Authors: Zhan Fengmei Yao, Hui Li, Jiahua Zhang g

Abstract:

The Northeast China (NEC) was the most important agriculture areas and known as the Golden-Maize-Belt. Based on observed crop data and crop model, we design four simulating experiments and separate relative impacts and contribution under climate change, planting date shift, and varieties change as well change of varieties and planting date. Without planting date and varieties change, maize yields had no significant change trend at Hailun station located in the north of NEC, and presented significant decrease by 0.2 - 0.4 t/10a at two stations, which located in the middle and the south of NEC. With planting date change, yields showed a significant increase by 0.09 - 0.47 t/10a. With varieties change, maize yields had significant increase by 1.8~ 1.9 t/10a at Hailun and Huadian stations, but a non-significant and low increase by 0.2t /10a at Benxi located in the south of NEC. With change of varieties and planting date, yields presented a significant increasing by 0.53- 2.0 t/10a. Their contribution to yields was -25% ~ -55% for climate change, 15% ~ 35% for planting date change, and 20% ~110% for varieties change as well 30% ~135% for varieties with planting date shift. It found that change in varieties and planting date were highest yields and were responsible for significant increases in maize yields, varieties was secondly, and planting date was thirdly. It found that adaptation in varieties and planting date greatly improved maize yields, and increased yields annual variability. The increase of contribution with planting date and varieties change in 2000s was lower than in 1990s. Yields with the varieties change and yields with planting date and varieties change all showed a decreasing trend at Huadian and Benxi since 2002 or so. It indicated that maize yields increasing trend stagnated in the middle and south of NEC, and continued in the north of NEC.

Keywords: Climate change, maize yields, varieties, planting date, impacts.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1108366

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References:

[1] H.Q. Zhou, C.J. Wang, “Analysis on comprehensive capability of food production in Northeast area,” Journal Northeast Agriculture University, vol.4, pp. 5-8, 2006.
[2] X. L. Bai, S. X. Sun, G. H. Yang, M. Liu, Z.P. Zhang, “Effect of water stress on maize yield during different growing stages,” Journal Maize Science, vol.17, pp. 60–63, 2009.
[3] Y.H. Ding, G. Y. Ren, Z.C. Zhao, Y. Xu, Y. Luo, Q. P. Li, and J. Zhang, “Detection, causes and projection of climate change over China: an overview of recent progress,” Advance Atmospheric Science, vol.24, pp. 954–971, 2007.
[4] F. M. Yao, Y. L. Xu, E.D. Lin, M. Yokozawa, and J.H. Zhang, “Assessing the impacts of climate change on rice yields in the main rice areas of China,” Climatic Change, vol. 80, pp. 375-409,2007.
[5] H. Ju, M. Velde, E.D. Lin, W. Xiong, Y. E. Li, “The impacts of climate change on agricultural production systems in China,” Climatic Change, vol.120, pp.313–324, 2013.
[6] D. Xiao and F. L. Tao, “Contributions of cultivars, management and climate change to winter wheat yield in the North China Plain in the past three decades,” European Journal of Agronomy, vol. 52, pp. 112-122, 2014.
[7] C. Rosenzweig and F.N. Tubiello, “Adaption and mitigation stratagies in agriculture: an analysis of potential aynergies,” Mitigation and Adaptation Strategies for Global Change, 12, 855-873, 2007.
[8] X. Yang, E. Lin, S. Ma, H. Ju, L. Guo, W. Xiong, Y. Li, and Y. Xu Adaptation of agriculture to warming in Northeast China. Climatic Change, vol. 84, pp. 45-58, 2007.
[9] Z. Qian, L.Z. Zhang, E. Jochem, D. W. Wopke, W.Q. Zhang, L.S. Duan, “Maize yield and quality in response to plant density and application of a novel plant growth regulator, “ Field Crops Research, vol. 164, pp.82-89, 2014.
[10] M.S. Babel and E. Turyatunga, “Evaluation of climate change impacts and adaptation measures for maize cultivation in the western Uganda agro-ecological zone,” Theortical and Applied Climatology, DOI 10.1007/s00704-014-1097-z, 2014.
[11] A.J. Challinor, J. Watson, D.B. Lobell, S. M. Howden, D.R. Smith and N. Chhetri, “A meta-analysis of crop yield under climate change and adaptation,” Nature, vol.4, pp. 287-291, 2014.
[12] Y. Yu, Y. Huang, W. Zhang, “Changes in rice yields in China since 1980 associated with cultivar improvement, climate and crop management,” Field Crops Research, 136, 65-75, 2012.
[13] L. L. Liu, Y. Zhu, L. Tang, W. X. Cao, and E. L. Wang, “Impacts of climate changes, soil nutrients, variety types and management practices on rice yields in East China :A case study in the Taihu region,” Field crop research, vol.149, pp. 40-48, 2013.
[14] X. Zhang, S. Wang, H. Sun, S. Chen, L. Shao, and X. Liu, “Contribution of cultivar, fertilizer and weather to yield variation of winter wheat over three decades: A case study in the North China Plain,” European Journal of Agronomy, vol.50, pp.52–59, 2013.
[15] Y. Liu, E. L. Wang, X. G. Yang, and J. Wang, “Contributions of climatic and crop varietal changes to crop production in the North China Plain, since 1980s,” Global Change Biology, vol.16, pp. 2287–2299, 2010.
[16] C. A. Jones and J. R., CERES–Maize: a simulation model of maize growth and development, 1986, Texas A＆M University Press, College Station.
[17] W. Xiong, I. Holman, D. Conway , E. D. Lin , and Y.E. Li, “A crop model cross calibration for use in regional climate impacts studies,” Ecological Modelling, vol.213, pp. 365–380, 2008.
[18] Zhang, X. Yang, H. Wang, Y Li, and Q. Ye, “Climatic and technological ceilings for Chinese rice stagnation based on yield gaps and yield trend pattern analysis,” Global Change Biology, vol. 20, pp. 1289-1298, 2014.
[19] Z.J. Liu, X. G. Yang, K. G. Hubbard, and X. M. Lin, “ Maize potential yields and yield gaps in the changing climate of northeast China, Global Change Biology,” vol.18, pp. 3441–3454, 2012.