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Warming affects water use, yield and crop quality of a potato–broad bean–winter wheat rotation system in semi-arid regions of China

Published online by Cambridge University Press:  01 December 2020

Xiao Guoju*
Affiliation:
Institute of Environmental Engineering, Ningxia Key Laboratory of Resource Assessment and Environment Regulation in Arid Region of China-Arab, Ningxia University, Yinchuan, Ningxia750021, China
Guo Zhanqiang
Affiliation:
Institute of Environmental Engineering, Ningxia Key Laboratory of Resource Assessment and Environment Regulation in Arid Region of China-Arab, Ningxia University, Yinchuan, Ningxia750021, China
Zhang Qiang*
Affiliation:
Institute of Arid Meteorology, China Meteorological Administration, Lanzhou, Gansu730020, China
Hu Yanbin
Affiliation:
Institute of Environmental Engineering, Ningxia Key Laboratory of Resource Assessment and Environment Regulation in Arid Region of China-Arab, Ningxia University, Yinchuan, Ningxia750021, China
Wang Jing
Affiliation:
Institute of Environmental Engineering, Ningxia Key Laboratory of Resource Assessment and Environment Regulation in Arid Region of China-Arab, Ningxia University, Yinchuan, Ningxia750021, China
Cao Jin
Affiliation:
Station of Gardening Technology, Ningxia, Yinchuan750002, China
Qiu Zhengji
Affiliation:
Center of Agricultural technology promotion, Longde, Ningxia756302, China
*
Author for correspondence: Xiao Guoju, E-mail: [email protected]; Zhang Qiang, E-mail: [email protected]
Author for correspondence: Xiao Guoju, E-mail: [email protected]; Zhang Qiang, E-mail: [email protected]

Abstract

Global warming will directly influence agricultural production and present new challenges for food security in semiarid regions of China. A warming experiment was conducted in Guyuan, China using infrared ray radiators to study the impact of warming on crop growth, yield and quality of a potato–broad bean–winter wheat crop rotation system. Warming significantly affected the crop photosynthesis rates of the potato–broad bean–winter wheat rotation system. In the podding stage of broad bean and the heading, blooming and booting stages of winter wheat, the photosynthesis rate was significantly decreased when the temperature increased by 0.5–2.0°C. The growing period of the potato–broad bean–winter wheat rotation system was shortened by 20–40 days per 3-year-period, and the fallow period was prolonged by 4–13 days per 3-year-period. The water use efficiency of the potato–broad bean–winter wheat rotation decreased by 8.6% when the temperature increased by 1.02.0°C. The yield of the potato–broad bean–winter wheat rotation increased by 6.1–7.7% when the temperature increased by 0.5–1.0°C. However, yield decreased 12.9–13.4% when temperature increased by 1.0–2.0°C. Potato protein significantly decreased by 9.3–17.6% and the winter wheat fat significantly decreased by 6.7% when the temperature increased by 0.5–2.0°C. The results indicate that global warming could seriously affect the crop growth, yield and water use of the potato–broad bean–winter wheat rotation in semiarid regions of China.

Type
Climate Change and Agriculture Research Paper
Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press

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References

Chen, C, Zhou, GS and Pang, YM (2015) Impacts of climate change on maize and winter wheat yields in China from 1961 to 2010 based on provincial data. Journal of Agricultural Science 153, 825836.CrossRefGoogle Scholar
Chen, S, Liua, SW, Zheng, X, Yin, M, Chu, G, Xu, CM, Yan, JX, Chen, LP, Wang, DY and Zhang, XF (2018) Effect of various crop rotations on rice yield and nitrogen use efficiency in paddy–upland systems in southeastern China. The Crop Journal 6, 576588.CrossRefGoogle Scholar
Deng, ZY, Zhang, Q, Pu, JY, Liu, DX, Guo, H, Wang, QF, Zhao, H and Wang, HL (2008) Impact of warming on cropping in Northwest China. Acta Ecologica Sinica 28, 37603768.Google Scholar
Gao, L and Zhang, YN (2016) Spatio-temporal variation of hydrological drought under climate change during the period 1960–2013 in the Hexi Corridor, China. Journal of Arid Land 8, 157171.CrossRefGoogle Scholar
Kimball, BA (2005) Theory and performance of an infrared heater for ecosystem warming. Global Change Biology 11, 20412056.Google Scholar
Kimball, BA (2015) Using canopy resistance for infrared heater control when warming open-field plots. Agronomy Journal 107, 11051112.CrossRefGoogle Scholar
Kimball, BA, Conley, MM, Wang, SP, Lin, XW, Luo, CY, Organ, J and Avidsmit, HD (2008) Infrared heater arrays for warming ecosystem fifield plots. Global Change Biology 14, 309320.CrossRefGoogle Scholar
Lei, YD, Zhang, HL, Chen, F and Zhang, LB (2016) How rural land use management facilitates drought risk adaptation in a changing climate – A case study in arid northern China. Science of the Total Environment 550, 192199.CrossRefGoogle Scholar
Li, FM, Song, QH, Liu, HS, Li, FR and Liu, XL (2001) Effects of pro-sowing irrigation and phosphorus application on water use and yield of spring wheat under semiarid conditions, Agric. Water Manage 49, 173183.CrossRefGoogle Scholar
Li, XM, Ni, SL and Wang, LM (2013) Discussion on the correlation between rainfall change and winter wheat yield and growth in the dry area of longdong. Agricultural Research in the Arid Areas 31, 2831.Google Scholar
Ogaya, R and Peuelas, J (2003) Comparative field study of quercusilex and phillyrealatifolia: photosynthetic response to experimental drought conditions. Environmental and Experimental Botany 50, 137148.CrossRefGoogle Scholar
Picotte, JJ, Rosenthal, DM, Rhode, JM and Cruzan, MB (2007) Plastic responses to temporal variation in moisture availability: consequences for water use efficiency and plant performance. Oecologia 153, 821832.CrossRefGoogle ScholarPubMed
Ponce, C, Guillermo, E, Moran, M, Susan, HA, Zhang, YG, Bresloff, C, Huxman, TE, Eamus, D, Bosch, DD, Buda, AR, Gunter, SA, Scalley, TH, Kitchen, SG, McClaran, MP, McNab, WH, Montoya, DS, Morgan Jack, A, Peters, DC, Sadler, EJ, Seyfried, MS and Starks, PJ (2013) Ecosystem resilience despite large-scale altered hydroclimatic condition. Nature 470, 14.Google Scholar
Shen, YP and Wang, GY (2013) The most updated scientific key points about global climate change in 5th evaluation report by 1st Work Team of IPCC. Journal of Glaciology and Geocryology 35, 10681076.Google Scholar
Tenhunen, J, Roupsard, O and Rambal, S (2002) Severe drought effects on ecosystem CO2 and H2O fluxes at three Mediterranean evergreen sites: revision of current hypotheses. Global Change Biology 8, 9991017.Google Scholar
Tian, YL, Zheng, JC, Zhang, B, Chen, J, Dong, WJ, Yang, F and Zhang, WJ (2010) Design and effect of an open day-night varying warming system on wheat farm. Scientia Agricultura Sinica 43, 37243731.Google Scholar
Wang, QW, Yu, DP, Dai, LM, Zhou, L, Zhou, WM, Qi, G, Qi, L and Ye, YJ (2010) Progress of the research on the plant moisture utilization rate in global climate change. Chinese Journal of Applied Ecology 21, 32553265.Google Scholar
Xiao, GJ, Zhang, Q, Xiong, YC, Yang, XG and Yang, QG (2007) Effects of temperature increase on water use and total yields of crops in a pea–spring wheat–potato rotation system in semiarid regions of China. Agricultural Water Management 91, 8691.CrossRefGoogle Scholar
Xiao, GJ, Zheng, FJ, Qiu, ZJ and Yao, YB (2013) Impact of climate change on water use efficiency by wheat, potato and corn in semiarid areas of China. Agriculture, Ecosystems & Environment 181, 108114.CrossRefGoogle Scholar
Xiao, GJ, Zhang, FJ, Huang, JY, Luo, CK, Wang, JG, Ma, F, Yao, YB, Wang, RY and Qiu, ZJ (2016) Response of bean cultures’ water use efficiency against climate warming in semiarid regions of China. Agricultural Water Management 173, 8490.Google Scholar
Yang, XG, Chen, F, Lin, XM, Liu, ZJ, Zhang, HL, Zhao, J, Li, KN, Ye, Q, Li, Y and Lv, S (2015) Potential benefits of climate change for crop productivity in China. Agricultural and Forest Meteorology 208, 7684.CrossRefGoogle Scholar
Yao, YB, Zhang, XY, Lu, HW, Han, HH, Li, XX and Zhang, SW (2009) Impact of meteorological conditions on the formation and yield of potato tuber in warm, cool and semi-wet regions in Northwest China. Chinese Journal of Agrometeorology 30, 208211.Google Scholar
Yao, YB, Wang, RY, Deng, ZY, Han, SL and Xing, TQ (2010) Climate change in semiarid regions in loess plateau and its impact on potato growth. Chinese Journal of Applied Ecology 21, 287295.Google Scholar
Ye, JB, Xiao, ZL, Wang, FS, Liao, JC, Fu, JZ and Zhang, ZB (2015) Past climate change and recent anthropogenic activities affect genetic structure and population demography of the greater long-tailed hamster in northern China. Integrative Zoology 10, 482496.CrossRefGoogle ScholarPubMed
Zhang, Q, Zhang, CJ, Bai, HZ, Li, L, Sun, LD, Liu, DX, Wang, JS and Zhao, HY (2010) New trends of climate change in Northwest China and the impact on drought. Arid Meteorology 28, 17.Google Scholar
Zhang, HL, Zhao, X, Yin, XG, Liu, SL, Xue, JF, Wang, M, Pu, C, Lal, R and Chen, F (2015) Challenges and adaptations of farming to climate change in the North China Plain. Climate Change 129, 213224.CrossRefGoogle Scholar
Zhang, LX, Zhu, LL, Yu, MY and Zhong, MX (2016) Warming decreases photosynthates and yield of soybean in the North China Plain. The Crop Journal 4, 139146.CrossRefGoogle Scholar
Zhao, FH and Yu, GR (2008) A review on the coupled carbon and water cycles in the terrestrial ecosystems. Progress in Geography 27, 3238.Google Scholar
Zheng, GQ (2010) Thinking on new situation and tasks of addressing climate change for China after Copenhagen Climate Change Conference 2009. Advances in Climate Change Research 6, 7982.Google Scholar
Zheng, CG, Jiang, Y, Chen, CQ, Sun, YN, Feng, JF, Deng, AX, Song, ZW and Zhang, WJ (2014) The impacts of conservation agriculture on crop yield in China depend on specific practices, crops and cropping regions. The Crop Journal 2, 289296.CrossRefGoogle Scholar