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Acta Agron Sin ›› 2017, Vol. 43 ›› Issue (08): 1226-1233.doi: 10.3724/SP.J.1006.2017.01226

• TILLAGE & CULTIVATION·PHYSIOLOGY & BIOCHEMISTRY • Previous Articles     Next Articles

Optimum Amount of Potassium Fertilizer Applied under Continuous Rice-rapeseed Rotation

XIAO Ke1,TANG Jing1,LI Ji-Fu1,*,ZOU Jia-Long2,ZHU Jian-Qiang1   

  1. 1 Engineering Research Center of Ecology and Agricultural Use of Wetland, Ministry of Education / College of Agriculture, Yangtze University, Jingzhou 434025, China; 2 Soil and Fertilizer Station of Jingzhou City, Jingzhou 434020, China
  • Received:2016-12-24 Revised:2017-07-20 Online:2017-08-12 Published:2017-04-27
  • Contact: Li Jifu, E-mail: jifuli@yangtzeu.edu.cn, Tel: 0716-8066314 E-mail:497378374@qq.com
  • Supported by:

    This research was supported by the Special National Key Research and Development (2016YFD0300907), the Open-end Fund of Engineering Research Center of Ecology and Agricultural Use of Wetland, Ministry of Education (KF201613), and the Earmarked Fund for China Agriculture Research System (CARS-13).

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Abstract:

In order to provide a scientific basis for K fertilization in paddy-upland rotation, effects of K fertilizer rate on crop production, K efficiency, and soil K status were studied. A long-term (2011–2016) field experiment was conducted in the Jianghan Plain, Hubei province, China. Five treatments were applied with three replications each: 0 kg hm-2 (K0), 45 kg hm-2 (K1), 90 kg hm-2 (K2), 135 kg hm-2 (K3) and 180 kg hm-2 (K4), where K2 treatment was the recommended amount of K fertilizer (90 kg ha-1). The yields of rice and rapeseed were 6.87 t ha-1 and 2.25 t ha-1 respectively, in the condition without K fertilizer and with higher soil available K content. Application of K fertilizer could significantly increase the yield after one crop rotation; the increase in rapeseed season was higher than that in the rice season, accounting for 16.9% and 63.8%, respectively. With the application of the recommended amount of K fertilizer, the agronomic K efficiency (KAE) of rice and rapeseed was 5.1 kg kg-1 and 3.2 kg kg-1, respectively; however, the K recovery efficiency (KRE) and K contribution rate (KCR) of rice were lower than those of rapeseed, which indicated that K absorbed by rice was mainly from the soil, and more external supply of K fertilizer was needed to meet the nutrient demand of rapeseed. According to the fertilizer efficiency model, the optimum annual amounts of K fertilizer (K2O) were 70.5–100.9 kg ha-1 for rice, with an average of 96.6 kg ha-1, and 75.6–118.2 kg ha-1 for rapeseed, with an average of 107.0 kg ha-1, which were 7.3% and 18.9% higher, respectively, than the recommended amount in this region. Under the soil K condition in this study, long-term application of recommended K fertilizer rate (180 kg ha-1 per year) could not only affect yield stability, but also decrease crop system K balance and soil available K content. Therefore, K fertilizer should be preferentially applied in the rapeseed season rather than the rice season and straw returning to field should also be taken into consideration to maintain the soil K balance and sustainable high-yield production in the crop rotation system.

Key words: Paddy-upland rotation, Yield, Soil K, Optimum recommendation of K fertilizer, K fertilizer efficiency

[1]Fan M S, Jiang R F, Liu X J, Zhang F S, Lu S H, Zeng X Z, Christie P. Interactions between non-flooded mulching cultivation and varying nitrogen inputs in rice–wheat rotations. Field Crops Res, 2005, 91: 307–318 [2]Zhang L M, Zhuang Q L, Li X D, Zhao Q Y, Yu D S, Liu Y L, Shi X Z, Xing S H, Wang G X. Carbon sequestration in the uplands of Eastern China: An analysis with high-resolution model simulations. Soil Tillage Res, 2016, 158: 165–176 [3]Cakmak I. Plant nutrition research: Priorities to meet human needs for food in sustainable ways. Plant Soil, 2002, 247: 3–24 [4]Subba R A, Srinivasarao C, Srivastava S. Potassium Status and Crop Response to Potassium on the Soils of Agroecological Regions of India. IPI Research Topics No. 20, International Potash Institute, Horgen, Switzerland, 2010 [5]Li J F, Lu J W, Ren T, Cong R H, Li X K, Zhou L. Crop straw can optimize potassium fertilization strategies in rice cropping system. Better Crop, 2014, 98(3): 13–15 [6]王伟妮. 基于区域尺度的水稻氮磷钾肥料效应及推荐施肥量研究. 华中农业大学博士学位论文, 湖北武汉, 2014 Wang W N. Evaluating Fertilization Effect and Fertilizer Recommendation of Nitrogen, Phosphorus and Potassium for Rice at a Regional Scale. PhD Dissertation of Huazhong Agricultural University, Wuhan, China, 2014 (in Chinese with English abstract) [7]Cui Z L, Zhang F S, Chen X P, Dou Z X, Li J L. In-season nitrogen management strategy for winter wheat: Maximizing yields, minimizing environmental impact in an over-fertilization context. Field Crops Res, 2010, 116: 140–146 [8]吴良泉, 武良, 崔振岭, 陈新平, 张福锁. 中国玉米区域氮磷钾肥推荐用量及肥料配方研究. 土壤学报, 2015, 52: 802–817 Wu L Q, Wu L, Cui Z L, Chen X P, Zhang F S. Basic NPK fertilizer recommendation and fertilizer formula for maize production regions in China. Acta Pedol Sin, 2015, 52: 802–817 (in Chinese with English abstract) [9]Wang Y, Liu T, Li X K, Ren T, Cong R H, Lu J W. Nutrient deficiency limits population development, yield formation, and nutrient uptake of direct sown winter oilseed rape. J Integr Agric, 2015, 14: 670–680 [10]Zhao S, He P, Qiu S, Jia L, Liu M, Jin J, Johnston A M. Long-term effects of potassium fertilization and straw return on soil potassium levels and crop yields in north-central China. Field Crops Res, 2014, 169: 116–122 [11]郭九信, 冯绪猛, 胡香玉, 田广丽, 王伟, 陈健, 刘田, 艾山江?赛衣丁, 郭世伟. 氮肥用量及钾肥施用对稻麦周年产量及效益的影响. 作物学报, 2013, 39: 2262–2271 Guo J X, Feng X M, Hu X Y, Tian G L, Wang W, Chen J, Liu T, Sai H, Guo S W. Effects of nitrogen and potassium fertilizers application on annual yield and economic effect in rotation of rice and wheat. Acta Agron Sin, 2013, 39: 2262?2271 (in Chinese with English abstract) [12]王筝, 鲁剑巍, 张文君, 李小坤. 田间土壤钾素有效性影响因素及其评估. 土壤, 2012, 44: 898–904 Wang Z, Lu J W, Zhang W J, Li X K. Influential factors on soil available potassium evaluation in agriculture. Soil, 2012, 44: 898–904 (in Chinese with English abstract) [13]Zhang H M, Yang X Y, He X H, Xu M G, Huang S, Liu H, Wang B R. Effect of long-term potassium fertilization on crop yield and potassium efficiency and balance under wheat-maize rotation in China. Pedosphere, 2011, 21: 154–163 [14]Liao Y L, Zheng S X, Nie J, Xie J, Lu Y H, Qin X L. Long-term effect of fertilizer and rice straw on mineral composition and potassium adsorption in a reddish paddy soil. J Integr Agric, 2013, 12: 694–710 [15]李银水. 湖北省油菜氮磷钾肥施用效果及肥料推荐用量研究. 武汉: 华中农业大学硕士学位论文, 2009 Li Y S. Study on NPK Fertilization Effect and Optimum Application Rate of Fertilizer for Rapeseed in Hubei Province. MS Thesis of Huazhong Agricultural University, Wuhan, Hubei, 2009 (in Chinese with English abstract) [16]鲍士旦. 土壤农化分析(第3版). 北京: 中国农业出版社, 2007 Bao S D. Soil and Agricultural Chemistry Analysis, 3rd edn. Beijing: China Agriculture Press, 2007 (in Chinese) [17]Wang W N, Lu J W, Ren T, Su W, Lu M X. Evaluating regional mean optimal nitrogen rates in combination with indigenous nitrogen supply for rice production. Field Crops Res, 2012, 137: 37–48 [18]Pettigrew W T. Potassium influences on yield and quality production for maize, wheat, soybean and cotton. Physiol Plant, 2008, 133: 670–681 [19]Battie-Laclau P, Laclau J P, Beri C, Mietton L, Muniz M R A, Arenque B C. Photosynthetic and anatomical responses of eucalyptus grandisleaves to potassium and sodium supply in a field experiment. Plant Cell Environ, 2014, 37: 70–81 [20]王伟妮, 鲁剑巍, 李银水, 邹娟, 苏伟, 李小坤, 李云春. 当前生产条件下不同作物施肥效果和肥料贡献率研究. 中国农业科学, 2010, 43: 3997–4007 Wang W N, Lu J W, Li Y S, Zou J, Su W, Li X K, Li Y C. Study on fertilization effect and fertilizer contribution rate of different crops at present production conditions. Sci Agric Sin, 2010, 43: 3997–4007 (in Chinese with English abstract) [21]Xiong W, Holman I P, You L Z, Yang J, Wu W B. Impacts of observed growing-season warming trends since 1980 on crop yields in China. Reg Environ Chang, 2014, 14: 7–16 [22]Su W, Liu B, Liu X W, Li X K, Ren T, Cong R H, Lu J W. Effect of depth of fertilizer banded-placement on growth, nutrient uptake and yield of oilseed rape (Brassica napus L.). Eur J Agron, 2015, 62: 38–45 [23]Timsina J. Nutrient uptake and apparent balances for rice-wheat sequences: III. Potassium. J Plant Nutr, 2006, 29: 137–155 [24]张维乐, 戴志刚, 任涛, 周先竹, 王忠良, 李小坤, 丛日环. 不同水旱轮作体系秸秆还田与氮肥运筹对作物产量及养分吸收利用的影响. 中国农业科学, 2016, 49: 1254–1266 Zhang W L, Dai Z G, Ren T, Zhou X Z, Wang Z L, Li X K, Cong R H. Effects of nitrogen fertilization managements with residues incorporation on crops yield and nutrients uptake under different paddy-upland rotation systems. Sci Agric Sin, 2016, 49: 1254–1266 (in Chinese with English abstract) [25]李继福, 薛欣欣, 李小坤, 任涛, 邹家龙, 陈华东, 丛日环, 周鹂, 鲁剑巍. 水稻?油菜轮作模式下秸秆还田替代钾肥的效应. 植物营养与肥料学报, 2016, 22: 317–325 Li J F, Xue X X, Li X K, Ren T, Zou J L, Chen H D, Cong R H, Zhou L, Lu J W. Substituting effect of crop residues for K fertilizer in rice-rapeseed rotation system. J Plant Nutr Fert, 2016, 22: 317–325 (in Chinese with English abstract) [26]Petersen J, Thomsen I K, Mattsson L, Hansen E M, Christensen B T. Estimating the crop response to fertilizer nitrogen residues in long-continued field experiments. Nutr Cycl Agroecos, 2012, 93: 1–12 [27]Parker M B. Nitrogen, phosphorus, and potassium fertilization of a coastal plain cotton–peanut rotation. Commun Soil Sci Plan, 2006, 37: 1485–1499 [28]Th?le H, Richter C, Ehlert D. Strategy of statistical model selection for precision farming on-farm experiments. Precis Agric, 2013, 14: 434–449 [29]Zhang Y, Zhang C C, Yan P, Chen X P, Yang J C, Zhang F S, Cui Z L. Potassium requirement in relation to grain yield and genotypic improvement of irrigated lowland rice in China. J Plant Nutr Soil Sci, 2013, 176: 400–406 [30]Wu L Q, Cui Z L, Chen X P, Zhao R F, Si D X, Sun Y X, Yue S C. High-yield maize production in relation to potassium uptake requirements in China. Agron J, 2014, 106: 1153–1158
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