Determination of lanthanum oxide,cerium oxide and silicon dioxide in rare earth selective catalytic reduction (SCR) denitration catalysts by alkali fusion-inductively coupled plasma atomic emission spectrometry
YU Yahui1,2,3, MU Baowei4, CUI Kailu1,2,3, ZHANG Huizhen1,2,3, WANG Sumei*1,2,3
1. National Key Laboratory of Baiyunobo Rare Earth Resource Researches and Comprehensive Utilization,Baotou 014030,China; 2. Baotou Research Institute of Rare Earths,Baotou 014030,China; 3. Ruike National Engineering Research Centre of Rare Earth Metallurgy and Functional Materials,Baotou 014030,China; 4. Department of Chemistry,Baotou Teachers' College,Baotou 014010,China
Abstract:Rare earth selective catalytic reduction (SCR) denitration catalysts have been widely used in denitration system. The chemical composition proportion is one of important bases for the performance judgment. Therefore, it is very necessary to develop a method for the determination of lanthanum oxide, cerium oxide and silicon dioxide in rare earth SCR denitration catalysts. These catalyst products contain tungsten and titanium with high temperature resistance and high hardness, which are hardly decomposed by the conventional acid dissolution method. In this study, the sample was melted with sodium hydroxide and sodium peroxide. The orthogonal condition experiments of L16 (45) were carried out on the flux dosage, melting temperature, melting time and the amount of hydrochloric acid for leaching. The optimal conditions for sample pretreatment were obtained as follows: 1.5 g of sodium hydroxide and 3.0 g of sodium peroxide were used as the flux, the melting temperature was 850 ℃, the melting time was 15 min, and the dosage of hydrochloric acid for leaching was 25 mL. La 333.749 nm, Ce 446.021 nm and Si 251.611 nm were selected as the analytical lines. When the mass concentration of Na+ in sample solution was not more than 2.0 mg/mL, the recoveries of elements were between 95.3% and 100%. Therefore, the solution was diluted for 10 times in experiments, and the concentration of Na+ in the solution was about 1.5 mg/mL. The influence of coexisting elements on the measurement results could be negligible. Finally, the method for the determination of lanthanum oxide, cerium oxide and silicon dioxide in rare earth SCR denitration catalysts by inductively coupled plasma atomic emission spectrometry (ICP-AES) was established. The linear correlation coefficients of calibration curves for lanthanum oxide, cerium oxide and silicon dioxide were all 0.999 9. The limits of detection for lanthanum oxide, cerium oxide and silicon dioxide were 0.009 0 μg/mL, 0.008 7 μg/mL, and 0.069 μg/mL, respectively. The limits of quantification for lanthanum oxide, cerium oxide and silicon dioxide were 0.024%, 0.023%, and 0.18%, respectively. The contents of lanthanum oxide, cerium oxide and silicon dioxide in rare earth SCR denitration catalysts were determined according to the experimental method. The relative standard deviations (RSD, n=11) of determination results were between 0.007% and 0.74%, and the recoveries were between 99.4% and 100%. The contents of lanthanum oxide, cerium oxide and silicon dioxide in rare earth SCR denitration catalysts were determined according to the experimental method and X-ray fluorescence spectroscopy (XRF), and the found results were consistent.
[1] 蔡丽娟,王大忠,唐小芩,等. 草酸盐重量法测氟碳铈矿中稀土含量[J].山东化工,2021,50(16):139,142. CAI Lijuan,WANG Dazhong,TANG Xiaoqin,et al.Determination of rare earth content in bastnaesite by oxalate gravimetric method[J].Shandong Chemical Industry,2021,50(16):139,142. [2] 刘春,张慧珍,张翼明,等.草酸盐重量法和电感耦合等离子体原子发射光谱法相结合测定钇铝合金中钇[J].冶金分析,2020,40(2):24-28. LIU Chun,ZHANG Huizhen,ZHANG Yiming,et al.Determination of yttrium in yttrium-aluminum alloy by oxalate gravimetry and inductively coupled plasma atomic emission spectrometry[J].Metallurgical Analysis,2020,40(2):24-28. [3] 龙旭东,高立红,张红,等.EDTA滴定法测定稀土铝中间合金中稀土总量[J].冶金分析,2020,40(4):70-75. LONG Xudong,GAO Lihong,ZHANG Hong,et al.Determination of total rare earths in intermediate alloy of rare earth aluminum by EDTA titration[J]. Metallurgical Analysis,2020,40(4):70-75. [4] 于亚辉,许涛,刘晓杰,等.酸溶法测定稀土抛光粉废粉中的稀土总量[J].稀土,2015,36(2):82-85. YU Yahui,XU Tao,LIU Xiaojie,et al.Determination of total rare earths in waste rare earth polishing powder-oxalate gravimetric method[J].Chinese Rare Earths,2015,36(2):82-85. [5] 温世杰,陈绯宇.镧铁合金中14项稀土杂质含量的测定——电感耦合等离子体发射光谱法[J].有色金属科学与工程,2021,12(6):123-134. WEN Shijie,CHEN Feiyu.Determination of 14 rare earth lmpurities in lanthanum-iron alloy by inductively coupled plasma optical emission spectrometry[J].Nonferrous Metals Science and Engineering,2021,12(6):123-134. [6] 刘春,高励珍,张翼明,等.电感耦合等离子体发射光谱法测定镨钕钆合金中稀土杂质量[J].金属功能材料,2021,28(4):59-63. LIU Chun,GAO Lizhen,ZHANG Yiming,et al.Determination of rare earth impurities in praseodymium-neodymium-gadolinium alloy by coupled plasma atomic emission spectrometry[J].Metallic Functional Materials,2021,28(4):59-63. [7] 王素梅,高娃,郝茜,等.电感耦合等离子体原子发射光谱法测定镨钕钆合金中镨钕钆配分量[J].冶金分析,2020,40(5):52-56. WANG Sumei,GAO Wa,HAO Qian,et al.Determination of partition amount of praseodymium,neodymium and gadolinium in praseodymium-neodymium-gadolinium alloy by inductively coupled plasma atomic emission spectrometry[J].Metallurgical Analysis,2020,40(5):52-56. [8] 郭宏杰,李辉,张庸.电感耦合等离子体发射光谱(ICP-OES)法测定稀土钢中微量镧、铈[J].中国无机分析化学,2021,11(3):75-78. GUO Hongjie,LI Hui,ZHANG Yong.Determination of trace lanthanum and cerium in rare earth steel by inductively coupled plasma optical emission spectrometry[J]. Chinese Journal of Inorganic Analytical Chemistry,2021,11(3):75-78. [9] 李甜,刘丽媛,王雪菲,等.沉淀分离-电感耦合等离子体原子发射光谱法测定稀土钨电极中镧铈钇[J].冶金分析,2020,40(3):32-36. LI Tian,LIU Liyuan,WANG Xuefei, et al.Determination of lanthanum,cerium and yttrium in rare-earth tungsten electrode by inductively coupled plasma atomic emission spectrometry with precipitation separation[J].Metallurgical Analysis,2020,40(3):32-36. [10] 唐清,黄葡英,李雨.硅钼蓝分光光度法测定铝钛硼合金中硅[J].冶金分析,2022,42(5):43-47. TANG Qing,HUANG Puying,LI Yu.Determination of silicon in aluminum-titanium-boron alloybysilicon molybdenum blue spectrophotometry[J]. Metallurgical Analysis,2022,42(5):43-47. [11] 丁艳,王恒,孙剑,等.钼蓝分光光度法测定银精矿中的二氧化硅[J].广东化工,2021,48(24):166-168. DING Yan,WANG Heng,SUN Jian,et al.Determination of silicon dioxide content in silver concentrates by molybdenum blue spectrophotometry[J]. Guangdong Chemical Industry,2021,48(24):166-168. [12] 程钱夏.硅钼蓝分光光度法测渣精矿中二氧化硅含量[J].铜业工程,2021(2):76-79. CHENG Qianxia.Determination of silica content in slag concentrate by silicomolybdic blue spectrophotometry[J].Copper Engineering,2021(2):76-79. [13] 王丽娟,于亚辉,赵拓,等.高氯酸脱水重量法结合钼蓝分光光度法测定富钾板岩中二氧化硅[J].冶金分析,2021,41(2):72-77. WANG Lijuan,YU Yahui,ZHAO Tuo,et al.Determination of silicon dioxide in potassium-rich slate by perchloric acid dehydration gravimetric method combined with molybdenum blue spectrophotometry[J]. Metallurgical Analysis,2021,41(2):72-77. [14] 吴俊,李策,任小荣,等.电感耦合等离子体原子发射光谱法测定多金属矿中二氧化硅[J].冶金分析,2022,42(2):33-39. WU Jun,LI Ce,REN Xiaorong,et al.Determination of silicon dioxide in polymetallic ore by inductively coupled plasma atomic emission spectrometry[J].Metallurgical Analysis,2022,42(2):33-39. [15] 高玉花,宋传洪,张同生,等.低温密闭碱熔-电感耦合等离子体发射光谱法测定岩石矿物中二氧化硅[J].化学分析计量,2021,30(10):42-45. GAO Yuhua,SONG Chuanhong,ZHANG Tongsheng,et al.Determination of silicon dioxide in rock and minerals by inductively coupled plasma emission spectrometry with low temperature sealed alkali fusion[J].Chemical Analysis and Meterage,2021,30(10):42-45. [16] 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 34700—2017 稀土型选择性催化还原(SCR)脱硝催化剂[S].北京:中国标准出版社,2017. [17] 晏敏,杜振,宋小宁,等. SCR脱硝催化剂主要化学成分的检测解析[J].环境工程,2019,37(6):22-25. YAN Min,DU Zhen,SONG Xiaoning,et al.Analysis on detection of mainchemical compositions of SCR denitrification catalysts[J].Environmental Engineering,2019,37(6):22-25. [18] 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 31590—2015 烟气脱硝催化剂化学成分分析方法[S].北京:中国标准出版社,2015. [19] 国家市场监督管理总局,中国国家标准化管理委员会.GB/T 38219—2019 烟气脱硝催化剂检测技术规范[S].北京:中国标准出版社,2019.
