Determination of eight impurity components in high-quality quartz sand by inductively coupled plasma atomic emission spectrometry-internal standard method
Abstract:The main component of high-quality quartz sand is SiO2. The content of impurities in high-quality quartz sand affects its quality directly. The traditional measurement methods of impurities include spectrophotometry and atomic absorption spectrometry. However, these methods have some disadvantages such as long process and inability for simultaneous determination of multi-components, which difficult to meet the actual detection requirements. The sample was decomposed using hydrofluoric acid, nitric acid and perchloric acid. The standard solution of indium was added as the internal standard to simplify the experimental process. The determination errors caused by matrix effect, instrument drift and inaccurate constant volume were eliminated. A method for the determination of eight impurities (including Al2O3, Fe2O3, TiO2, CaO, MgO, K2O, Na2O and P2O5) in high-quality quartz sand by inductively coupled plasma atomic emission spectrometry (ICP-AES)-internal standard method was established. The linear correlation coefficients of calibration curves within linear range were between 0.9994 and 1.0000. The limit of detection of each component was in range of 0.0001%-0.0038% (mass fraction). The components in national standard material (GBW07837) were determined according to the experimental method, and the relative standard deviations (RSD, n=12) of results were between 0.92% and 6.6%. The found results were consistent with the certified values. Eight components in actual sample of high-quality quartz sand were determined according to the experimental method. The RSDs (n=6) were between 0.59% and 8.1%, and the determination results were basically consistent with the reference values.
庞衍军,林光汉,杨玉英.广西沿岸石英砂矿特征及其资源保护[J].广西科学院学报,1991,7(2):23-30.PANG Yan-jun,LIN Guang-han,YANG Yu-ying.The character and resources protection of quartz-sand mine in Guangxi seaboard [J].Journal of Guangxi Academy of Sciences,1991,7(2):23-30.
[2]
蒋晓光,林忠,李卫刚.X-射线荧光光谱法测定硅石中主次成分[J].冶金分析,2008,28(10):31-35.JIANG Xiao-guang,LIN Zhong,LI Wei-gang.Determination of major and minor components in silica by X-ray fluorescence spectrometry[J].Metallurgical Analysis,2008,28(10):31-35.
[3]
刘艳,曾静,胡军凯,等.X射线荧光光谱法测定含金石英石中7种成分[J].岩矿测试,2011,30(5):580-583.LIU Yan,ZENG Jing,HU Jun-kai,et al.Determination of seven components in gold-bearing quartz by X-ray fluorescence spectrometry[J].Rock and Mineral Analysis,2011,30(5):580-583.
[4]
蔡玉斌,陈苔,金骏,等.XRF玻璃熔片法测定石英砂主次痕量组分[J].光谱实验室,2012,29(6):3470-3473.CAI Yu-bin,CHEN Tai,JIN Jun,et al.Determination of primay and secondary trace components in quartz sand samples by XRF with melting glass[J].Chinese Journal of Spectroscopy Laboratory,2012,29(6):3470-3473.
[5]
马景治,贾海峰,兰绿灯,等.X射线荧光光谱法测定硅石中主次量元素组分[J].中国无机分析化学,2017,7(2):55-58.MA Jing-zhi,JIA Hai-feng,LAN Lü-deng,et al.Simultaneous determination of major and minor components in silica samples by XRF[J].Chinese Journal of Inorganic Analytical Chemistry,2017,7(2):55-58.
[6]
蔚志毅,薛福林,张万智.熔融法XRF测定地质样品中石英岩中的主、次量元素[J].化学工程师,2017,31(2):35-37.WEI Zhi-yi,XUE Fu-lin,ZHANG Wan-zhi.Determination of the principal and secondary elements in the quartz in the geological samples by XRF[J].Chemical Engineer,2017,31(2):35-37.
[7]
顾晓庆,袁钢,项威,等.ICP-MS检测石英砂中多种微量金属元素的含量[J].广东化工,2018,45(17):171-172.GU Xiao-qing,YUAN Gang,XIANG Wei,et al.Determination the content of various trace metal elements in silica sand by ICP-MS[J].Guangdong Chemical Industry,2018,45(17):171-172.
[8]
魏晶晶,薛秋红,刘心同,等.电感耦合等离子体发射光谱法测定石英砂中15种杂质元素[J].岩矿测试,2011,30(3):310-314.WEI Jing-jing,XUE Qiu-hong,LIU Xin-tong,et al.Determination of 15 impurity elements in quartz sand by inductively coupled plasma-atomic emission spectrometry[J].Rock and Mineral Analysis,2011,30(3):310-314.
[9]
杭义萍,谢增春,吴彩云.ICP-AES同时测定高纯石英砂中硼和磷含量[J].光谱实验室,2010(4):1503-1506.HANG Yi-ping,XIE Zeng-chun,WU Cai-yun.Simultaneous determination of boron and phosphorus in purifying high grade quartz sand by ICP-AES[J].Chinese Journal of Spectroscopy Laboratory,2010(4):1503-1506.
[10]
李万春.ICP-AES法同时测定石英砂中的痕量元素[J].分析试验室,2002,21(5):83-85.LI Wan-chun.Simultaneous determination of trace elements in quartz sand by ICP-AES[J].Chinese Journal of Analysis Laboratory,2002,21(5):83-85.
[11]
张云晖,杨晓静,亢若谷,等.电感耦合等离子体原子发射光谱法测定工业硅中8种杂质元素[J].冶金分析,2013,33(2):55-59.ZHANG Yun-hui,YANG Xiao-jing,KANG Ruo-gu,et al.Determination of eight impurity elements in industrial silicon by inductively coupled plasma atomic emission spectrometry[J].Metallurgical Analysis,2013,33(2):55-59.
[12]
代建强.电感耦合等离子体原子发射光谱法测定石英岩中杂质元素[J].安阳工学院学报,2012,11(6):31-33.DAI Jian-qiang.Simultaneous determination of the common impurity elements in quartzite rock by inductively coupled plasma atomic emission spectrometry[J].Journal of Anyang Institute of Technology,2012,11(6):31-33.
[13]
龙纪群,杨刚,陈菊.ICP-AES法测定硅石样品中多种杂质元素[J].贵州地质,2008,25(3):236-238.LONG Ji-qun,YANG Gang,CHEN Ju.ICP-AES determination of multi-impurity elements in geologic sample:silica[J].Guizhou Geology,2008,25(3):236-238.
[14]
张爱芬,马慧侠,李国会.X射线荧光光谱法测定铝矿石中主次痕量组分[J].岩矿测试,2005,24(4):307-310.ZHANG Ai-fen,MA Hui-xia,LI Guo-hui.Determination of major,minor and trace elements in bauxite by XRF spectrometry[J].Rock and Mineral Analysis,2005,24(4):307-310.
[15]
陆安军,苏梦晓.波长色散X射线荧光光谱法测定中低品位铝土矿和高硫铝土矿中主次组分[J].冶金分析,2019,39(4):53-59.LU An-jun;SU Meng-xiao.Determination of major and minor components in medium-low grade bauxite and high-sulfur bauxite by wavelength dispersive X-ray fluorescence spectrometry[J].Metallurgical Analysis,2019,39(4):53-59.
[16]
曾静,胡军凯,冯朝军.电感耦合等离子体原子发射光谱-内标法测定铜精矿中镉[J].冶金分析,2017,37(3):58-63.ZENG Jing,HU Jun-kai,FENG Zhao-jun.Determination of cadmium in copper concentrate by inductively coupled plasma atomic emission spectrometry combined with internal standard method[J].Metallurgical Analysis,2017,37(3):58-63.
[17]
冯朝军,曾静.电感耦合等离子体原子发射光谱法测定金精矿中铅、锌、铋、镉、铬、砷含量[J].资源环境与工程,2016,30(6):1027-1030.FENG Chao-jun,ZENG Jing.Determination of Pb,Zn,Bi,Cd,Cr,As in gold concentrate by ICP-AES[J].Resources Environment & Engineering,2016,30(6):1027-1030.
[18]
刘烽,吴骋,吴广宇,等.微波消解-电感耦合等离子体原子发射光谱法测定高镍铸铁中硅锰磷铬镍铜[J].冶金分析,2018,38(5):78-82.LIU Feng,WU Cheng,WU Guang-yu,et al.Determination of silicon,manganese,phosphorus,chromium,nickel and copper in high nickel cast iron by inductively coupled plasma atomic emission spectrometry after microwave digestion[J].Metallurgical Analysis,2018,38(5):78-82.
[19]
徐金玲,李力,王荣.ICP-AES法同时测定锂离子正极材料钴酸锂的杂质元素[J].矿冶工程,2009,29(3):75-77.XU Jin-ling,LI Li,WANG Rong.Measurement of impurity elements in the positive electrode material LiCoO2 for lithium battery by ICP-AES method[J].Mining and Metallurgical Engineering,2009,29(3):75-77.
[20]
汪灵,李彩侠,王艳,等.高纯石英质量的ICP检测技术研究与应用[J].光谱学与光谱分析,2013(6):1684-1688.WANG Ling,LI Cai-xia,WANG Yan,et al.Research on and application of the ICP detection technology for the quality of high-purity quartz[J].Spectroscopy and Spectral Analysis,2013(6):1684-1688.
[21]
刘加威,李京伟,白枭龙,等.石英砂ICP-OES测试溶样方法对比研究:酸溶法和碱熔法[J].化学工程师,2017,31(4):21-24.LIU Jia-wei,LI Jing-wei,BAI Xiao-long,et al.Research on comparing the sample digestion methods for ICP-OES testing quartz sand:acid sissolution and alkali fusion[J].Chemical Engineer,2017,31(4):21-24.
[22]
李献华,刘颖,涂湘林,等.硅酸盐岩石化学组成的ICP-AES和ICP-MS准确测定:酸溶与碱熔分解样品方法的对比[J].地球化学,2002,31(3):289-294.LI Xian-hua,LIU Ying,TU Xiang-lin,et al.Precise determination of chemical compositions in silicate rocks using ICP-AES and ICP-MS:A comparative study of sample digestion techniques of alkali fusion and acid dissolution[J].Geochimica,2002,31(3):289-294.
