Cultivar selection can increase yield potential and resource use efficiency of spring maize to adapt to climate change in Northeast China

doi:10.1016/S2095-3119(20)63359-7

Journal of Integrative Agriculture

2021, Vol. 20

Issue (2): 371-382 DOI: 10.1016/S2095-3119(20)63359-7

Section 1: Using modeling method to evaluate yield and efficiency gaps

Advanced Online Publication | Current Issue | Archive | Adv Search

Cultivar selection can increase yield potential and resource use efficiency of spring maize to adapt to climate change in Northeast China

SU Zheng-e¹, LIU Zhi-juan¹, BAI Fan¹, ZHANG Zhen-tao¹, SUN Shuang^{1, 2}, HUANG Qiu-wan¹, LIU Tao¹, LIU Xiao-qing¹, YANG Xiao-guang¹

¹ College of Resources and Environmental Sciences, China Agricultural University, Beijing 100193, P.R.China
² Chinese Academy of Meteorological Sciences, Beijing 100081, P.R.China

Abstract
References

Download: PDF in ScienceDirect
Export: BibTeX | EndNote (RIS)

Abstract Northeast China (NEC) is one of the major maize production areas in China. Agro-climatic resources have obviously changed, which will seriously affect crop growth and development in this region. It is important to investigate the contribution of climate change adaptation measures to the yield and resource use efficiency to improve our understanding of how we can effectively ensure high yield and high efficiency in the future. In this study, we divided the study area into five accumulated temperature zones (ATZs) based on growing degree days (GDD). Based on the meteorological data, maize data (from agro-meteorological stations) and the validated APSIM-Maize Model, we first investigated the spatial distributions and temporal trends of maize potential yield of actual planted cultivars, and revealed the radiation use efficiency (RUE) and heat resource use efficiency (HUE) from 1981 to 2017. Then according to the potential growing seasons and actual growing seasons, we identified the utilization percentages of radiation (P_R) resource and heat resource (P_H) for each ATZ under potential production from 1981 to 2017. Finally, we quantified the contributions of cultivar changings to yield, P_R and P_Hof maize. The results showed that during the past 37 years, the estimated mean potential yield of actual planted cultivars was 13 649 kg ha^–1, ranged from 11 205 to 15 257 kg ha^–1, and increased by 140 kg ha^–1 per decade. For potential production, the mean values of RUE and HUE for the actual planted maize cultivars were 1.22 g MJ^–1 and 8.58 kg (°C d)^–1 ha^–1. RUE showed an increasing tendency, while HUE showed a decreasing tendency. The lengths of the potential growing season and actual growing season were 158 and 123 d, and increased by 2 and 1 d per decade. P_R and P_H under potential production were 82 and 86%, respectively and showed a decreasing tendency during the past 37 years. This indicates that actual planted cultivars failed to make full use of climate resources. However, results from the adaptation assessments indicate that, adoption of cultivars with growing season increased by 2–11 d among ATZs caused increase in yield, P_R and P_H of 0.6–1.7%, 1.1–7.6% and 1.5–8.9%, respectively. Therefore, introduction of cultivars with longer growing season can effectively increase the radiation and heat utilization percentages and potential yield.

Keywords: APSIM maize potential yield radiation use efficiency resource utilization percentage cultivar selection

Received: 30 March 2020 Accepted:

Fund: This work was supported by the National Key Research and Development Program of China (2016YFD0300101-03).

Corresponding Authors: LIU Zhi-juan, Tel: +86-10-62731737, E-mail: zhijuanliu@cau.edu.cn

About author: SU Zheng-e, E-mail: suzhenge_cau@163.com

	Service
	E-mail this article
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	SU Zheng-e
	LIU Zhi-juan
	BAI Fan
	ZHANG Zhen-tao
	SUN Shuang
	HUANG Qiu-wan
	LIU Tao
	LIU Xiao-qing
	YANG Xiao-guang

Cite this article:

SU Zheng-e, LIU Zhi-juan, BAI Fan, ZHANG Zhen-tao, SUN Shuang, HUANG Qiu-wan, LIU Tao, LIU Xiao-qing, YANG Xiao-guang. 2021. Cultivar selection can increase yield potential and resource use efficiency of spring maize to adapt to climate change in Northeast China. Journal of Integrative Agriculture, 20(2): 371-382.

Allen R G, Pereira L S, Raes D, Smith M. 1998. Crop evapotranspiration - Guidelines for computing crop water requirements - FAO irrigation and drainage paper 56. Food and Agriculture Organization of the United Nations, Rome. Chen C Q, Qian C R, Deng A X, Zhang W J. 2012. Progressive and active adaptations of cropping system to climate change in Northeast China. European Journal of Agronomy, 38, 94–103. Chen Q, Geng T, Hou W J, Chen C Q. 2014. Impacts of climate warming on growth and yield of spring maize in recent 20 years in Northeast China. Scientia Agricultura Sinica, 47, 1904–1916. (in Chinese) Chen X C, Chen F J, Chen Y L, Gao Q, Yang X L, Yuan L X, Zhang F S, Mi G H. 2013. Modern maize hybrids in Northeast China exhibit increased yield potential and resource use efficiency despite adverse climate change. Global Change Biology, 19, 923–936. Cui D C. 2001. Climatic resources utilization co-efficiency of cereal crops in China and development measures. Agricultural Meteorology, 26–33. (in Chinese) Guo J P, Zhao J F, Xu Y H, Chu Z, Mu J, Zhao Q. 2015. Effects of adjusting cropping systems on utilization efficiency of climatic resources in Northeast China under future climate scenarios. Physics and Chemistry of the Earth, 87–88, 87–96. Guo J P, Zhao J F, Yuan B, Ye M Z. 2013. Evaluation of agricultural climatic resource utilization during spring maize cultivation in Northeast China under climate change. Acta Meteorologica Sinica, 27, 758–768. (in Chinese) He Y K, Guo J P. 2011. Characteristics of agricultural climate resources in the three provinces of Northeast China from 1961 to 2006. Journal of Natural Resources, 26, 1199–1208. (in Chinese) Keating B A, Carberry P S, Hammer G L, Probert M E, Robertson M J, Holzworth D, Huth N I, Hargreaves J N G, Meinke H, Hochman Z, McLean G, Verburg K, Snow V, Dimes J P, Silburn M, Wang E, Brown S, Bristow K L, Asseng S, Chapman S, et al. 2003. An overview of APSIM, a model designed for farming systems simulation. European Journal of Agronomy, 18, 267–288. Li J L. 2009. Study on northeastern agricultural multifunctionality and regional development strategy. Ph D thesis, Chinese Academy of Agricultural Sciences, China. (in Chinese) Li S K, Wang K R, Xie R Z, Ming B. 2018. Grain mechanical harvesting technology promotes the transformation of maize production mode. Scientia Agricultura Sinica, 51, 1842–1844. (in Chinese) Li Z G, Tan J Y, Tang P Q, Chen H, Zhang L, Liu H, Wu W B, Tang H J, Yang P, Liu Z H. 2016. Spatial distribution of maize in response to climate change in Northeast China during 1980–2010. Journal of Geographical Sciences, 26, 3–14. Liu Y E, Hou P, Xie R Z, Hao W P, Li S K, Mei X R. 2015. Spatial variation and improving measures of the utilization efficiency of accumulated temperature. Crop Science, 55, 1806–1817. Liu Z J, Hubbard K G, Lin X M, Yang X G. 2013. Negative effects of climate warming on maize yield are reversed by the changing of sowing date and cultivar selection in Northeast China. Global Change Biology, 19, 3481–3492. Liu Z J, Yang X G, Hubbard K G, Lin X M. 2012. Maize potential yields and yield gaps in the changing climate of Northeast China. Global Change Biology, 18, 3441–3454. Liu Z J, Yang X G, Lin X M, Hubbard K G, Lv S, Wang J. 2016. Maize yield gaps caused by non-controllable, agronomic, and socioeconomic factors in a changing climate of Northeast China. Science of the Total Environment, 541, 756–764. Liu Z J, Yang X G, Lv S, Wang J, Lin X M. 2018. Spatial-temporal variations of spring maize potential yields in a changing climate in Northeast China. Chinese Journal of Applied Ecology, 29, 103–112. (in Chinese) Lv S. 2016. Analysis of impacts of climate change on spring maize and adaptation in maize cultivars in Lishu Jilin. Ph D thesis, China Agricultural University, China. (in Chinese) Lv S, Yang X G, Zhao J, Liu Z J, Li K N, Mu C Y, Chen X C, Chen F J, Mi G H. 2013. Effects of climate change and variety alternative on potential yield of spring maize in Northeast China. Transactions of the Chinese Society of Agricultural Engineering, 29, 179–190. (in Chinese) Ma Y L, Guo J P. 2018. Evaluation of climatic resource utilization during spring maize in Northeast China in recent 36 years. Meteorological and Environmental Sciences, 41, 1–10. (in Chinese) Monteith J L. 1972. Solar radiation and productivity in tropical ecosystems. Journal of Applied Ecology, 9, 747–766. NBSC (National Bureau of Statistics of China). 2017. China Statistics Yearbook. China Statistics Press, Beijing. (in Chinese) NBSC (National Bureau of Statistics of China). 2020. China Statistics Yearbook. China Statistics Press, Beijing. (in Chinese) Ning X J, Qin Y C, Cui Y P, Li X, Chen Y M. 2015. The spatio-temporal change of agricultural hydrothermal conditions in China from 1951 to 2010. Acta Geographica Sinica, 70, 364–379. (in Chinese) Ramankutty N, Foley J A, Norman J, McSweeney K. 2002. The global distribution of cultivable lands: Current patterns and sensitivity to possible climate change. Global Ecology and Biogeography, 11, 377–392. Sinclair T R, Horie T. 1989. Leaf nitrogen, photosynthesis, and crop radiation use efficiency: A review. Crop Science, 29, 90. Wang P J, Han L J, Zhou G S, Liang H. 2015. The effects of climate warming on different cultivars of spring maize under climate warming in Northeast China and the adaptation countermeasures. Journal of Natural Resources, 30, 1343–1355. (in Chinese) Wang X Y, Yang X G, Sun S, Xie W J. 2015. Comparison of potential yield and resource utilization efficiency of main food crops in three provinces of Northeast China under climate change. Chinese Journal of Applied Ecology, 26, 3091–3102. (in Chinese) Wilson D R, Muchow R C, Murgatroyd C J. 1995. Model analysis of temperature and solar radiation limitations to maize potential productivity in a cool climate. Field Crops Research, 43, 1–18. Xu Y H. 2014. Evaluation on the effect of adaptation countermeasures of maize on climate resources utilization in Northeast China under climate change. MSc thesis, Chinese Academy of Meteorological Sciences. (in Chinese) Yang X G, Li Y, Di S W, Liu Z J, Wang W F. 2011. Changes of China agricultural climate resources under the background of climate change: IX. Spatiotemporal change characteristics of China agricultural climate resources. Chinese Journal of Applied Ecology, 22, 3177–3188. (in Chinese) Yin X G, Olesen J E, Wang M, Öztürk I, Zhang H L, Chen F. 2016. Impacts and adaptation of the cropping systems to climate change in the Northeast Farming Region of China. European Journal of Agronomy, 78, 60–72. Yuan B. 2012. Climatic potential productivity and climate resources utilization rate of spring maize in Northeast China under climate change. MSc thesis, Chinese Academy of Meteorological Sciences. (in Chinese) Zhao F, Wang R, Zhao H Y, Li X F, Lin W N, Tian B X. 2019. Evolution characteristics of potential heat utilization efficiency in maize production in cold region. Journal of Maize Sciences, 27, 73–81. (in Chinese) Zhao J. 2015. Analysis of impacts of climate change on spring maize and adaptation in maize cultivars in Lishu, Jilin. Ph D thesis, China Agricultural University, China. (in Chinese) Zhao J, Yang X G, Dai S W, Lv S, Wang J. 2015. Increased utilization of lengthening growing season and warming temperatures by adjusting sowing dates and cultivar selection for spring maize in Northeast China. European Journal of Agronomy, 67, 12–19. Zhao J F, Guo J P, Mu J. 2015a. Exploring the relationships between climatic variables and climate-induced yield of spring maize in Northeast China. Agriculture, Ecosystems and Environment, 207, 79–90. Zhao J F, Guo J P, Xu Y H, Mu J. 2015b. Effects of climate change on cultivation patterns of spring maize and its climatic suitability in Northeast China. Agriculture, Ecosystems and Environment, 202, 178–187. Zhao J F, Mu J, Guo J P. 2015c. Response of agricultural thermal resources equal to and more than 10°C to climate change over the past 50 years in Northeast China. Journal of Natural Disasters, 24, 190–198. (in Chinese) Zheng C, Guo J P, Zhao J F. 2017. Impacts of future climate change on agroclimatic resources in Northeast China. Journal of Geographical Sciences, 27, 1044–1058.

[1]	Teng Li, Shumei Wang, Qing Liu, Xuepeng Zhang, Lin Chen, Yuanquan Chen, Wangsheng Gao, Peng Sui. Effects of changing assimilate supply on starch synthesis in maize kernels under high temperature stress[J]. >Journal of Integrative Agriculture, 2026, 25(2): 639-647.
[2]	Xiaohui Xu, Qiang Chai, Falong Hu, Wen Yin, Zhilong Fan, Hanting Li, Zhipeng Liu, Qiming Wang. Intercropping grain crops with green manure under reduced chemical nitrogen improves the soil carbon stocks by optimizing aggregates in an oasis irrigation area[J]. >Journal of Integrative Agriculture, 2026, 25(1): 326-338.
[3]	Qinghao Wang, Juan Hu, Weizhen Yu, Limin Gu, Peng Liu, Bin Zhao, Wenchao Zhen, Jiwang Zhang, Baizhao Ren. Shading and waterlogging interactions exacerbate summer maize yield losses by reducing assimilate accumulation and remobilization processes[J]. >Journal of Integrative Agriculture, 2026, 25(1): 92-104.
[4]	Ziwen Shi, Sheng Zhang, Qing He, Xiaoyuan Wang, Bo yang, Tao Yu, Hongyang Yi, Tingzhao Rong, Moju Cao. ZmCals12 impacts maize growth and development by regulating symplastic transport[J]. >Journal of Integrative Agriculture, 2026, 25(1): 42-55.
[5]	Lichao Zhai, Shijia Song, Lihua Zhang, Jinan Huang, Lihua Lv, Zhiqiang Dong, Yongzeng Cui, Mengjing Zheng, Wanbin Hou, Jingting Zhang, Yanrong Yao, Yanhong Cui, Xiuling Jia. Subsoiling before winter wheat alleviates the kernel position effect of densely grown summer maize by delaying post-silking root–shoot senescence[J]. >Journal of Integrative Agriculture, 2025, 24(9): 3384-3402.
[6]	Ling Ai, Ju Qiu, Jiuguang Wang, Mengya Qian, Tingting Liu, Wan Cao, Fangyu Xing, Hameed Gul, Yingyi Zhang, Xiangling Gong, Jing Li, Hong Duan, Qianlin Xiao, Zhizhai Liu. *A naturally occurring 31 bp deletion in TEOSINTE* BRANCHED1 causes branched ears in maize**[J]. >Journal of Integrative Agriculture, 2025, 24(9): 3322-3333.
[7]	Dan Lü, Jianxin Li, Xuehai Zhang, Ran Zheng, Aoni Zhang, Jingyun Luo, Bo Tong, Hongbing Luo, Jianbing Yan, Min Deng. Genetic analysis of maize crude fat content by multi-locus genome-wide association study[J]. >Journal of Integrative Agriculture, 2025, 24(7): 2475-2491.
[8]	Chunxiang Li, Yongfeng Song, Yong Zhu, Mengna Cao, Xiao Han, Jinsheng Fan, Zhichao Lü, Yan Xu, Yu Zhou, Xing Zeng, Lin Zhang, Ling Dong, Dequan Sun, Zhenhua Wang, Hong Di. *GWAS analysis reveals candidate genes associated with density tolerance (ear leaf structure) in maize (Zea* mays L.)**[J]. >Journal of Integrative Agriculture, 2025, 24(6): 2046-2062.
[9]	Lihua Xie, Lingling Li, Junhong Xie, Jinbin Wang, Zechariah Effah, Setor Kwami Fudjoe, Muhammad Zahid Mumtaz. A suitable organic fertilizer substitution ratio stabilizes rainfed maize yields and reduces gaseous nitrogen loss in the Loess Plateau, China[J]. >Journal of Integrative Agriculture, 2025, 24(6): 2138-2154.
[10]	Huairen Zhang, Tauseef Taj Kiani, Huabang Chen, Juan Liu, Xunji Chen. Genome wide association analysis reveals multiple QTLs controlling root development in maize [J]. >Journal of Integrative Agriculture, 2025, 24(5): 1656-1670.
[11]	Lanjie Zheng, Qianlong Zhang, Huiying Liu, Xiaoqing Wang, Xiangge Zhang, Zhiwei Hu, Shi Li, Li Ji, Manchun Ji, Yong Gu, Jiaheng Yang, Yong Shi, Yubi Huang, Xu Zheng. *Fine mapping and discovery of MIR172e, a candidate gene required for inflorescence development and lower floret abortion in maize ear*[J]. >Journal of Integrative Agriculture, 2025, 24(4): 1372-1389.
[12]	Xiaoxia Guo, Wanmao Liu, Yunshan Yang, Guangzhou Liu, Bo Ming, Ruizhi Xie, Keru Wang, Shaokun Li, Peng Hou. Matching the light and nitrogen distributions in the maize canopy to achieve high yield and high radiation use efficiency[J]. >Journal of Integrative Agriculture, 2025, 24(4): 1424-1435.
[13]	Yang Wang, Chunhua Mu, Xiangdong Li, Canxing Duan, Jianjun Wang, Xin Lu, Wangshu Li, Zhennan Xu, Shufeng Sun, Ao Zhang, Zhiqiang Zhou, Shenghui Wen, Zhuanfang Hao, Jienan Han, Jianzhou Qu, Wanli Du, Fenghai Li, Jianfeng Weng. A genome-wide association study and transcriptome analysis reveal the genetic basis for the Southern corn rust resistance in maize[J]. >Journal of Integrative Agriculture, 2025, 24(2): 453-466.
[14]	Xiuling Wang, Li Niu, Huaipan Liu, Xucun Jia, Yulong Zhao, Qun Wang, Yali Zhao, Pengfei Dong, Moubiao Zhang, Hongping Li, Panpan An, Zhi Li, Xiaohuan Mu, Yongen Zhang, Chaohai Li. Integrated transcriptomics and metabolomics analysis provide insights into the alleviation of waterlogging stress in maize by exogenous spermidine application[J]. >Journal of Integrative Agriculture, 2025, 24(12): 4546-4560.
[15]	Xinglong Wang, Fan Liu, Nan Zhao, Xia Du, Pijiang Yin, Tongliang Li, Tianqiong Lan, Dongju Feng, Fanlei Kong, Jichao Yuan. Optimizing sowing dates increase solar radiation to mitigate maize lodging and yield variability: A five-year field study[J]. >Journal of Integrative Agriculture, 2025, 24(12): 4573-4587.

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Shared

Discussed

Cite this article:

About JIA

Editorial board

For authors