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Multispectral Structural Characterization of Low-Molecular-Weight Organic Acids Modified Urea |
ZHANG Ying-qiang1, ZHANG Shui-qin2, WANG Li-yan1*, YUAN Liang2, LI Yan-ting2, XIONG Qi-zhong3, LIN Zhi-an2, ZHAO Bing-qiang2* |
1. School of Chemical and Environmental Engineering, China University of Mining and Technology, Beijing 100083, China
2. Institute of Agricultural Resources and Regional Planning, Chinese Academy of Agricultural Sciences/Key Laboratory of Plant Nutrition and Fertilizer, Ministry of Agriculture and Rural Affairs, Beijing 100081, China
3. Anhui Province Key Laboratory of Farmland Ecological Conservation and Pollution Prevention, School of Resources and Environment/Anhui Agricultural University, Hefei 230036, China |
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Abstract As the main nitrogen fertilizer in China, urea shows high activity. After hydrolysis in soil, urea is easily lost through volatilization and leaching, resulting in a low urea utilization efficiency, a waste of nutrient resources, and environmental pollution. Using organic acids to modify urea can delay urea decomposition, enhance urea use efficiency. However, the combination and enhancement mechanism is unclear. In this study, two low-molecular-weight organic acids, citric acid and salicylic acid, were selected as additives and added to molten urea to obtain urea containing citric acid (CAU) and urea containing salicylic acid (SAU). The combination of these two organic acids and urea was characterized by using Fourier transform infrared spectroscopy (FTIR), X-ray photoelectron spectroscopy (XPS), liquid chromatography-mass spectrometry (LC-MS) and other analytical technologies. The results showed that after the combination of citric acid and salicylic acid with urea, there was an enhanced primary amine vibrational peak at 3 348 cm-1 of FTIR spectra, indicating the reaction happened on the primary amine of urea. The new carbon structure (—CX) and nitrogen structure (—NX) was separated from the XPS C(1s) spectra and the N(1s) spectra, respectively. These new structures led to the decrease of the carboxyl group in citric/salicylic acid and amide group of urea. In addition, the C—OH chemical bond breakage happened in the XPS O(1s) spectra. The above indicated a new substance formed through the reaction of the carboxyl group in citric/salicylic acid and the amide group of urea to form a new substance. LC-MS analysis showed that the dehydration reaction happened between the carboxyl group of citric acid/salicylic acid and the amide group of urea, and that the new substance was structured with O═CNHC(O)NH2 will be produced in CAU or SAU. Therefore, the results from the spectral analysis and other analytical technologies used in this study clarified the combination characteristics of low-molecular-weight organic acid and urea. This founds a basis for the study on the reaction mechanism of organic polymer and urea and provides new ideas for the selection of high-efficiency fertilizer synergists.
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Received: 2020-06-05
Accepted: 2020-10-26
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Corresponding Authors:
WANG Li-yan, ZHAO Bing-qiang
E-mail: wangly@cumtb.edu.cn;zhaobingqiang@caas.cn
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[1] DING He-ping, WANG Shuai, WANG Nan, et al(丁和平, 王 帅, 王 楠, 等). Modern Agricultural Sciences(现代农业科学), 2009, 16(2): 24.
[2] YUAN Liang, ZHAO Bing-qiang, LIN Zhi-an, et al(袁 亮, 赵秉强, 林治安, 等). Journal of Plant Nutrition and Fertilizers(植物营养与肥料学报), 2014, 20(3): 620.
[3] WANG Zhi-yong, CHEN Zhen-wei, FANG Shan, et al(王志勇, 陈振伟, 房 山, 等). Chemical Fertilizer Industry(化肥工业), 2018, 45(4): 66.
[4] ZHANG Shui-qin, YUAN Liang, LI Wei, et al(张水勤, 袁 亮, 李 伟, 等). Journal of Plant Nutrition and Fertilizers(植物营养与肥料学报), 2017, 23(5): 1207.
[5] WU Li-ping, CHENG Shao-xin(武丽萍, 成绍鑫). Journal of Fuel Chemistry Technology(燃料化学学报). 2001, (5): 454.
[6] LIANG Zong-cun, WU Li-ping, CHENG Shao-xin (梁宗存, 武丽萍, 成绍鑫). Humic Acid(腐殖酸), 1996, (3): 10.
[7] LIU Zeng-bing, SHU Ai-ping, ZHAO Bing-qiang, et al(刘增兵, 束爱萍, 赵秉强, 等). Journal of Agricultural Resources and Environment(农业资源与环境学报), 2014, 31(5): 393.
[8] WENG Shi-fu(翁诗甫). Fourier Transform Infrared Spectroscopy(傅里叶变换红外光谱分析). 3rd ed.(第3版). Beijing: Chemical Industry Press(北京: 化学工业出版社), 2016. 490.
[9] ZHAO Na, LIANG Jia-cheng, SHI Li-yan, et al(赵 娜, 梁嘉诚, 时丽艳, 等). Chinese Journal of Chromatography(色谱), 2019, 37(3): 313.
[10] John F Watts, John Wolstenholme. An Introduction to Surface analysis By XPS and AES(表面分析(XPS和AES)引论). Translated by WU Zheng-long(吴正龙, 译). Shanghai: East China University of Science and Technology Press(上海: 华东理工大学出版社), 2008. 95.
[11] Briggs D. Polymer Surface Analysis(聚合物表面分析). Translated by CAO Li-li, DENG Zong-wu(曹立礼, 邓宗武, 译). Beijing: Chemical Industry Press(北京: 化学工业出版社), 2001. 67.
[12] XU Xiu-feng, ZHANG Peng-zhou(徐秀峰, 张蓬洲). Coal Conversion(煤炭转化), 1996, 19(1): 72.
[13] ZHANG Jia-yu, QIAO Yan-jiang, ZHANG-qian, et al (张加余, 乔延江, 张 倩, 等). Chinese Journal of Pharmaceutical Analysis(药物分析杂志), 2013, 33(2): 349. |
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