via mitigation of conventional pollutant precursors (NOx, CO, and NMVOCs) would prevent significant additional future yield reductions (Van Dingenen et al, 2009; Avnery et al, 2011b), even with aggressive emission controls global year 2030 losses could remain substantial – for O3-sensitive crops (e.g., up to 17% globally for wheat with considerable regional variability) (Avnery et al, 2011b). It is worthwhile to explore supplemental strategies to reduce O3-induced crop losses beyond the targeting of traditional short-lived O3 precursors
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