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| Extraction Spectrophotometric Determination of Octadecylamine in Potassium Chloride |
| SONG Zhong-mei1, 4, LU Miao1, 4, ZHANG Hui-fang1*, ZHANG Peng-rui1, FANG De-zhen1, 4, MA Liang1, 4, LIU Qing-qing2, YU Xue-feng2, LIU Hai-ning1, YE Xiu-shen1, MA Zhen2, PENG Wen-bo3, WU Zhi-jian1 |
1. Key Laboratory of Green and High-end Utilization of Salt Lake Resources, Salt Lake Resources Chemistry of Qinghai Province, Qinghai Institute of Salt Lakes, Chinese Academy of Sciences, Xining 810008, China
2. Salt Lake Corporation Central Research Istitute, Qinghai Salt Lake Industry Co., Ltd., Golmud 816000, China
3. Department of Science and Technology Affaris, Qinghai Productivity Promotion Center Co., Ltd., Xining 810008, China
4. School of Chemical Science, University of Chinese Academy of Sciences, Beijing 100049, China
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Abstract Octadecylamine is a flotation collector commonly used to produce potassium chloride by cold crystallization-positive flotation, and its dosage will significantly affect the flotation separation efficiency. In addition, octadecylamine will adsorb on the surface of potassium chloride and inevitably remain in potassium chloride products, which is inconducive to developing high-purity potassium salt products. To meet the requirement of determination of octadecamide potency in potassium chloride, an extraction spectrophotometry was developed, based on the principle of van der Waals force and hydrogen bonding between octadecylamine and bromophenol blue with butyl acetate as extractant and bromophenol blue sodium salt as chromogenic agent. The effects of solution pH, dodecyl morpholine, co-existing salt, equilibrium time, and the amount of chromogenic agent on the concentration measurement of octachylamine were investigated. The results show that when the solution pH increases from 3 to 9, the absorbance of the extract decreases because the complexation between octachylamine and bromophenol blue weakens. The polarity of the complex molecules increases. When the solution pH is less than 5, dodecyl morpholine and bromophenol blue can also form colored complexes. While pH is between 6 and 9, the absorbance tends to zero. The ionic strength of the coexisting solutions of potassium chloride, sodium chloride, potassium sulfate and magnesium chloride increases, weakening the hydrogen bonding. Still, the salting-out effect of the complex molecules is enhanced, and the trace Li+, NH+4 and B in the solution have little effect on the absorbance. The absorbance does not conform to Lambert-Beer law when the amount of chromogenic agent is too large. Besides, equilibrium time has little effect on the absorbance. The determination conditions in potassium chloride solution are as follows: The solution pH is 6, the ionic strength is 1 mol·L-1, and the amount of 2 mmol·L-1 chromogenic agent is 0.5 mL. 5 mL butyl acetate is added to the 25 mL aqueous solution adjusted by buffer after 5 min of reaction for extraction. After 2 min of delamination equilibrium, the absorbance of the extraction solution is tested at 458 nm. The working curve is A=0.049 49c+0.066 24 (R2=0.992 3, ε=1.33×104 L·mol-1·cm-1, 0~10 mg·L-1). The relative standard deviation of this method was 0.33%~2.63%, the mean relative error was -0.90%, and the mean relative error of the system of octadecylamine and dodecylmorpholine was -0.25%. The content of octadecamide in the filter liquor derived from washing potassium chloride after positive flotation was 8.66 mg·L-1 and recoveres were 95.5%~106% by this method. The extraction spectrophotometry has been proven to be appropriate for detecting the concentration of octadecamide in the production of potassic fertilizer in salt lakes.
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Received: 2023-04-04
Accepted: 2023-11-01
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Corresponding Authors:
ZHANG Hui-fang
E-mail: zhanghf@isl.ac.cn
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[1] HUI Qing-hua, QUAN Chao-ming, ZHANG Hui-fang, et al(惠庆华,权朝明,张慧芳,等). Applied Chemical Industry(应用化工), 2021, 50(12): 3414.
[2] XIONG Xue-heng, TAN Qin-jian, LU Zhi-bin, et al(熊学恒,谭勤俭,卢志斌). Modern Mining(现代矿业), 2016, 32(5): 51.
[3] GUO Bo-hong, WU Wei, CHENG Yi(郭波红,吴 卫,程 怡). Chinese Journal of Pharmaceutical Analysis(药物分析杂志), 2011, 31(8): 1560.
[4] LIANG Hui-bin, DU Zhi-ping, LI Da, et al(梁慧斌,杜志平,李 达,等). Chemical Reagents(化学试剂), 2015, 37(8): 711.
[5] PENG Lai, ZHU Gui-lin(彭 莱,祝桂林). Journal of Salt Science and Chemical Industry(盐业与化工), 2015, 44(6): 31.
[6] DIAO Xiang-rui, ZHANG Hong-man, ZHANG Jun, et al(刁祥瑞,张洪满,张 君,等). Journal of North University of China(Natural Science Edition)[中北大学学报(自然科学版)], 2011, 32(3): 323.
[7] GE Hong-hua, ZHANG Jia-lin, LI Ji, et al(葛红花,张嘉琳,李 骥,等). Chinese Patent(中国专利):112881315, 2021.
[8] HU Jia-yuan, CAO Shun-an, HAN Jian-wei, et al(胡家元,曹顺安,韩建伟,等). Chinese Patent(中国专利):102062728, 2011.
[9] LI Bing(李 兵). Chinese Society of Electrical Engineering(中国电机工程学会), 2009, 578.
[10] LIANG Hui-bin, DU Zhi-ping, LI En-ze, et al(梁慧斌,杜志平,李恩泽,等). China Surfactant Detergent & Cosmetics(日用化学工业), 2016, (8): 485.
[11] ZHANG Hui-fang, DONG Ming-zhe, DANG Hui-qing, et al(张慧芳,董明哲,党慧卿,等). Chinese Patent(中国专利):114910471, 2021.
[12] Metcalfe L D. Journal of the American Oil Chemists' Society, 1984, 61(2): 363.
[13] Silverstein R M. Analytical Chemistry, 2002, 35(2): 154.
[14] Fang D, Wang Y, Liu H, et al. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2021, 608: 125581.
[15] Nightingale E R JR. The Journal of Physical Chemistry, 1959, 63(9): 1381.
[16] ZHOU Yong-quan, FANG Yan, FANG Chun-hui(周永全,房 艳,房春晖). Journal of Salt Lake Research(盐湖研究), 2010, 18(2): 65.
[17] BAI Chun, LIU Hai-ning, LIU Zhong, et al(柏 春,刘海宁,刘 忠,等). Journal of Salt Lake Research(盐湖研究), 2020, 28(2): 56. |
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