Analysis of soil and plant nutrients in alfalfa fields in China

doi:10.11686/cyxb2015206

Abstract

Abstract: A scientific approach to fertilizer management is important to ensure optimal plant growth, high fertilizer use efficiency and to resolve the contradictions surrounding production and environmental issues. In order to understand fertilizer management in alfalfa production, a survey was conducted to investigate alfalfa yield at first cut, as well as soil nutrients and plant nutrient content in 49 alfalfa fields in northern China over two years (2012 and 2013). Simultaneously, a survey (questionnaire) was conducted to determine how alfalfa growers (including farmers and corporate growers) managed fertilizer application. Alfalfa was mostly planted in relatively barren sandy soils. Among 49 fields, 35 fields were sandy soil (71.4%), mainly in Inner Mongolia, Gansu and Xinjiang. Soil available nitrogen (N) was high in most fields and deficient in only 10% of fields, mainly due to extremely low organic matter content. Available phosphorus (P) was low in 24.5% of fields and very low in 10.2% of fields. Available potassium (K) was low in 10.2% of fields. Calcium and magnesium were plentiful in all soils. Analysis of micronutrients revealed that 32.2% fields had low available iron (mainly Gansu and Inner Mongolia); 7.1% of fields low available manganese (Gansu and Inner Mongolia); 14.3% of fields had low available copper (1 field Gansu, 3 Inner Mongolia); 50% of fields had low available zinc; 10.7% of fields had low available molybdenum (Mo) (mainly Inner Mongolia); conversely all fields were high in available boron. The alfalfa stands generally had good N nutrition but were low P and K. Among 49 fields 49% of fields had low Mo. Correlation analysis showed that soil total and available P were significantly positively correlated (P<0.05) with alfalfa dry matter yield, suggesting that P fertilizer would significantly increase alfalfa yield. Growers of 18 fields, mostly farmers, didn't apply any fertilizer. 57.1% of growers applied N to increase yields, mostly corporate growers. Phosphate was applied to 41% of fields K to 26.5%. Organic fertilizer was only applied in 8 fields. Micronutrients were not applied to any crops. It was concluded that application of N to alfalfa was relatively common, contradicting the ability of the crop to biologically fix N. Soil P and K levels in soils were low, especially K in China, suggesting that many alfalfa crops would benefit from application of these nutrients. Molybdenum may be limiting in some alfalfa crops.

XIE Kai-Yun, HE Feng, LI Xiang-Lin, HAN Dong-Mei, WAN Li-Qiang. Analysis of soil and plant nutrients in alfalfa fields in China[J]. Acta Prataculturae Sinica, 2016, 25(3): 202-214.

References

[1] Zhang Y J, Wang M L, Huang D, et al . The development trends and technical requirements of forage industry in our country.Modern Animal Husbandry and Veterinary, 2011, 10(8): 11.
[2] Undersander D, Martin N, Cosgrove D, et al . Alfalfa Management Guide[K]. Madison: American Society of Agronomy, 2011.
[3] Russelle M, Sheaffer C. Use of the diagnosis and recommendation integrated system with alfalfa. Agronomy Journal, 1986, 78(3): 557-560.
[4] Xie Y, Sun H R, Zhang X Q, et al . Effects of N, P, K fertilizers on lucern and recommended fertilizer applied rate in Bashang area. Chinese Journal of Grassland, 2012, 34(2): 52-57.
[5] Liu X J, Zhang J X, Li W Q, et al . Effects of nitrogen and phosphorus addition and cuttings on yield and quality of alfalfa in dry region of Gansu, China. Journal of Desert Research, 2014, 34: 1516-1526.
[6] He F, Han D M, Wan L Q, et al . The nutrient situations in the major alfalfa producing areas of China. Plant Nutrition and Fertilizer Science, 2014, (2): 503-509.
[7] Bao S D. Soil and Agricultural Chemistry Analysis[M]. Beijing: China Agricultural Press, 2000.
[8] NY/T 890-2004, Determination of available zinc, manganese, iron, copper in soil-extraction with buffered DTPA solution[S]. 2005.
[9] NY 1121.8-2006-T, Soil testing Part 8: Method for determination of soil available boron[S]. 2006.
[10] NY 1121.9-2006-T, Soil testing Part 9: Method for determination of soil available molybdenum[S]. 2006.
[11] NY/T 2700-2015, Code of practice for soil rest and fertilizer recommendation of forage fields-Alfalfa ( Medicago sativa L)[S].
[12] Hesterman O, Sheaffer C, Barnes D, et al . Alfalfa dry matter and nitrogen production, and fertilizer nitrogen response in legume-corn rotations. Agronomy Journal, 1986, 78(1): 19-23.
[13] Xie K Y, Li X L, He F, et al . Response of alfalfa and smooth brome to nitrogen fertilizer in monoculture and mixed grasslands. Acta Prataculturae Sinica, 2014, 23(6): 148-156.
[14] He S B, Shen Y Y, Yang H M, et al . The effect of nitrogen on alfalfa yield and quality and carbon assimilation mechanism[A]. The Third Alfalfa Development Conference Proceedings in China[C]. Beijing: Chinese Grassland Society, 2010.
[15] Peters E, Stritzke J. Herbicides and nitrogen fertilizer for the establishment of three varieties of spring-sown alfalfa. Agronomy Journal, 1970, 62(2): 259-262.
[16] Hannaway D, Shuler P. Nitrogen fertilization in alfalfa production. Journal of Production Agriculture, 1993, 6(1): 80-85.
[17] Raun W, Johnson G, Phillips S, et al . Alfalfa yield response to nitrogen applied after each cutting. Soil Science Society of America Journal, 1999, 63(5): 1237-1243.
[18] Nuttall W. Effect of N, P and S fertilizers on alfalfa grown on three soil types in northeastern saskatchewan I. yield and soil tests. Agronomy Journal, 1985, 77(1): 41-46.
[19] Razmjoo K, Henderlong P R. Effect of potassium, sulfur, boron, and molybdenum fertilization on alfalfa production and herbage macronutrient contents. Journal of Plant Nutrition, 1997, 20(12): 1681-1696.
[20] Wang L, Attoe O, Truog E. Effect of lime and fertility level on the chemical composition and winter survival of alfalfa. Agronomy Journal, 1953, 45: 381-384.
[21] Smith D. Effects of potassium topdressing a low fertility silt loam soil on alfalfa herbage yields and composition and on soil K values. Agronomy Journal, 1975, 67(1): 60-64.
[22] Sheafler C, Russelle M, Hesterman O, et al . Alfalfa response to potassium, irrigation, and harvest management. Agronomy Journal, 1986, 78(3): 464-468.
[23] Harris P, McNaught K, Lynch P. The main effects and interactions of nutrients on the growth of irrigated lucerne. New Zealand Journal of Agricultural Research, 1966, 9(3): 653-690.
[24] Sherrell C. Sodium and potassium effects on cation concentration and yield of lucerne and phalaris grown separately and together. Journal of Plant Nutrition, 1983, 6(9): 801-816.
[25] Liu G H, Han J G, Wang K. Effects of boron, molybdenum, zinc and macronutrients on the yield and quality of alfalfa. Acta Agrestia Sinica, 2004, 12(4): 268-272.
[26] Liu G H, Zhang X X, Wang K. Effects of combined application of B, Mo and Zn fertilizers on yield and crude protein content of lucerne. Grassland of China, 2005, 27(6): 13-18.
[27] Gupta U C. Boron nutrition of alfalfa, red clover and timothy grown on podzol soils of eastern canada. Soil Science, 1984, 137(1): 16-22.
[28] Chandler R F, Peech M, Bradfield R. A study of techniques for predicting the potassium and boron requirements of alfalfa: I. The influence of muriate of potash and borax on yield, deficiency symptoms, and potassium content of plant and soil. Soil Science Society of America Journal, 1946, 10(C): 141-146.
[29] Du W H, Tian X H. Effects of micronutrients on seed yield and yield components of alfalfa. Journal of Plant Nutrition, 2009, 32(5): 809-820.
[30] Xing Y H, Wang R, Xie F D, et al . Effects of potassium fertilizer on N, P 2 O 5 and K 2 O absorption of alfalfa. Soil and Fertilizer Sciences in China, 2008, (1): 32-34.
[31] Han Q F, Zhou F, Jia J, et al . Effect of fertilization on productivity of different lucerne varieties and soil fertility. Plant Nutrition and Fertilizer Science, 2009, 15(6): 1413-1418.
[32] Chen P, Shen Z R, Chi H F, et al . Effects of different fertilization on output and plant height of alfalfa. Crops, 2013, (1): 8-11.
[33] He F, Xie K Y, Wan L Q, et al . The role of alfalfa on the maintenance of food security in china. Journal of Agricultural Science and Technology, 2014, 16(6): 7-13.
[34] 张英俊, 王明利, 黄顶, 等. 我国牧草产业发展趋势与技术需求. 现代畜牧兽医, 2011, 10(8): 11.
[35] 谢勇, 孙洪仁, 张新全, 等. 坝上地区紫花苜蓿氮, 磷, 钾肥料效应与推荐施肥量. 中国草地学报, 2012, 34(2): 52-57.
[36] 刘晓静, 张进霞, 李文卿, 等. 施肥及刈割对干旱地区紫花苜蓿产量和品质的影响. 中国沙漠, 2014, 34: 1516-1526.
[37] 何峰, 韩冬梅, 万里强, 等. 我国主产区紫花苜蓿营养状况分析. 植物营养与肥料学报, 2014, (2): 503-509.
[38] 鲍士旦. 土壤农化分析[M]. 北京: 中国农业出版社, 2000.
[39] NY/T 890-2004, 土壤有效态锌, 锰, 铁, 铜含量的测定-二乙三胺五乙酸 (DTPA) 浸提法[S]. 2005.
[40] NY 1121.8-2006-T, 土壤检测第8部分:土壤有效硼的测定[S]. 2006.
[41] NY 1121.9-2006-T, 土壤检测第9部分:土壤有效钼的测定[S]. 2006.
[42] NY/T 2700-2015, 草地测土施肥技术规程紫花苜蓿[S].
[43] 谢开云, 李向林, 何峰, 等. 单播与混播下紫花苜蓿与无芒雀麦生物量对氮肥的响应. 草业学报, 2014, 23(6): 148-156.
[44] 何树斌, 沈禹颖, 杨惠敏, 等. 氮对紫花苜蓿产量和品质的影响及其对碳同化的调控机理[A]. 第三届中国苜蓿发展大会论文集[C]. 北京: 中国草学会, 2010.
[45] 刘贵河, 韩建国, 王堃. 硼, 钼, 锌与大量元素配施对紫花苜蓿草产量和品质的影响. 草地学报, 2004, 12(4): 268-272.
[46] 刘贵河, 章杏杏, 王堃. 硼, 钼, 锌配施对紫花苜蓿草产量和粗蛋白质含量的影响. 中国草地, 2005, 27(6): 13-18.
[47] 邢月华, 汪仁, 谢甫绨, 等. 钾肥对苜蓿植株吸收氮磷钾的影响. 中国土壤与肥料, 2008, (1): 32-34.
[48] 韩清芳, 周芳, 贾珺, 等. 施肥对不同品种苜蓿生产力及土壤肥力的影响. 植物营养与肥料学报, 2009, 15(6): 1413-1418.
[49] 陈萍, 沈振荣, 迟海峰, 等. 不同施肥处理对紫花苜蓿产量和株高的影响. 作物杂志, 2013, (1): 8-11.
[50] 何峰, 谢开云, 万里强, 等. 紫花苜蓿在维护我国食物安全中的作用. 中国农业科技导报, 2014, 16(6): 7-13.