Determination of tantalum, uranium and ytterbium in coal by microwave digestion and high resolution inductively coupled plasma mass spectrometry based on matrix matching
SHEN Jian1,2, WANG Bing2, XU Qianru2, MIN Hong2, ZHANG Linping*1, LIU Shu*2
1. Chemical Engineering and Biotechnology, Key Laboratory of Science and Technology of Eco-Textile, Ministry of Education, Donghua University,Shanghai 201620, China; 2. Technical Center for Industrial Product and Raw Material Inspection and Testing of Shanghai Customs,Shanghai 200135, China
摘要 煤中Ta、U、Yb的测定对煤炭地球化学研究和产地溯源具有重要意义。在采用高分辨电感耦合等离子体质谱(HR-ICP-MS)测定煤中Ta、U、Yb时,基体效应较为严重,导致测定结果偏高。采用8 mL HNO3-1 mL HF微波消解煤炭样品,优化了消解体系、消解程序、复溶时间等前处理条件,选用181Ta、238U、172Yb为测定同位素,采用低分辨率模式测定U,高分辨率模式测定Ta、Yb,以Rh内标结合基体匹配法克服基体效应,实现了煤中Ta、U、Yb的HR-ICP-MS测定。在优化的实验条件下,在1.000~20.00 μg/L范围内,被测元素与内标元素信号强度的比值与被测元素质量浓度呈现良好的线性相关,相关系数不小于0.999 9,各元素的检出限在0.002~0.008 μg/g之间,定量限在0.007~0.027 μg/g之间。将实验方法应用于煤炭标准样品中Ta、U、Yb的测定,测定值与认定值基本一致,相对标准偏差(RSD,n=6)为2.3%~4.3%。选取俄罗斯其他烟煤及无烟煤、澳大利亚其他烟煤、蒙古炼焦煤、印度尼西亚褐煤及其他烟煤6个代表性样品,按照实验方法进行测定,测定结果表明,Ta、U在俄罗斯其他烟煤样品中含量最高,Yb在澳大利亚其他烟煤样品中含量最高,印度尼西亚褐煤中3种元素含量均最低。
Abstract:The determination of Ta, U and Yb in coal is of great significance for coal geochemical research and origin traceability. During the determination of Ta, U and Yb in coal by high resolution inductively coupled plasma mass spectrometry (HR-ICP-MS), the matrix effect was relatively serious, which resulted in higher measurement results. The coal samples were dissolved with 8 mL of HNO3 and 1 mL of HF by microwave digestion. The pretreatment conditions such as digestion system, digestion procedure and resolution time were optimized. 181Ta, 238U and 172Yb were selected as the test isotopes. U was determined at low resolution mode, while Ta and Yb were determined at high resolution mode. The matrix effect was overcome with Rh as internal standard and matrix matching. Consequently, the determination of Ta, U and Yb in coal by HR-ICP-MS was realized. Under the optimized experimental conditions, the ratio of the signal intensity between the analyzed element to the internal standard element showed a good linear relationship with the concentration of the analyzed element in range of 1.000-20.00 μg/L. The correlation coefficient was not less than 0.999 9. The limits of detection were between 0.002 μg/g and 0.008 μg/g, and the limits of quantitation were between 0.007 μg/g and 0.027 μg/g. The experimental method was applied to the determination of Ta, U and Yb in coal certified reference materials, and the results were basically consistent with the certified values. The relative standard deviations (RSD, n=6) were between 2.3% and 4.3%. Six representative coal samples, including other bituminous coal and anthracite from Russian, Australian other bituminous coal, Mongolian coking coal, lignite coal and other bituminous coal from Indonesian, were determined according to the experimental method. The results showed that the contents of Ta and U in Russian other bituminous coal samples were the highest, the content of Yb in Australian other bituminous coal samples was the highest, while the contents of three elements in Indonesian lignite were all the lowest.
沈健, 王兵, 徐倩茹, 闵红, 张琳萍, 刘曙. 微波消解-基体匹配高分辨电感耦合等离子体质谱法测定煤中钽铀镱[J]. 冶金分析, 2022, 42(6): 30-36.
SHEN Jian, WANG Bing, XU Qianru, MIN Hong, ZHANG Linping, LIU Shu. Determination of tantalum, uranium and ytterbium in coal by microwave digestion and high resolution inductively coupled plasma mass spectrometry based on matrix matching. , 2022, 42(6): 30-36.
[1] 马亮帮,张大勇,腾格尔,等.高压密闭消解-电感耦合等离子体质谱(ICP-MS)法测定煤中稀土元素[J].中国无机分析化学,2019,9(4):27-30. MA Liangbang,ZHANG Dayong,BORJIGIN Tenger,et al.Determination of rare elements in coal by inductively coupled plasma-mass spectrometry with high-pressure closed digestion[J].Chinese Journal of Inorganic Analytical Chemistry,2019,9(4):27-30. [2] 孔亚飞,孔贝贝,马真真,等.氧化石墨烯/壳聚糖微球吸附-电感耦合等离子体质谱法测定地质样品中痕量钽[J].分析试验室,2022,41(1):29-32. KONG Yafei,KONG Beibei,MA Zhenzhen,et al.Determination of trace tantalum in geological samples by ICP-MS after extraction on graphene oxide/chitosan beads[J].Chinese Journal of Analysis Laboratory,2022,41(1):29-32. [3] 许菱.用萃取色谱法测定地质样品中的铀和钍[J].国外铀金地质,2001,18(3):176-179. XU Ling.Determination of uranium and thorium in geological samples by extraction chromatography[J].Overseas Uranium and Gold Geology,2001,18(3):176-179. [4] 李艳玲,熊采华,黄慧萍,等.基体分离-电感耦合等离子体质谱测定重晶石中超痕量稀土元素[J].岩矿测试,2005,24(2):87-92. LI Yanlin,XIONG Caihua,HUANG Huiping,et al.Determination of ultra-trace rare earth elements in barite by ICP-MS after matrix spearation[J].Rock and Mineral Analysis,2005,24(2):87-92. [5] Yan X Y,Dai S F,Graham I T,et al.Determination of Eu concentrations in coal, fly ash and sedimentary rocks using a cation exchange resin and inductively coupled plasma mass spectrometry (ICP-MS)[J].International Journal of Coal Geology,2018,191:152-156. [6] DAI Shifeng,SONG Weijiao,ZHAO Lei,et al.Determination of boron in coal using closed-vessel microwave digestion and inductively coupled plasma mass spectrometry (ICP-MS)[J].Energy & Fuels,2014,28(7):4517-4522. [7] 石变芳,刘达,张小满,等.微波消解-ICP-MS法测定煤炭中汞、铍、砷和铀[J].实验室研究与探索,2016,35(11):4-7. SHI Bianfang,LIU Da,ZHANG Xiaoman,et al.Determination of mercury, beryllium, arsenic, and uranium in coal samples by inductively coupled plasma-mass[J].Research and Exploration in Laboratory,2016,35(11):4-7. [8] 任传婷,何姣,汪原伊,等.标准加入法测定纯钯中的杂质元素[J].贵金属,2020,41(S1):172-179. REN Chuanting,HE Jiao,WANG Yuanyi,et al.Determination of impurity elements in pure palladium by standard addition method[J].Precious Metals,2020,41(S1):172-179. [9] 乔娜,包毓含,杨丽,等.基体稀释或基体匹配石墨炉原子吸收光谱法测定土壤样品中铅和镉[J].冶金分析,2019,39(11): 9-15. QIAO Na,BAO Yuhan,YANG Li,et al.Determination of lead and cadmium in soil samples by graphite furnace atomic absorption spectrometry based on matrix dilution or matrix matching[J].Metallurgical Analysis,2019,39(11):9-15. [10] 杨平,邓传东,孙琳,等.电感耦合等离子体原子发射光谱法测定核级铁铬铝合金中10种杂质元素[J].冶金分析,2019,39(11):74-78. YANG Ping,DENG Chuandong,SUN Lin,et al.Determination of ten impurity elements in nuclear grade iron-chromium-aluminum alloy by inductively coupled plasma atomic emission spectrometry[J].Metallurgical Analysis,2019,39(11):74-78. [11] 张玉芹,彭艳,韦时宏,等.高压密闭消解-电感耦合等离子体质谱法测定地质样品中稀土元素[J].实验室研究与探索,2021,40(3):29-32. ZHANG Yuqin,PENG Yan,WEI Shihong,et al.Determiantion of rare earth elements in geological samples by high pressure closed digestion ICP-MS[J].Research and Exploration in Laboratory,2021,40(3):29-32. [12] Robert L Thompson,Tracy Bank,Elliot Roth,et al.Resolution of rare earth element interferences in fossil energy by-product samples using sector-field ICP-MS[J].Fuel,2016,185:94-101. [13] Lieve Balcaen,Eduardo Bolea-Fernandez,Martín Resano,et al.Inductively coupled plasma-tandem mass spectrometry (ICP-MS/MS):a powerful and universal tool for the interference-free determination of (ultra)trace elements-a tutorial review[J].Analytica Chimica Acta,2015,894:7-19. [14] 沈健,赵雨薇,王兵,等.微波消解-高分辨电感耦合等离子体质谱(HR-ICP-MS)法测定煤炭中35种痕量金属元素[J].中国无机分析化学,2022,12(2):26-34. SHEN Jian,ZHAO Yuwei,WANG Bing,et al.Determination of 35 trace metal elements in coal by microwave digestion and high resolution inductively coupled plasma mass spectrometry[J].Chinese Journal of Inorganic Analytical Chemistry,2022,12(2):26-34. [15] Nomvano Mketo,Philiswa N Nomngongo,J Catherine Ngila.An overview on analytical methods for quantitative determination of multi-element in coal samples[J].Trends in Analytical Chemistry,2016,85:107-116. [16] Li X,Dai S F,Zhang W G,et al.Determination of As and Se in coal and coal combustion products using closed vessel microwave digestion and collision/reaction cell technology (CCT) of inductively coupled plasma mass spectrometry(ICP-MS)[J].International Journal of Coal Geology,2014,124(1):1-4. [17] 龚子珊,蒋学慧,杨雨,等.电感耦合等离子体质谱中的基质效应[J].分析测试学报,2020,39(8):1058-1064. GONG Zishan,JIANG Xuehui,YANG Yu,et al.Matrix effects in inductively coupled plasma mass spectrometry[J].Journal of Instrumental Analysis,2020,39(8):1058-1064.
