Yield sustainability of winter wheat under three limited-irrigation schemes based on a 28-year field experiment

Yanmei Gao; Meng Zhang; Zhimin Wang; Yinghua Zhang

doi:10.1016/j.cj.2022.04.006

AI Chat Paper

Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.

Chat more with AI

| Sign up

Browse by Subject

Search for peer-reviewed journals with full access.

Journals A - Z

About Us

Discover the SciOpen Platform and Achieve Your Research Goals with Ease.

About Us

Publish with Us

Support

Search articles, authors, keywords, DOl and etc.

Published Date

Reset Search

{{expandStatus?'Exit ':''}}Advanced Search

Journals A - Z

About Us

Publish with Us

Support

PDF (2.3 MB)

Cite

EndNote(RIS) BibTeX

Collect

Submit Manuscript

AI Chat Paper

Show Outline

Outline

Show full outline

Hide outline

Outline

Show full outline

Hide outline

Research Article | Open Access

Yield sustainability of winter wheat under three limited-irrigation schemes based on a 28-year field experiment

Yanmei Gao^{^b^,^c}, Meng Zhang^{^b}, Zhimin Wang^{^a}, Yinghua Zhang^{^a}(

)

College of Agronomy and Biotechnology, China Agricultural University, Beijing 100193, China

School of Life Science, Shanxi Normal University, Taiyuan 030031, Shanxi, China

Ministerial and Provincial Co-Innovation Centre for Endemic Crops Production with High-quality and Efficiency in Loess Plateau, Shanxi Agricultural University, Taigu 030801, Shanxi, China

Show Author Information

Abstract

Sustainable intensification is an agricultural development direction internationally. However, little is known about the yield sustainability of winter wheat (Triticum aestivum L.) under limited irrigation schemes on the North China Plain (NCP). A 28-year field experiment from 1991 to 2018 at Wuqiao Experimental Station was used to characterize long-term yield, evapotranspiration (ET), and water use efficiency (WUE) trends under three irrigation treatments (W1, irrigation just before sowing; W2, irrigation before sowing and at jointing stage; W3, irrigation before sowing, at jointing stage, and at anthesis). Yield gaps and the effects of genetic improvement, climate change, and climate variables on wheat yield and key phenological stages were estimated using the Agricultural Production Systems Simulator (APSIM) model. Grain yield and WUE of winter wheat increased during the 28 years under the three irrigation treatments, and the upward trend of WUE followed a saturation curve pattern. ET increased slightly. Simulation results showed that genetic improvement dramatically prolonged the phenological stages of vegetative growth period and contributed to yield increase by 0.03%–15.6%. The rapid increase in yield with lower water use was associated mainly with an increase in biomass with genetic improvement and partly with an increase in harvest index. A curvilinear relationship between WUE and yield emphasized the importance of obtaining high yields for high WUE. The yield gaps between potential yield and yield under W1 treatment increased from 1991 to 2018 but were relatively constant for the W2 and W3 treatments. Elevated atmospheric CO₂ concentration offset the negative effects of temperature increase on yield, leading to minor (−2.3% to 0.3%) changes in yield under climate change. Thus, genetic improvement played a dominant role in yield increase, and limited-irrigation schemes (W2 and W3) can increase wheat yield and promote sustainability of crop production on the NCP.

Keywords

Climate change Sustainability Yield Phenology Cultivars

References

[1]

W.L. Liang, P. Carberry, G.Y. Wang, R.H. Lyu, H.Z. Lyu, A.P. Xia, Quantifying the yield gap in wheat-maize cropping systems of the Hebei Plain, China, Field Crops Res. 124 (2011) 180-185.

Crossref Google Scholar

[2]

G. He, Z.L. Cui, H. Ying, H.F. Zheng, Z.H. Wang, F.S. Zhang, Managing the trade-offs among yield increase, water resources inputs and greenhouse gas emissions in irrigated wheat production systems, J. Clean. Prod. 164 (2017) 567-574.

Crossref Google Scholar

[3]

S.Z. Kang, X.M. Hao, T.S. Du, L. Tong, X.L. Su, H.N. Lu, X.L. Li, Z.L. Huo, S. Li, R.S. Ding, Improving agricultural water productivity to ensure food security in China under changing environment: from research to practice, Agric. Water Manage. 179 (2017) 5-17.

Crossref Google Scholar

[4]

C. Dalin, H. Qiu, N. Hanasaki, D.L. Mauzerall, I. Rodriguez-Iturbe, Balancing water resource conservation and food security in China, Proc. Natl. Acad. Sci. U. S. A. 112 (2015) 4588-4593.

Crossref Google Scholar

[5]

Z.M. Wang, P. Wang, X.H. Li, J.M. Li, L.Q. Lu, Principle and technology of water-saving, fertilizer-saving, high-yielding and simple cultivation in winter wheat, Rev. China Agric. Sci. Technol. 8 (2006) 38-44 (in Chinese with English abstract).

Google Scholar

[6]

F. Tao, M. Yokozawa, Y. Hayashi, E. Lin, 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 (2003) 251-261.

Crossref Google Scholar

[7]

Y.F. Shi, Y.S. Lou, Y.W. Zhang, Z.F. Xu, Quantitative contributions of climate change, new cultivars adoption, and management practices to yield and global warming potential in rice-winter wheat rotation ecosystems, Agric. Syst. 190 (2021) 103087.

Crossref Google Scholar

[8]

L.E. Drinkwater, S.S. Snapp, Nutrients in agroecosystems: rethinking the management paradigm, Adv. Agron. 92 (2007) 163-186.

Crossref Google Scholar

[9]

N.D. Mueller, J.S. Gerber, M. Johnston, D.K. Ray, N. Ramankutty, J.A. Foley, Closing yield gaps through nutrient and water management, Nature 490 (2012) 254.

Crossref Google Scholar

[10]

M.M. Martín, J.E. Olesen, J.R. Porter, A genotype, environment and management (GxExM) analysis of adaptation in winter wheat to climate change in Denmark, Agric. For. Meteorol. 187 (2014) 1-13.

Crossref Google Scholar

[11]

Z. Liu, X. Yang, K.G. Hubbard, X. Lin, Maize potential yields and yield gaps in the changing climate of northeast China, Glob. Change Biol. 18 (2012) 3441-3454.

Crossref Google Scholar

[12]

S. Lyu, X.G. Yang, X.M. Lin, Z.J. Liu, J. Zhao, K.N. Li, C.Y. Mu, X.C. Chen, F.J. Chen, G.H. Mi, Yield gap simulations using ten maize cultivars commonly planted in Northeast China during the past five decades, Agric. For. Meteorol. 205 (2015) 1-10.

Crossref Google Scholar

[13]

D.P. Xiao, F.L. Tao, Contributions of cultivars, management and climate change to winter wheat yield in the North China Plain in the past three decades, Eur. J. Agron. 52 (2014) 112-122.

Crossref Google Scholar

[14]

D.B. Lobell, J.I. Ortiz-Monasterio, G.P. Asner, P.A. Matson, R.L. Naylor, W.P. Falcon, Analysis of wheat yield and climatic trends in Mexico, Field Crops Res. 94 (2005) 250-256.

Crossref Google Scholar

[15]

Y. Zhou, Z.H. He, X.X. Sui, X.C. Xia, X.K. Zhang, G.S. Zhang, Genetic improvement of grain yield and associated traits in the Northern China winter wheat region from 1960 to 2000, Crop Sci. 47 (2007) 245-253.

Crossref Google Scholar

[16]

A.L. Olmstead, P.W. Rhode, Adapting north American wheat production to climatic challenges, 1839–2009, Proc. Natl. Acad. Sci. U. S. A. 108 (2011) 480-485.

Crossref Google Scholar

[17]

X.Y. Zhang, S.F. Wang, H.Y. Sun, S.Y. Chen, L.W. Shao, X.W. Liu, Contribution of cultivar, fertilizer and weather to yield variation of winter wheat over three decades: a case study in the North China Plain, Eur. J. Agron. 50 (2013) 52-59.

Crossref Google Scholar

[18]

Y. Liu, E.L. Wang, X.G. Yang, J. Wang, Contributions of climatic and crop varietal changes to crop production in the North China Plain, since 1980s, Glob. Change Biol. 16 (2010) 2287-2299.

Crossref Google Scholar

[19]

G. Rizzo, J.P. Monzon, F.A. Tenorio, R. Howard, K.G. Cassman, P. Grassini, Climate and agronomy, not genetics, underpin recent maize yield gains in favorable environments, Proc. Natl. Acad. Sci. U. S. A. 119 (2022) e2113629119.

Crossref Google Scholar

[20]

B.A. Keating, P.S. Carberry, G.L. Hammer, M.E. Probert, M.J. Robertson, D. Holzworth, N.I. Huth, J.N.G. Hargreaves, H. Meinke, Z. Hochman, G. McLean, K. Verburg, V. Snow, J.P. Dimes, M. Silburn, E. Wang, S. Brown, K.L. Bristow, S. Asseng, S. Chapman, R.L. McCown, D.M. Freebairn, C.J. Smith, An overview of APSIM, a model designed for farming systems simulation, Eur. J. Agron. 18 (2003) 267-288.

Crossref Google Scholar

[21]

Y.Q. Yu, Y. Huang, W. Zhang, Changes in rice yields in China since 1980 associated with cultivar improvement, climate and crop management, Field Crops Res. 136 (2012) 65-75.

Crossref Google Scholar

[22]

D.L. Giltrap, C. Li, S. Saggar, DNDC: a process-based model of greenhouse gas fluxes from agricultural soils, Agric. Ecosyst. Environ. 136 (2010) 292-300.

Crossref Google Scholar

[23]

Y. Huang, Y.Q. Yu, W. Zhang, W.J. Sun, S.L. Liu, J. Jiang, J.S. Wu, W.T. Yu, Y. Wang, Z.F. Yang, Agro-C: a biogeophysical model for simulating the carbon budget of agroecosystems, Agric. For. Meteorol. 149 (2009) 106-129.

Crossref Google Scholar

[24]

A.K. Ettinger, C.J. Chamberlain, I. Morales-Castilla, D.M. Buonaiuto, D.F.B. Flynn, T. Savas, J.A. Samaha, E.M. Wolkovich, Winter temperatures predominate in spring phenological responses to warming, Nat. Clim. Change 10 (2020) 1137-1142.

Crossref Google Scholar

[25]

Y.J. Liu, Q.M. Chen, Q.S. Ge, J.H. Dai, Y. Qin, L. Dai, X.T. Zou, J. Chen, Modelling the impacts of climate change and crop management on phenological trends of spring and winter wheat in China, Agric. For. Meteorol. 248 (2018) 518-526.

Crossref Google Scholar

[26]

F.L. Tao, L.L. Zhang, Z. Zhang, Y. Chen, Climate warming outweighed agricultural managements in affecting wheat phenology across China during 1981–2018, Agric. For. Meteorol. 316 (2022) 108865.

Crossref Google Scholar

[27]

S. Zhang, F.L. Tao, Z. Zhang, Rice reproductive growth duration increased despite of negative impacts of climate warming across China during 1981–2009, Eur. J. Agron. 54 (2014) 70-83.

Crossref Google Scholar

[28]

X.Y. Hu, Y. Huang, W.J. Sun, L.F. Yu, Shifts in cultivar and planting date have regulated rice growth duration under climate warming in China since the early 1980s, Agric. For. Meteorol. 247 (2017) 34-41.

Crossref Google Scholar

[29]

X.H. Wang, P. Ciais, L. Li, F. Ruget, N. Vuichard, N. Viovy, F. Zhou, J.F. Chang, X.C. Wu, H.F. Zhao, S.L. Piao, Management outweighs climate change on affecting length of rice growing period for early rice and single rice in China during 1991–2012, Agric. For. Meteorol. 233 (2017) 1-11.

Crossref Google Scholar

[30]

M. Tariq, S. Ahmad, S. Fahad, G. Abbas, S. Hussain, Z. Fatima, W. Nasim, M. Mubeen, M.H.U. Rehman, M.A. Khan, M. Adnan, C.J. Wilkerson, G. Hoogenboom, The impact of climate warming and crop management on phenology of sunflower-based cropping systems in Punjab, Pakistan, Agric. For. Meteorol. 256–257 (2018) 270-282.

Crossref Google Scholar

[31]

T. Ye, S. Zong, A. Kleidon, W. Yuan, Y. Wang, P. Shi, Impacts of climate warming, cultivar shifts, and phenological dates on rice growth period length in China after correction for seasonal shift effects, Clim. Change 155 (2019) 127-143.

Crossref Google Scholar

[32]

F.L. Tao, S. Zhang, Z. Zhang, Spatiotemporal changes of wheat phenology in China under the effects of temperature, day length and cultivar thermal characteristics, Eur. J. Agron. 43 (2012) 201-212.

Crossref Google Scholar

[33]

G. Abbas, S. Ahmad, A. Ahmad, W. Nasim, Z. Fatima, S. Hussain, M.H.U. Rehman, M.A. Khan, M. Hasanuzzaman, S. Fahad, K.J. Boote, G. Hoogenboom, Quantification the impacts of climate change and crop management on phenology of maize-based cropping system in Punjab, Pakistan, Agric. For. Meteorol. 247 (2017) 42-55.

Crossref Google Scholar

[34]

A. Tirol-Padre, J.K. Ladha, Integrating rice and wheat productivity trends using the SAS mixed-procedure and meta-analysis, Field Crops Res. 95 (2006) 75-88.

Crossref Google Scholar

[35]

H.G. Jones, Plants and Microclimate: a Quantitative Approach to Environmental Plant Physiology, Cambridge University Press, Cambridge, UK, 1992.

[36]

J.C. Zadoks, T.T. Chang, C.F. Konzak, A decimal code for the growth stages of cereals, Weed Res. 14 (1974) 415-421.

Crossref Google Scholar

[37]

A. Pask, J. Pietragalla, D.M. Mullan, M.P. Reynolds, Physiological Breeding Ⅱ: A Field Guide to Wheat Phenotyping, CIMMYT, Mexico, 2012.

[38]

M. Zhang, Y. Gao, Z. Zhang, Y. Liu, M. Han, N. Hu, Z. Wang, Z. Sun, Y. Zhang, Limited irrigation influence on rotation yield, water use, and wheat traits, Agron. J. 112 (2020) 241-256.

Crossref Google Scholar

[39]

X. Zhang, S. Chen, H. Sun, D. Pei, Y. Wang, Dry matter, harvest index, grain yield and water use efficiency as affected by water supply in winter wheat, Irrig. Sci. 27 (2008) 1-10.

Crossref Google Scholar

[40]

R.G. Allen, L.S. Pereira, D. Raes, S. Martin, Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements, FAO, Rome, Italy, 1998.

[41]

D.B. Lobell, W. Schlenker, J. Costa-Roberts, Climate trends and global crop production since 1980, Science 333 (2011) 616-620.

Crossref Google Scholar

[42]

D.K. Ray, J.S. Gerber, G.K. MacDonald, P.C. West, Climate variation explains a third of global crop yield variability, Nat. Commun. 6 (2015) 5989.

Crossref Google Scholar

[43]

C.J. Willmott, Some comments on the evaluation of model performance, Bull. Am. Meteorol. Soc. 63 (1982) 1309-1313.

Crossref Google Scholar

[44]

P. Steduto, T.C. Hsiao, E. Fereres, On the conservative behavior of biomass water productivity, Irrig. Sci. 25 (2007) 189-207.

Crossref Google Scholar

[45]

X. Zhang, S. Chen, H. Sun, Y. Wang, L. Shao, Water use efficiency and associated traits in winter wheat cultivars in the North China Plain, Agric. Water Manage. 97 (2010) 1117-1125.

Crossref Google Scholar

[46]

D. Tilman, K.G. Cassman, P.A. Matson, R. Naylor, S. Polasky, Agricultural sustainability and intensive production practices, Nature 418 (2002) 671-677.

Crossref Google Scholar

[47]

Crossref Google Scholar

[48]

M. Tollenaar, E.A. Lee, Yield potential, yield stability and stress tolerance in maize, Field Crops Res. 75 (2002) 161-169.

Crossref Google Scholar

[49]

L. Cattivelli, F. Rizza, F. Badeck, E. Mazzucotelli, A.M. Mastrangelo, E. Francia, C. Marè, A. Tondelli, A. Michele Stanca, Drought tolerance improvement in crop plants: An integrated view from breeding to genomics, Field Crops Res. 105 (2008) 1-14.

Crossref Google Scholar

[50]

M. Hlaváčová, K. Klem, B. Rapantová, K. Novotná, O. Urban, P. Hlavinka, P. Smutná, V. Horáková, P. Škarpa, E. Pohanková, M. Wimmerová, M. Orság, F. Jurečka, M. Trnka, Interactive effects of high temperature and drought stress during stem elongation, anthesis and early grain filling on the yield formation and photosynthesis of winter wheat, Field Crops Res. 221 (2018) 182-195.

Crossref Google Scholar

[51]

D.B. Lobell, M.J. Roberts, W. Schlenker, N. Braun, B.B. Little, R.M. Rejesus, G.L. Hammer, Greater sensitivity to drought accompanies maize yield increase in the U.S. Midwest, Science 344 (2014) 516-519.

Crossref Google Scholar

[52]

S.C. Zipper, J.X. Qiu, C.J. Kucharik, Drought effects on US maize and soybean production: spatiotemporal patterns and historical changes, Environ. Res. Lett. 11 (2016) 94021.

Crossref Google Scholar

[53]

G.Y. Leng, Evidence for a weakening strength of temperature-corn yield relation in the United States during 1980–2010, Sci. Total Environ. 605–606 (2017) 551-558.

Crossref Google Scholar

[54]

S. Siebert, H. Webber, G. Zhao, F. Ewert, Heat stress is overestimated in climate impact studies for irrigated agriculture, Environ. Res. Lett. 12 (2016) 54023.

Crossref Google Scholar

[55]

E.D. Coffel, C. Lesk, J.M. Winter, E.C. Osterberg, J.S. Mankin, Crop-climate feedbacks boost US maize and soy yields, Environ. Res. Lett. 17 (2022) 24012.

Crossref Google Scholar

[56]

N. Li, N. Yao, Y. Li, J.Q. Chen, D.L. Liu, A. Biswas, L.C. Li, T.X. Wang, X.G. Chen, A meta-analysis of the possible impact of climate change on global cotton yield based on crop simulation approaches, Agric. Syst. 193 (2021) 103221.

Crossref Google Scholar

[57]

J. Deryng, C. Elliott, C. Folberth, T.A. Müller, K.J. Pugh, D. Boote, A.C. Conway, D. Ruane, J.W. Gerten, Jones, Regional disparities in the beneficial effects of rising CO₂ concentrations on crop water productivity, Nat. Clim. Change 6 (2016) 786-790.

Crossref Google Scholar

[58]

E. Dias De Oliveira, J.A. Palta, H. Bramley, K. Stefanova, K.H. Siddique, Elevated CO₂ reduced floret death in wheat under warmer average temperatures and terminal drought, Front. Plant Sci. 6 (2015) 1010.

Crossref Google Scholar

The Crop Journal

Volume 10 Issue 6,
December 2022

Pages 1774-1783

DOI: 10.1016/j.cj.2022.04.006

Cite this article:

Gao Y, Zhang M, Wang Z, et al. Yield sustainability of winter wheat under three limited-irrigation schemes based on a 28-year field experiment. The Crop Journal, 2022, 10(6): 1774-1783. https://doi.org/10.1016/j.cj.2022.04.006

321

Views

Downloads

Crossref

Web of Science

Scopus

CSCD

Google Scholar
Citation

Altmetrics

Received: 29 December 2021

Revised: 09 April 2022

Accepted: 24 April 2022

Published: 16 May 2022

This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).