Abstract
In the North China Plain, the grain yield of irrigated wheat-maize cropping system has been steadily increasing in the past decades under a significant warming climate. This paper combined regional and field data with modeling to analyze the changes in the climate in the last 40 years, and to investigate the influence of changes in crop varieties and management options to crop yield. In particular, we examined the impact of a planned adaptation strategy to climate change -“Double-Delay” technology, i.e., delay both the sowing time of wheat and the harvesting time of maize, on both wheat and maize yield. The results show that improved crop varieties and management options not only compensated some negative impact of reduced crop growth period on crop yield due to the increase in temperature, they have contributed significantly to crop yield increase. The increase in temperature before over-wintering stage enabled late sowing of winter wheat and late harvesting of maize, leading to overall 4–6% increase in total grain yield of the wheat-maize system. Increased use of farming machines and minimum tillage technology also shortened the time for field preparation from harvest time of summer maize to sowing time of winter wheat, which facilitated the later harvest of summer maize.
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References
Carberry PS, Abrecht DG (1991) Tailoring crop models to the semi-arid tropics. In: Muchow RC, Bellamy JA (eds) Climatic risk in crop production: models and management in the semi-arid tropics and sub-tropics. Cab International, Wallingford, pp 157–182
Carberry PS, Muchow RC, McCown RL (1989) Testing the CERES-Maize simulation model in a semi-arid tropical environment. Field Crops Res 20:297–315
Che HZ, Shi GY, Zhang XY et al (2005) Analysis of 40 years of solar radiation data from China 1961–2000. Geophys Res Lett 32:1–5
Chen C (2008) Response of crop water productivity and water balance to climate variability/change in the North China Plain. PhD thesis, Graduate University of Chinese Academy of Sciences, Beijing, 170 pp
Chen L, Zhu W, Wang W et al (1998) Studies on climate change in China in recent 45 years. Acta Meteorol Sin 56:257–271
Chen C, Wang EL, Yu Q (2010a) Modelling the effects of climate variability and water management on crop water productivity and water balance in the North China Plain. Agric Water Manage 97:1175–1184
Chen C, Wang E, Yu Q et al (2010b) Quantifying the effects of climate trends in the past 43 years (1961–2003) on crop growth and water demand in the North China Plain. Clim Change 100:559–578
Egli DB, Bruening WP (2000) Potential of early-maturing soybean cultivars in late plantings. Agron J 92:532–537
Ellis EC, Wang SM (1997) Sustainable traditional agriculture in the Tai Lake of China. Agric Ecosys Env 61:177–193
Evans LT (1993) Crop evolution adaptation and yield. Cambridge University Press, Cambridge, p 500
Howden SM, Soussana JF, Tubillo FN et al (2007) Adapting agriculture to climate change. PNAS 104:19691–19696
Ju XT, Xing GX, Chen XP et al (2009) Reducing environmental risk by improving N management in intensive Chinese agricultural systems. PNAS 106:3041–3046
Kantolic AG, Mercau JL, Slafer GA et al (2007) Simulated yield advantages of extending post-flowering development at the expense of a shorter pre-flowering development in soybean. Field Crops Res 101:321–330
Keating BA, Godwin DC, Watiki JM (1991) Optimising nitrogen inputs in response to climatic risk. In: Muchow RC, Bellamy JA (eds) Climatic risk in crop production: Models and management in the semi-arid tropics and sub-tropics. Cab International, Wallingford, pp 329–358
Keating BA, Wafula BM, Watiki JM (1992) Development of a modelling capability for maize in semi-arid eastern Kenya. In: A search for strategies for sustainable dryland cropping in semi-arid eastern Kenya (eds Probert ME), pp 138, Proceedings of a Symposium held in Nairobi, kenya
Keating BA, Meinke H, Probert ME et al (2001) NWheat: documentation and performance of a wheat module for APSIM. Tropical Agriculture Technical Memorandum. Indooroopilly, Queensland
Keating BA, Carberry PS, Hammer GL et al (2003) An overview of APSIM, a model designed for farming systems simulation. Eur J Agron 18:267–288
Lin E (1996) Agricultural vulnerability and adaptation to global warming in China. Water Air Soil Pollut 92:63–73
Liu Y, Wang E, Yang X et al (2010) Contributions of climatic and crop varietal changes to crop production in the North China Plain, since 1980s. Global Change Biol 16:2287–2299
Luo Q, Bellotti W, Williams M et al (2009) Adaptation to climate change of wheat growing in South Australia: analysis of management and breeding strategies. Agric Ecosys Env 129:261–267
Meinke H, Hammer GL, Van Keulen H et al (1998) Improving wheat simulation capabilities in Australia from a cropping systems perspective III. The integrated wheat model (I-WHEAT). Eur J Agron 8:101–116
Monzon JP, Sadras VO, Abbate PA et al (2007) Modelling management strategies for wheat-soybean double crops in the south-eastern Pampas. Field Crops Res 101:44–52
National Bureau of Statistics of China (2008) China agriculture yearbook. Agricultural Publishing House, Beijing
Peng S, Huang J, Sheehy JE et al (2004) Rice yields decline with higher night temperature from global warming. PNAS 101:9971–9975
Probert ME, Dimes JP, Keating BA et al (1998) APSIM’s water and nitrogen modules and simulation of the dynamics of water and nitrogen in fallow system. Agric Syst 56:1–28
Sadras VO, Monzon JP (2006) Modelled wheat phenology captures rising temperature trends: shortened time to flowering and maturity in Australia and Argentina. Field Crops Res 93:136–146
Smit B, Cai Y (1996) Climate change and agriculture in China. Global Enviro Change 6:205–214
Sun H, Zhang X, Chen S et al (2007) Effects of harvest and sowing time on the performance of the rotation of winter wheat–summer maize in the North China Plain. Ind Crop Prod 25:239–247
Tao F, Zhang Z (2010) Adaptation of maize production to climate change in North China Plain: quantify the relative contributions of adaptation options. Eur J Agron 33:103–116
Tao F, Yokozawa M, Hayashi Y et al (2003) Changes in agricultural water demands and soil moisture in China over the last half-century and their effects on agricultural production. Agric For Meteorol 118:251–261
Tao F, Yokozawa M, Xu YL et al (2006) Climate changes and trends in phenology and yields of field crops in China, 1981–2000. Agric For Meteorol 138:82–92
Tao F, Yokozawa M, Liu J et al (2008) Climate-crop yield relationships at provincial scales in China and the impacts of recent climate trends. Clim Res 38:83–94
Wang Q, Halbrendt C, Johnson SR (1995) Grain production and environmental management in China’s fertilizer economy. J Environ Manage 47:283–296
Wang E, van Oosterom E, Meinke H et al (2003) The new APSIM-Wheat Model - performance and future improvements. In: Solutions for a better environment. Proceedings of the 11th Australian Agronomy Conference, Geelong, Victoria
Wang L, Zheng YF, Yu Q et al (2007) Applicability of agricultural production systems simulator (APSIM) in simulating the production and water use of wheat-maize continuous cropping system in North China Plain. Chin J Appl Ecol 18:2480–2486 (in Chinese)
Wang E, Yu Q, Wu D et al (2008) Climate, agricultural production and hydrological balance in the North China Plain. Int J Climatol 28:1959–1970
Wang H, Zhang M, Cai Y (2009a) Problems, challenges, and strategic options of grain security in China. Adv Agron 103:101–147
Wang J, Wang E, Luo Q et al (2009b) Modelling the sensitivity of wheat growth and water balance to climate change in southeast Australia. Clim Change 96:79–96
Wang J, Zhao T, Wang E et al (2010) Measurement and simulation of diurnal variations in water use efficiency and radiation use efficiency in an irrigated wheat-maize field in the North China Plain. NZJC&HS 38:119–135
Winter SR, Musick JT (1993) Wheat planting date effects on soil water extraction and grain yield. Agron J 85:912–916
Xiong W, Matthews R, Holman I et al (2007) Modelling China’s potential maize production at regional scale under climate change. Clim Change 85:433–451
Xu FA, Zhao BZ (2001) Development of crop yield and water use efficiency in Fengqiu in the NCP of China. Acta Pedologica Sin 38:491–497 (in Chinese)
Yang Y, Yu Q, Wang J (2004) Spatio-temporal variations of principal climatic factors in North China and part of East China within past 40 years. Resour Sci 26:45–50 (in Chinese)
Zhang F, Zhao M, Zhang B (2004) Problem in the development of conservation tillage in North of China. J Agric Sci Technology 6:36–39 (in Chinese)
Zhang XY, Chen SY, Liu MY et al (2005) Improved water use efficiency associated with cultivars and agronomic management in the North China Plain. Agron J 97:783–790
Zhang Q, Gao Q, Herbert SJ et al (2010) Influence of sowing date on phonological stages, seed growth and marketable yield of four vegetable soybean cultivars in North-eastern USA. Afr J Agric Res 5:2556–2562
Zhou Y, He ZH, Sui XX et al (2007) Genetic improvement of grain yield and associated traits in the northern China winter wheat region from 1960 to 2000. Crop Sci 47:245–253
Acknowledgements
We sincerely acknowledge the Special Fund for agriculture profession (201103003), National Basic Research Program of China (2009CB118608) and the National Natural Science Foundation of China (No. 41101046). This work is also supported by National Basic Research Program of China (2005CB121106) and the Innovative Group Grant of the National Science Foundation of China (30821003). The authors acknowledge the anonymous referees for their valuable comments.
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Wang, J., Wang, E., Yang, X. et al. Increased yield potential of wheat-maize cropping system in the North China Plain by climate change adaptation. Climatic Change 113, 825–840 (2012). https://doi.org/10.1007/s10584-011-0385-1
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DOI: https://doi.org/10.1007/s10584-011-0385-1