Abstract
The major wheat production region of China the North China Plain (NCP) is seriously affected by air pollution. In this study, yield of winter wheat (Triticum aestivum L.) was analyzed with respect to the potential impact of air pollution index under conditions of optimal crop management in the NCP from 2001 to 2012. Results showed that air pollution was especially serious at the early phase of winter wheat growth significantly influencing various weather factors. However, no significant correlations were found between final grain yield and the weather factors during the early growth phase. In contrast, significant correlations were found between grain yield and total solar radiation gap, sunshine hour gap, diurnal temperature range and relative humidity during the late growing phase. To disentangle the confounding effects of various weather factors, and test the isolated effect of air pollution induced changes in incoming global solar radiation on yield under ceteris paribus conditions, crop model based scenario-analysis was conducted. The simulation results of the calibrated Agricultural Production Systems Simulator (APSIM) model indicated that a reduction in radiation by 10% might cause a yield reduction by more than 10%. Increasing incident radiation by 10% would lead to yield increases of (only) 7%, with the effects being much stronger during the late growing phase compared to the early growing phase. However, there is evidence that APSIM overestimates the effect of air pollution induced changes on radiation, as it does not consider the changes in radiative properties of solar insulation, i.e. the relative increase of diffuse over direct radiation, which may partly alleviate the negative effects of reduced total radiation by air pollution. Concluding, the present study could not detect a significantly negative effect of air pollution on wheat yields in the NCP.
Highlights
Incoming solar radiation, the driver of plant photosynthesis, has continuously declined on the world’s land surface over the last decades [1]
Air pollution significantly reduced radiation, i.e. increased the radiation gap, at early phase represented by all four radiation related variables (GSR, photosynthetic active radiation (PAR), ultraviolet radiation (UVR), sunshine hours (SH))
The contrary observations for early and late phase are a result of the difference in the angle of the sun during the two Weather factors GSRgap PAR gap ultra-violet radiation gap (UVRgap) sunshine hour gap (SHgap) TMAX TMIN DTR relative humidity (RH)
Summary
The driver of plant photosynthesis, has continuously declined on the world’s land surface over the last decades [1] This phenomenon is known as total dimming and is driven mainly by changes in cloud cover and aerosols [2, 3]. A global hotspot of air pollution are the densely populated coastal regions of China, which experience high levels of air pollution resulting from gas or dust emissions from transport, fossil-fuel power generation and construction activities [7, 8]. These densely populated regions are at the same time the major crop production regions of China. Wheat is globally the third largest crop and an essential contributor to food security in China and the world [10]
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