Determination of fluorine in calcium superphosphate by X-ray fluorescence spectrometry with powder pellet preparation
LIU Lin, WANG Yong*, SHAO Guoqing, SHI Zongyou
Panxi Institute of Vanadium and Titanium Inspection and Testing,National Quality Supervision and Inspection Center of Vanadium and Titanium Products,Panzhihua 617000,China
Abstract:The determination of fluorine content in calcium superphosphate has guiding significance for the production and quality control of calcium superphosphate.In experiments,the samples were thoroughly dried and then crushed until the particle size was less than 74 μm.Boric acid was used for edging,and the sample was prepared at pressure of 35 t for 30 s.F-Kα was selected as the analytical line.The method for the determination of fluorine in calcium superphosphate by wavelength dispersive X-ray fluorescence spectrometry(WDXRF) with powder pellet preparation was established.A large number of calcium superphosphate samples were scanned by X-ray diffraction(XRD).The results showed that the phases in calcium superphosphate were mainly composed of calcium sulfate,calcium fluoride,and silicon dioxide.Therefore,the calcium superphosphate sample which was certified by ion selective electrode method was use as the matrix in experiments.Various amounts of calcium fluoride were added followed by uniform mixing using a three-dimensional sample mixer.A series of calibration samples with a certain gradient of fluorine content that could cover the range of fluorine content in the sample were obtained for the drawing of calibration curves.Therefore,the spectrum peak angles of fluorine in the calibration sample series and calcium superphosphate sample were always consistent.Moreover,the influence of matrix effect and mineral effect on the determination could be reduced.Three calibration samples with different fluorine contents were selected and then mixed with a three-dimensional sample mixer for 5 min.The samples were determined in parallel for five times according to the experimental method.The results showed that the relative standard deviation(RSD,n=5) of the measurement values of fluorescence intensity was less than 3.0%,indicating that the uniformity of the calibration samples could meet the experimental requirements.The calibration curve of fluorine was prepared using the fluorine content as the horizontal axis and the corresponding fluorescence intensity as the vertical axis.The linear correlation coefficient was 0.999 6,and the limit of detection was 3 mg/kg.Three calcium superphosphate samples with different fluorine contents were determined according to the experimental method,and the RSDs (n=10) were between 1.4% and 3.1%.Three samples were also determined by fluoride ion selective electrode method for comparison.The results showed that the determination values of two methods were basically consistent.
刘林, 王勇, 邵国庆, 施宗友. 粉末压片-X射线荧光光谱法测定过磷酸钙中氟[J]. 冶金分析, 2024, 44(4): 45-50.
LIU Lin, WANG Yong, SHAO Guoqing, SHI Zongyou. Determination of fluorine in calcium superphosphate by X-ray fluorescence spectrometry with powder pellet preparation. , 2024, 44(4): 45-50.
[1] 王伟亚.长期施用磷肥对农田土壤氟累积与小麦氟吸收的影响及阻控措施[D].杨凌:西北农林科技大学,2022. [2] 卫士美,王量.氟化物污染对植物的影响[J].农业技术与装备,2015(2):22-23. WEI Shimei,WANG Liang.Effects of fluoride pollution on plants[J].Agricultural Technology & Equipment,2015(2):22-23. [3] 杨柳,李俏,尹韵伊,等.地方性氟中毒病区居民膳食构成对氟骨症患病情况的影响[J].中华地方病学杂志,2023,42(2):87-91. YANG Liu,LI Qiao,YIN Yunyi,et al.Influence of dietary composition of residents in endemic fluorosis area on the prevalence of skeletal fluorosis[J].Chinese Journal of Endemiology,2023,42(2):87-91. [4] 中华人民共和国国家质量监督检验检疫总局,中国国家标准化管理委员会.GB/T 32954—2016 肥料中氟化物的测定:离子选择性电极法[S].北京:中国标准出版社,2016. [5] 吕长宽,唐碧玉,吴琼,等.超声提取-离子色谱法测定钨尾矿中水溶性氟氯和硫酸根[J].冶金分析,2023,43(3):21-26. LÜ Changkuan,TANG Biyu,WU Qiong,et al.Determination of water-soluble fluorine,chlorine and sulfate in tungsten tailing by ion chromatography with ultrasonic extraction[J].Metallurgical Analysis,2023,43(3):21-26. [6] 张晨芳,刘献锋,李墨,等.碱熔-超声提取-离子色谱法测定土壤中总氟化物的含量[J].理化检验(化学分册),2023,59(1):93-97. ZHANG Chenfang,LIU Xianfeng,LI Mo,et al.Determination of total fluoride in soil by ion chromatography after alkali fusion and ultrasound extraction[J].Physical Testing and Chemical Analysis(Part B:Chemical Analysis),2023,59(1):93-97. [7] 王毅民,邓赛文,王祎亚,等.X射线荧光光谱在矿石分析中的应用评介—总论[J].冶金分析,2020,40(10):32-49. WANG Yimin,DENG Saiwen,WANG Yiya,et al.Review on the application of X-ray fluorescence spectrometry in ores′ analysis[J].Metallurgical Analysis,2020,40(10):32-49. [8] 李小莉,李庆霞,安树清,等.X射线荧光光谱法测定土壤样品中的氟[J].分析化学,2019,47(11):1864-1869. LI Xiaoli,LI Qingxia,AN Shuqing,et al.Determination of fluorine in soil sample by X-ray fluorescence spectrometry[J].Chinese Journal of Analytical Chemistry,2019,47(11):1864-1869. [9] 赵文志,张填昊,卢兵,等.粉末压片制样-波长色散X射线荧光光谱法测定土壤和水系沉积物中溴氯氟磷硫[J].冶金分析,2021,41(4):27-33. ZHAO Wenzhi,ZHANG Tianhao,LU Bing,et al.Determination of bromine,chlorine,fluorine,phosphorus and sulfur in soil and stream sediment by wavelength dispersive X-ray fluorescence spectrometry with pressed powder pellet[J].Metallurgical Analysis,2021,41(4):27-33. [10] 刘林,王勇,曾晖,等.粉末压片-波长色散X射线荧光光谱法测定煤中氟[J].冶金分析,2019,39(10):78-82. LIU Lin,WANG Yong,ZENG Hui,et al.Determination of fluorine in coal by wavelength dispersive X-ray fluorescence spectrometry with pressed powder pellet[J].Metallurgical Analysis,2019,39(10):78-82. [11] 白万里,李小艳,马艳红.X射线荧光光谱法测定氟化铝元素组分影响因素探讨[J].轻金属,2020(8):49-54. BAI Wanli,LI Xiaoyan,MA Yanhong.Discussion on the determination of elemental constituent in aluminum fluoride by X-ray fluorescence spectrometry[J].Light Metals,2020(8):49-54. [12] 曾江萍,李小莉,张楠,等.粉末压片制样-X射线荧光光谱法测定锂云母中的高含量氟[J].岩矿测试,2019,38(1):71-76. ZENG Jiangping,LI Xiaoli,ZHANG Nan,et al.Determination of high concentration of fluorine in lithium mica by X-ray fluorescence spectrometry with pressed-powder pellets[J].Rock and Mineral Analysis,2019,38(1):71-76. [13] 袁永海,杨锋,吴杰,等.含钙乙酸分离-熔融制样-X射线荧光光谱法测定萤石中氟化钙[J].冶金分析,2023, 43(3):34-39. YUAN Yonghai,YANG Feng,WU Jie,et al.Determination of calcium fluoride in fluorite by X-ray fluorescence spectrometry with fusion sample preparation after separation by calcium-containing acetic acid[J].Metallurgical Analysis,2023,43(3):34-39.
