Global crop yield reductions due to surface ozone exposure: 2. Year 2030 potential crop production losses and economic damage under two scenarios of O3 pollution
Shiri Avnery, Denise L. Mauzerall, Junfeng Liu and Larry W. Horowitz
Abstract
We examine the potential global risk of increasing surface ozone (O3)
exposure to three key staple crops (soybean, maize, and wheat) in the
near future (year 2030) according to two trajectories of O3
pollution: the Intergovernmental Panel on Climate Change Special Report
on Emissions Scenarios (IPCC SRES) A2 and B1 storylines, which represent
upper- and lower-boundary projections, respectively, of most O3 precursor emissions in 2030. We use simulated hourly O3
concentrations from the Model for Ozone and Related Chemical Tracers
version 2.4 (MOZART-2), satellite-derived datasets of agricultural
production, and field-based concentration:response relationships to
calculate crop yield reductions resulting from O3 exposure.
We then calculate the associated crop production losses and their
economic value. We compare our results to the estimated impact of O3
on global agriculture in the year 2000, which we assessed in our
companion paper [Avnery et al., 2011]. In the A2 scenario we find global
year 2030 yield loss of wheat due to O3 exposure ranges from
5.4 to 26% (a further reduction in yield of +1.5–10% from year 2000
values), 15–19% for soybean (reduction of +0.9–11%), and 4.4–8.7% for
maize (reduction of +2.1–3.2%) depending on the metric used, with total
global agricultural losses worth $17–35 billion USD2000
annually (an increase of +$6–17 billion in losses from 2000). Under the
B1 scenario, we project less severe but still substantial reductions in
yields in 2030: 4.0–17% for wheat (a further decrease in yield of
+0.1–1.8% from 2000), 9.5–15% for soybean (decrease of +0.7–1.0%), and
2.5–6.0% for maize (decrease of + 0.3–0.5%), with total losses worth
$12–21 billion annually (an increase of +$1–3 billion in losses from
2000). Because our analysis uses crop data from the year 2000, which
likely underestimates agricultural production in 2030 due to the need to
feed a population increasing from approximately 6 to 8 billion people
between 2000 and 2030, our calculations of crop production and economic
losses are highly conservative. Our results suggest that O3
pollution poses a growing threat to global food security even under an
optimistic scenario of future ozone precursor emissions. Further efforts
to reduce surface O3 concentrations thus provide an
excellent opportunity to increase global grain yields without the
environmental degradation associated with additional fertilizer
application or land cultivation.
http://www.sciencedirect.com/science/article/pii/S1352231011000070
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