Nutrient uptake requirements with increasing grain yield for rice in China

doi:10.1016/S2095-3119(15)61143-1

Journal of Integrative Agriculture ›› 2016, Vol. 15 ›› Issue (4): 907-917.DOI: 10.1016/S2095-3119(15)61143-1

Nutrient uptake requirements with increasing grain yield for rice in China

CHE Sheng-guo¹, ZHAO Bing-qiang¹, LI Yan-ting¹, YUAN Liang¹, LIN Zhi-an¹, HU Shu-wen², SHEN Bing³

¹ Key Laboratory of Plant Nutrition and Fertilizer, Ministry of Agriculture/Institute of Agricultural Resources and Regional Planning, Chinese Academy of Agricultural Sciences, Beijing 100081, P.R.China
² College of Resource and Environmental Sciences, China Agricultural University, Beijing 100193, P.R.China
³ China BlueChemical Ltd., Beijing 100029, P.R.China

收稿日期:2015-03-18 出版日期:2016-04-01 发布日期:2016-04-07
通讯作者: ZHAO Bing-qiang, Tel/Fax: +86-10-82108664, E-mail: zhaobingqiang@caas.cn
作者简介:CHE Sheng-guo, Tel/Fax: +86-10-82108664, E-mail: cheshengguo@caas.cn
基金资助:
This research was supported by the Key Technologies R&D Program of China during the 12th Five-Year Plan period (2011BAD11B05).

Nutrient uptake requirements with increasing grain yield for rice in China

CHE Sheng-guo¹, ZHAO Bing-qiang¹, LI Yan-ting¹, YUAN Liang¹, LIN Zhi-an¹, HU Shu-wen², SHEN Bing³

¹ Key Laboratory of Plant Nutrition and Fertilizer, Ministry of Agriculture/Institute of Agricultural Resources and Regional Planning, Chinese Academy of Agricultural Sciences, Beijing 100081, P.R.China
² College of Resource and Environmental Sciences, China Agricultural University, Beijing 100193, P.R.China
³ China BlueChemical Ltd., Beijing 100029, P.R.China

Received:2015-03-18 Online:2016-04-01 Published:2016-04-07
Contact: ZHAO Bing-qiang, Tel/Fax: +86-10-82108664, E-mail: zhaobingqiang@caas.cn
About author:CHE Sheng-guo, Tel/Fax: +86-10-82108664, E-mail: cheshengguo@caas.cn
Supported by:
This research was supported by the Key Technologies R&D Program of China during the 12th Five-Year Plan period (2011BAD11B05).

摘要/Abstract

摘要： Improved estimates of nutrient requirements for rice (Oryza sativa L.) in China are essential to optimize fertilization regulation for increasing grain yields and reducing the potential of environmental negative influences, especially under high-yielding intensive systems. A database involving rice grain yields, nutrient concentrations and accumulations collected from on-field station experiments in the literatures published from 2000 to 2013 in China was developed to understand the relationships between grain yields and plant nutrient uptakes, and to quantify nutrient requirements for different yield levels. Considering all data sets, rice grain yield ranged from 1.4 to 15.2 t ha^–1 with the mean value of 7.84 t ha^–1, and ca. 10.4% of yield observations were higher than the yield barrier level of 10 t ha^–1. N requirement to produce one ton grain was 21.10 kg for the yield range <4.0 t ha^–1 with a high variation of 45.8%. Except of the yield range <4.0 t ha^–1, the values of N requirement, firstly increased from 18.78 kg for yield range 4.0–5.5 t ha^–1 to 20.62 kg for yield range 7.0–8.5 t ha^–1, then decreased slightly to 19.67 and 19.17 kg for the yield range 8.5–10 and >10 t ha^–1, respectively. Phosphorus (P) and potassium (K) requirements showed increasing trends, from 3.51 and 19.87 kg per t grain for <4.0 t ha^–1 yield range to 4.10 and 21.70 kg for >10.0 t ha^–1 range. In conclusion, nutrient requirement varied with increasement of grain yield, and N, P and K presented various response trends, increasing, declining or stagnating, which would be of great benefit for improving fertilizer strategies.

关键词: rice , nutrient requirement , nitrogen , phosphorus , potassium

Abstract: Improved estimates of nutrient requirements for rice (Oryza sativa L.) in China are essential to optimize fertilization regulation for increasing grain yields and reducing the potential of environmental negative influences, especially under high-yielding intensive systems. A database involving rice grain yields, nutrient concentrations and accumulations collected from on-field station experiments in the literatures published from 2000 to 2013 in China was developed to understand the relationships between grain yields and plant nutrient uptakes, and to quantify nutrient requirements for different yield levels. Considering all data sets, rice grain yield ranged from 1.4 to 15.2 t ha^–1 with the mean value of 7.84 t ha^–1, and ca. 10.4% of yield observations were higher than the yield barrier level of 10 t ha^–1. N requirement to produce one ton grain was 21.10 kg for the yield range <4.0 t ha^–1 with a high variation of 45.8%. Except of the yield range <4.0 t ha^–1, the values of N requirement, firstly increased from 18.78 kg for yield range 4.0–5.5 t ha^–1 to 20.62 kg for yield range 7.0–8.5 t ha^–1, then decreased slightly to 19.67 and 19.17 kg for the yield range 8.5–10 and >10 t ha^–1, respectively. Phosphorus (P) and potassium (K) requirements showed increasing trends, from 3.51 and 19.87 kg per t grain for <4.0 t ha^–1 yield range to 4.10 and 21.70 kg for >10.0 t ha^–1 range. In conclusion, nutrient requirement varied with increasement of grain yield, and N, P and K presented various response trends, increasing, declining or stagnating, which would be of great benefit for improving fertilizer strategies.

Key words: rice , nutrient requirement , nitrogen , phosphorus , potassium

CHE Sheng-guo, ZHAO Bing-qiang, LI Yan-ting, YUAN Liang, LIN Zhi-an, HU Shu-wen, SHEN Bing. Nutrient uptake requirements with increasing grain yield for rice in China[J]. Journal of Integrative Agriculture, 2016, 15(4): 907-917.

参考文献

Barea J M, Escudero J L, Azcon A C. 1980. Effects of introduced and indigenous VA mycorrhizal fungi nodulation, growth and nutrition of Medicago sativa in phosphate-fixing soils as affected by P fertilizers. Plant and Soil, 54, 283-296.

Cassman K G, Dobermann A, Walters D T, Yang H. 2003. Meeting cereal demand while protecting natural resources and improving environmental quality. Annual Review of Environment and Resources, 28, 315–358.

Dai X Q, Zhang H Y, Spiertz J H J, Yu J, Xie G H, Bouman B A M. 2010. Crop response of aerobic rice and winter wheat to nitrogen, phosphorus and potassium in a double cropping system. Nutrient Cycling in Agroecosystems, 86, 301–315.

Dobermann A, Witt C, Abdulrachman S, Gines H, Nagarajan R, Son T, Tan P, Wang G, Chien N, Thoa V. 2003. Estimating indigenous nutrient supplies for site-specific nutrient management in irrigated rice. Agronomy Journal, 95, 924–935.

Fageria N K. 2004. Dry matter yield and nutrient uptake by lowland rice at different growth stages. Journal of Plant Nutrition, 27, 947–958.

Fan M, Lu S, Jiang R, Liu X, Zhang F. 2009. Triangular transplanting pattern and split nitrogen fertilizer application increase rice yield and nitrogen fertilizer recovery. Agronomy Journal, 101, 1421.

FAO. 2013. FAO Statistical databases. Food and Agriculture Organization of the United Nations, Rome. [2014-10-08]. http://www.fao.org

Guo S L, Wu J S, Dang TH, Liu W Z, Li Y, Wei W X, Kwith S. 2010. Impacts of fertilizer practices on environmental risk of nitrate in semiarid farmlands in the Loess Plateau of China. Plant and Soil, 330, 1–13.

Haefele S M, Wopereis M C S, Ndiaye M K, Barro S E, Ould Isselmou M. 2003. Internal nutrient efficiencies, fertilizer recovery rates and indigenous nutrient supply of irrigated lowland rice in Sahelian West Africa. Field Crops Research, 80, 19–32.

Hay R K M. 1995. Harvest index: A review of its use in plant breeding and crop physiology. Annals of Applied Biology, 126, 197–216.

Hou P, Gao Q, Xie R, Li S, Meng Q, Kirkby E A, Römheld V, Müller T, Zhang F, Cui Z, Chen X. 2012. Grain yields in relation to N requirement: Optimizing nitrogen management for spring maize grown in China. Field Crops Research, 129, 1–6.

Huang M, Zou Y B, Jiang P, Xia B, Ibrahim M, Ao H J. 2011. Relationship between grain yield and yield components in super hybrid rice. Agricultural Sciences in China, 10, 1537–1544.

Jarrell W M, Beverly, R B. 1981. The dilution effect in plant nutrition studies. Advances in Agronomy, 34, 197–224.

Katsura K, Maeda S, Lubis I, Horie T, Cao W, Shiraiwa T. 2008. The high yield of irrigated rice in Yunnan, China. Field Crops Research, 107, 1–11.

Lin B. 1989. Utilization of Chemical Fertilizer in China. Beijing Science and Technology Publishing, Beijing, China. p. 11. (in Chinese)

Ling Q H. 2000. Crop Population Quality. Shanghai Scientific and

Technical Publishers, Shanghai, China. p. 157. (in Chinese)

Ling Q H, Zhang H C, Huang P S, Ling L, Dai Q G. 2002. New nitrogen application regime on high-yielding rice. Acta Pedologica Sinica, 39, 26–40. (in Chinese)

Ling Q H. 2007. Precise and Quantitative Cultivation Theory and Technique in Rice. Chinese Agricultural Press, Beijing, China. p. 101. (in Chinese)

Mann C C. 1999. Crop scientists seek a new revolution. Science, 283, 310–314.

National Bureau of Statistics of China. 2013. China Agriculture Yearbook. China Agriculture Press, Beijing. (in Chinese)

Peng S B, Buresh R J, Huang J L, Yang J C. 2006. Strategies for overcoming low agronomic nitrogen use efficiency in irrigated rice systems in China. Field Crops Research, 96, 37–47.

Peng S B, Cassman K G, Virmani S S, Sheehy J, Khush G S. 1999. Yield potential trends of tropical rice since the release of ir8 and the challenge of increasing rice yield potential. Crop Science, 39, 1552–1559.

Peng S B, Laza R C, Visperas R M, Sanico A L, Cassman K G, Khush G S. 2000. Crop breeding, genetics and cytology. Crop Science, 40, 307-314.

Peng S B, Tang Q Y, Zou Y B. 2009. Current status and challenges of rice production in China. Plant Production Science, 12, 3-8.

Sinclair T R. 1998. Historical changes in harvest index and crop nitrogen accumulation. Crop Science, 38, 638–643.

Sui B, Feng X, Tian G, Hu X, Shen Q, Guo S. 2013. Optimizing nitrogen supply increases rice yield and nitrogen use efficiency by regulating yield formation factors. Field Crops Research, 150, 99–107.

Timsina J, Panaullah G M, Saleque M A, Ishaque M, Pathan A B, Quayyum M A, Connor D J, Saha P K, Humphreys E, Meisner C A. 2006. Nutrient uptake and apparent balances for rice-wheat sequences. I. Nitrogen. Journal of Plant Nutrition, 29, 137–155.

Tong C, Hall C A S, Wang H. 2003. Land use change in rice, wheat and maize production in China (1961–1998). Agriculture, Ecosystems & Environment, 95, 523–536.

Wang G H, Dobermann A, Witt C, Sun Q Z, Fu R X. 2001. Performance of site-specific nutrient management for irrigated rice in Southeast China. Agronomy Journal, 93, 869-878.

Wang G H, Zhang Q C, Witt C, Buresh R J. 2007. Opportunities for yield increases and environmental benefits through site-specific nutrient management in rice systems of Zhejiang Province, China. Agricultural Systems, 94, 801–806.

Witt C, Dobermann A, Abdulrachman S, Gines H C, Guanghuo W, Nagarajan R, Satawatananont S, Thuc Son T, Sy Tan P, Van Tiem L, Simbahan G C, Olk D C. 1999. Internal nutrient efficiencies of irrigated lowland rice in tropical and subtropical Asia. Field Crops Research, 63, 113–138.

Xie G H, Wang X Y, Han D Q, Xue S. 2011. Harvest index and residue factor of non-cereal crops in China. Journal of China Agricultural University, 16, 9–17. (in Chinese)

Xue L, Li G, Qin X, Yang L, Zhang H. 2014. Topdressing nitrogen recommendation for early rice with an active sensor in south China. Precision Agriculture, 15, 95–110.

Yu L H. 2011. Study on Population Quality and Quantitative Cultivation of Mechanical Transplanting Rice. Nanjing Agricultural University, Nanjing, China. (in Chinese)

Yang W, Peng S B, Laza R C, Visperas R M, Dionisio M L. 2007. Grain yield and yield attributes of new plant type and hybrid rice. Crop Science, 47, 1393-1400.

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

Yue S, Meng Q, Zhao R, Ye Y, Zhang F, Cui Z, Chen X. 2012. Change in nitrogen requirement with increasing grain yield for winter wheat. Agronomy Journal, 104, 1687–1693.

Zhang Q C, Wang G H. 2005. Studies on nutrient uptake of rice and characteristics of soil microorganisms in a long-term fertilization experiments for irrigated rice. Journal of Zhejiang University Science, 6B, 147–154.

Zhang Y, Zhang C C, Yan P, Chen X P, Yang J C, Zhang F S, Cui Z L. 2013. Potassium requirement in relation to grain yield and genotypic improvement of irrigated lowland rice in China. Journal of Plant Nutrition and Soil Science, 176, 400–406.

Zhao B, Li X, Liu H, Wang B, Zhu P, Huang S, Bao D, Li Y, So H B. 2011. Results from long-term fertilizer experiments in China: The risk of groundwater pollution by nitrate. NJAS-Wageningen Journal of Life Sciences, 58, 177–183.

Zhang F C, Zhu Z H. 1990. Harvest index for various crops in China. Scientia Agricultura Sinica, 23, 83-87. (in Chinese)

Zhu Z L, Chen D L. 2002. Nitrogen fertilizer use in China – Contributions to food production, impacts on the environment and best management strategies. Nutrient Cycling in Agroecosystems, 63, 117–127.

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Nutrient uptake requirements with increasing grain yield for rice in China

Nutrient uptake requirements with increasing grain yield for rice in China

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