Determination of partition amount of praseodymium, neodymium and gadolinium in praseodymium-neodymium-gadolinium alloy by inductively coupled plasma atomic emission spectrometry
WANG Su-mei1,2, GAO Wa1,2, HAO Qian1,2, YU Ya-hui1,2
1. State Key Laboratory of Rare Earth Resources Research and Comprehensive Utilization, Baotou Research Institute of Rare earths, Baotou 014030, China; 2. Ruike National Engineering Research Center of Rare Earth Metallurgy and Functional Materials, Baotou 014030, China
Abstract:Praseodymium-neodymium-gadolinium metal is a new material of neodymium-iron-boron alloy. It has some advantages such as low harmful elements content, stable product composition and low cost. The rapid and accurate determination of partition amount of praseodymium, neodymium and gadolinium in praseodymium-neodymium-gadolinium alloy is of great importance to the product quality control. The samples were dissolved with nitric acid. Pr 418.948nm, Nd 445.156nm and Gd 342.246nm were selected as the analytical lines. The partition amount of praseodymium,neodymium and gadolinium in praseodymium-neodymium-gadolinium alloy was determined by inductively coupled plasma atomic emission spectrometry (ICP-AES) under the optimal analysis conditions of instrument. The effect of sample dissolution condition and coexisting element interference on the determination was discussed. The results showed that the carbide and nitride inclusions in praseodymium-neodymium-gadolinium alloy could be easily dissolved with nitric acid. The influence of coexisting rare earth elements and non-rare earth elements (including iron, calcium, magnesium, aluminum, silicon, molybdenum and tungsten) in sample on the determination of praseodymium, neodymium and gadolinium could be ignored. The proposed method was applied for the determination of partition amount of praseodymium, neodymium and gadolinium in three praseodymium-neodymium-gadolinium alloy samples. The relative standard deviations (RSD, n=11) of determination results were between 0.070% and 0.56%. The partition amount of praseodymium, neodymium and gadolinium in internal control standard sample of praseodymium-neodymium-gadolinium alloy was determined according to the experimental method as well as X-ray fluorescence spectrometry (XRF). The found results of two methods were consistent.
陈国华,曹永存,刘玉宝,等.熔盐电解法制备镨钕钆合金的研究[J].中国稀土学报,2015(2):206-210.CHEN Guo-hua,CAO Yong-cun,LIU Yu-bao,et al.Preparation of Pr-Nd-Gd alloys by molten salt electrolysis[J].Journal of the Chinese Society of Rare Earths,2015(2):206-210.
[2]
阮桂色.电感耦合等离子体原子发射光谱(ICP-AES)技术的应用进展[J].中国无机分析化学,2011,1(4):15-18.RUAN Gui-se.Development and application of inductivelycoupled plasma atomic emission sepctrometry[J].Chinese Journal of Inorganic Analytical Chemistry,2011,1(4):15-18.
[3]
石景燕,李振海.电感耦合等离子体发射光谱法在化学分析中的应用[J].河北电力技术,2003(22):43-44.SHI Jing-yan,LI Zhen-hai.Application of inductively coupled plasma atomic emission spectroscopy in chemistry analysis[J].Hebei Electric Power Technology,2003(22):43-44.
[4]
沙伟南,黄志荣,王春红,等.氧化铕无基体匹配ICP摄谱定量分析方法的研究[J].分析试验室,1993,12(5):16-21.SHA Wei-nan,HUANG Zhi-rong,WANG Chun-hong,et al.Study on quantitative analysis method of europium oxide without matrix matching ICP photogrammetry[J].Analytical Laboratory,1993,12(5):16-21.
[5]
张国文,张涵,刘永华,等.稀土矿区茶叶中稀土元素ICP-AES测定[J].光谱学与光谱分析,1997(1):74-78.ZHANG Guo-wen,ZHANG Han,LIU Yong-hua,et al.Simultaneous determination of rare earth in rare earth ore band tea-leaves by ICP-AES[J].Spectroscopy and Spectral Analysis,1997(1):74-78.
[6]
吴波英,黄少文.ICP-AES在稀土元素分析中的抗干扰技术的应用及进展[J].稀土,2005(5):17-22.WU Bo-ying,HUANG Shao-wen.Application and progress of anti-interference technology of ICP-AES in rare eath element analysis[J].Chinese Rare Earths,2005(5):17-22.
[7]
续建敏.ICP-AES对稀土矿石中稀土氧化物总量的测定方法的研究[J].四川建材,2012,38(3):93-101.XU Jian-min.Study on ICP-AES method for determination of total rare earth oxides content in rare earth ores[J].Sichuan Building Materials,2012,38(3):93-101.
[8]
刘晓杰,杜梅,崔爱端,等.ICP-AES法测定镝铁合金中稀土杂质[J].稀土,2011,32(5):78-82.LIU Xiao-jie,DU Mei,CUI Ai-duan,et al.Determination of rare earth impurity in Dy-Fe alloy by ICP-AES[J].Chinese Rare Earths,2011,32(5):78-82.
[9]
杜梅,刘晓杰.电感耦合等离子体发射光谱法测定包头稀土矿中的稀土总量[J].岩矿测试,2014,33(2):218-223.DU Mei,LIU Xiao-jie.Determination of total rare earth contents of Baotou rare earth concentrates by inductively coupled plasma atomic emission spectroscopy[J].Rock and Mineral Analysis,2014,33(2):218-223.
[10]
许涛,崔爱端,杜梅.电感耦合等离子体发射光谱法测定稀土铌钽矿中稀土元素和钍量[J].岩矿测试,2009,28(6):549-552.XU Tao,CUI Ai-duan,DU Mei.Determination of rare earth elements and thorium in RE-Nb-Ta ores by inductively coupled plasma atomic emission spectroscopy[J].Rock and Mineral Analysis,2009,28(6):549-552.
[11]
刘晓杰,李玉梅,刘丽静.电感耦合等离子体发射光谱法测定稀土矿石中的三氧化二铝[J].岩矿测试,2013,32(3):436-440.LIU Xiao-jie,LI Yu-mei,LIU Li-jing.Determination of aluminium oxide content in rare earth ores by inductively coupled plasma atomic emission spectroscopy[J].Rock and Mineral Analysis,2013,32(3):436-440.
[12]
张秀艳,常诚,赵静.电感耦合等离子体原子发射光谱法测定铈铁合金中铝硅镍[J].冶金分析,2018,38(9):89-93.ZHANG Xiu-yan,CHANG Cheng,ZHAO Jing.Determination of Al,Si,Ni in cerium-iron alloy by inductively coupled plasma atomic emission spectroscopy[J].Metallurgical Analysis,2018,38(9):89-93.
[13]
温世杰,周俊海,张少夫.电感耦合等离子体原子发射光谱法测定钇铁合金中铝硅钙镁锰[J].有色金属科学与工程,2016,7(1):133-136.WEN Shi-jie,ZHOU Jun-hai,ZHANG Shao-fu.Determination of Al,Si,Ca,Mg,Mn in yttrium-iron alloy by inductively coupled plasma atomic emission spectroscopy[J].Nonferrous Metals Science and Engineering,2016,7(1):133-136.
[14]
崔爱端,张秀燕.ICP-AES法测定镨钕氧化物及镨钕金属中的镧、铈、钐、钇、铝和硅量[J].稀土,2006,27(4):75-77.CUI Ai-duan,ZHANG Xiu-yan.ICP-AES detecting method for La,Ce,Sm,Y,Al and Si in Pr-Nd oxide and metal[J].China Rare Earth,2006,27(4):75-77.
[15]
刘晓杰,杜梅,崔爱端,等.等离子光谱法测定稀土矿石中钍[J].稀土,2007,28(1):63-65.LIU Xiao-jie,DU Mei,CUI Ai-duan,et al.Determination of thorium in rare earth ore by ICP-AES[J].China Rare Earth,2007,28(1):63-65.
