钕基体效应对电感耦合等离子体发射光谱法测定9种微量金属杂质的影响

研究了钕基体效应对电感耦合等离子体发射光谱法测定钕中9种微量金属杂质元素(Na、Mg、Al、K、Ca、Fe、Cr、Zn、Cu)的影响.通过对比筛选多条谱线确定了钕基体中各元素的优选分析谱线,溶液体系酸度影响研究发现酸度对钕基体溶液中各元素强度影响较小,研究了基体浓度对每一个杂质元素谱峰强度和含量测试影响程度及趋势.当钕...     

端视等离子体原子发射光谱法中内标法校正钠基体干扰

端视电感耦合等离子体原子发射光谱在分析过程中易电离元素引起的非光谱干扰 ,常常使分析结果产生偏差。就不同浓度Na基体对分析谱线产生的干扰进行了实验和研究 ,并用Y作为内标元素来补偿钠基体的干扰。得出在Robust条件 ,即高功率和低载气流速条件下 ,选择合适的离子线 ,并且离子线的总能量大于 10eV下 ,用内标Y 4 37.4 94nm可以很好的补偿不同Na含量的干扰。     

液体阴极辉光放电原子发射光谱法分析硅酸钇镥中痕量杂质元素

采用液体阴极辉光放电原子发射光谱( Solution-cathode glow discharge-atomic emission spectrometry, SCGD-AES)法测定了硅酸钇镥(Lutetium-Yttrium Orthosilicate, LYSO)闪烁晶体材料中痕量元素 Ca,Fe, K, Li, Mg和Na。最佳实验条件是溶液pH为1的HNO3,直流电压为1080 V,溶液流速为2.0 mL/min。本方法对LYSO基体的耐盐量为10 g/L。硅酸钇镥晶体使用HNO3, HF, HClO4溶解后经SCGD-AES分析测定,结果同电感耦合等离子体发射光谱( Inductively coupled plasma-atomic emission spectroscopy, ICP-AES)和电感耦合等离子体质谱( Inductively coupled plasma-mass spectroscopy, ICP-MS)分析结果比对,具有较好的一致性。在运用SCGD-AES对LYSO的测定中,未观察到Lu、Y元素的激发谱线,因此测定LYSO中痕量元素时测定的光谱干扰少,Ca, Fe, K, Li, Mg和Na的检出限分别为：1.0,3.0,0.02,0.01,0.02和1.0 mg/kg。     

改性Y分子筛的酸碱性能及吸附性能的研究

吡啶、吡咯、苯、甲苯、乙苯作为探针分子，在Li＋, Na＋, K＋, Cs＋改性的Y型分子筛上进行吸附，用TPD及IR方法系统地研究了不同碱金属离子改性的Y型分子筛的酸碱性能和吸附性能的变化. 结果表明，按Li、Na、K、Cs的顺序, 随着碱金属离子半径的增大, 其L酸酸强度依次减弱，L碱的强度逐渐增强.由于改性Y型分子筛所含碱金属离子的不同，其对芳烃的吸附的强弱及吸附量的大小亦不同.随着骨架外的阳离子的半径逐渐增大，碱的强度逐渐增强，与芳烃的作用愈强烈，导致TPD脱附峰温增高及芳烃和侧链上的C－H伸缩振动谱带向低波数位移愈多.由于位阻的原因，对含同一种碱金属离子的分子筛来说，随着芳烃侧链C数的增加，芳烃的吸附量逐渐减小.     

端视等离子体原子发射光谱法中内标法校正的钠基体干扰

端视电感耦合等离子体原子发射光谱在分析过程中易电离元素引起的非光谱干扰，常常使分析结果产生偏差，就不同浓度Na基体对分析谱线产生的干扰进行了实验和研究，并用Y作为内标元素来补偿钠基体的干扰。得出在Robust条件，即高功率和低载气流速条件下，选择合适的离子线，并且离子线的总能量大于10eV下，用内标Y437.494nm可以很好的补偿不同Na含量的干扰。     

微量进样/ICP-MS体系中的基体效应研究

考察了自行组装的高效微量进样系统在22μL/min低提升量下电感耦合等离子体质谱的基体效应.质量数和电离电位不同的基体元素质量浓度为2g/L时,低质量数分析元素受到一定的干扰,而对于高质量数分析元素,其信号几乎不受基体元素干扰,归一化信号值接近1.对于体积分数为5%的有机基体样品溶液,此微量高效雾化系统测得的归一化信号值多接近0.5.实际样品中常见的基体元素K,Na,Ca和Mg质量浓度低于500mg/L,以及乙醇和乙酸体积分数小于1%时,微量进样系统均不产生显著干扰.     

生物质气化过程中碱金属和碱土金属的析出特性研究

研究了固定床上生物质及热解焦CO2气化过程中碱金属及碱土金属(AAEMs)的析出特性。利用原子吸收光谱仪,考察了不同生物质种类、不同热解制焦温度对AAEMs析出的影响。不同生物质由于其挥发分含量不同引起气化失重率的差异,焦气化活性随制焦温度升高而降低。生物质及焦气化过程中Na析出率最大,其次是K,碱土金属析出率低于碱金属,这与元素在生物质中的存在形式、金属价态有关。低温段K的析出率随热解制焦温度的提高而增加,而Na在热解与气化段总的析出率与制焦温度关系不大。生物质的种类尤其是灰中的Si含量对Ca和Mg的析出影响较大,气化效率高的生物质AAEMs析出较多。热力学计算结果显示,气化过程中Na、K多以氯化物的形式存在并析出,Ca、Mg则更倾向于形成硅酸化合物而不易析出。     

不同预处理方法对准东高碱煤中碱金属含量测定的影响

以四种不同的准东高碱煤及气化飞灰为研究对象,对高碱煤及气化飞灰中碱金属(Na、K)的赋存形态,以及不同预处理方法(低温灰化法、直接消解法、中国国标法、萃取法及氧弹燃烧法)对准东高碱煤及气化飞灰中碱金属(Na、K)含量测定的影响进行了测试分析。结果表明,准东高碱煤中碱金属Na主要以水溶态形式存在,碱金属K主要以水不溶态形式存在;不同的预处理方法对准东高碱煤中碱金属(Na、K)含量的测定结果影响显著,对于准东高碱煤及气化飞灰中碱金属(Na、K)含量测定,建议采用氧弹燃烧法,萃取法也可以相对准确地反映煤中碱金属Na的含量。     

微波等离子体原子发射光谱新技术同时测定环境水样中多种元素

环境水样经不同酸消解后,利用微波等离子体原子发射光谱法(MP-AES)和多模式样品导入系统(MSIS)对环境水样中可蒸气发生元素(As,Hg,Sb和Se)及重金属元素(Cd,Cu,Cr,Ni,Pb,Ti,V和Zn)同时分析,分别根据溶液中元素信号强度变化和测定值与加标值差异,优化氢化物发生条件和考察测定的基体及谱线干扰影响.结果表明,在还原剂溶液(1.0％ NaBH4,m/V)和载流HCl(5％,V/V)的最佳实验浓度下,相比HC1消解,水样经HNO3消解可获得满意分析结果;环境标准样品中元素测定值与标准值一致,样品分析相对标准偏差在0.34％ ～ 3.2％范围内.高浓度的K,Ca,Na和Mg等元素对测定无明显影响,稀土元素和稀有元素对重金属光谱干扰严重,需选择合适谱线分析.本方法除对Hg和Se的检出限稍高外(6.5和37.1μg/L),其它目标元素检出限为1.6～9.8μg/L,能够满足地表水环境质量标准和生活饮用水卫生标准的质量控制要求.     

碱金属离子对Fe(phen)3/Y催化氧化性能的影响

采用自由配体法,将铁邻菲啰啉(Fe(phen)3)配合物封装在含有不同碱金属阳离子的Y型分子筛中,制备了系列Fe(phen)3/M-Y(M=Li+,Na+,K+和Cs+)催化剂.采用X射线衍射、红外光谱、紫外-可见光谱、热重-差热分析、电感耦合等离子原子发射光谱、N2吸附-脱附以及催化氧化反应考察了碱金属离子对Fe(phen)3/M-Y催化剂物化性质和催化氧化性能的影响.结果表明,交换有不同碱金属离子的Y型沸石中Fe(phen)3的封装量不同,而且Fe(phen)3在Y型沸石中的热稳定性随着碱金属离子半径的增加有所降低,其中Fe(phen)3/Li+-Y具有最高的配合物封装量和热稳定性能.在环己烷或苯乙烯氧化反应中,在较低的反应温度下,Fe(phen)3/K+-Y表现出最高的催化活性,而在较高的反应温度下,Fe(phen)3/Cs+-Y的催化活性最高,碱金属离子对Fe(phen)3/M-Y催化氧化性能的影响是电子效应、空间限制作用和扩散效应的综合结果.     

Comparison of pneumatic and ultrasonic nebulizations in inductively coupled plasma atomic emission spectrometry — matrix effects and plasma parameters

Matrix effects and plasma parameters in inductively coupled plasma atomic emission spectrometry (ICP-AES) using the sample introduction systems with ultrasonic and pneumatic nebulizations were studied. Analytical line intensities of fourteen elements and their detection limits as well as plasma temperatures, electron number density and ion-to-atom line intensity ratios were investigated with and without presence of complex matrix composed of Na, K, Mg and Ca. With ultrasonic nebulization in comparison to pneumatic nebulization, the line intensities were enhanced and the enhancement factor was dependent on the total line excitation energy. For each type of the sample introduction system, the changes in line intensities induced by the complex matrix were correlated with the sum of Ca and Mg concentrations. The excitation temperatures of atoms and ions, the ionization temperatures and the ion-to-atom line intensity ratios were the lowest using the ultrasonic nebulizer and quite well comparable for both pneumatic nebulizers (Meinhard and V-groove). The differences between excitation temperatures of ions and atoms were the largest while the electron number density was the lowest when the ultrasonic nebulizer was employed. Generally, the plasma parameters were independent of the matrix composition. The differences in plasma parameters observed for the individual nebulizers were related to various amounts of solvent loaded to the plasma.     

Investigation of matrix effects in inductively coupled plasma-atomic emission spectroscopy using laser ablation and solution nebulization — effect of second ionization potential

Plasma-related non-spectroscopic matrix effects of 31 elements in inductively coupled plasma (ICP)-atomic emission spectrometry were investigated using both laser ablation and solution nebulization as sample introduction techniques. Matrix effects were studied by monitoring the excitation conditions of the plasma using the ionic to atomic spectral line intensity ratios of zinc and magnesium. A new kind of matrix interference was found in the ICP that appears to be related to matrices with elements of low second ionization potential. The matrix effects do not correlate with the first ionization potential of the element. Only those matrix elements with low second ionization potential showed severe matrix effects. Increasing the forward power of the ICP or replacing the carrier gas with a 50%/50% argon–helium mixture did not significantly reduce this matrix effect. However, using 100% helium as the carrier gas greatly reduced the extent of this matrix effect, suggesting that argon is involved in the interference mechanism. The interference mechanism may involve interactions between doubly-charged matrix ions and argon species.     

A practical approach to non-spectral interferences elimination in inductively coupled plasma optical emission spectrometry

Matrix effects and practical possibilities of reducing accompanying non-spectral interferences in inductively coupled plasma optical emission spectrometry (ICP-OES) were studied for microconcentric Micromist, concentric and V-groove nebulizers (VGN) coupled with two cyclonic spray chambers of different sizes. The effect of a wide scale of interferents and mixtures thereof in the concentration range of up to 2 mass % (Na, Ca, Ba, La, urea) or up to 20 vol. % (nitric acid) on the analysis of Cd, Cu, K, Mg, Mn, Pb and Zn was investigated in terms of their analytical recovery and Mg(II) 280.27 nm/Mg(I) 285.29 nm line intensity ratio. Recoveries of ionic lines were lower than those of atomic lines (37–102 %) depending on the matrix concentration. The Mg(II)/Mg(I) ratios were found to be 12–15 and they slightly decreased as the matrix load increased. Exceptional behavior of pure La matrix, steeply lowering the recoveries and Mg(II)/Mg(I) ratios was observed. A Micromist nebulizer coupled with a small inner volume spray chamber provided the highest recoveries (94–102 %), lowest matrix effects across the matrix loads and, compared to others, the least significant dependence without worsening of the analytical characteristics (recoveries, signal background ratios and the Mg(II)/Mg(I) ratios) across the studied matrices.     

小麦粉的ICP-AES多元素同时测定

本文报告了ICP-AES法同时测量小麦粉中Ca、Mg、Al、Fe、Cu、Zn、Mn、Ba、Y、Ni的含量。采用元素间干扰系数法校正主要基体元素对微量元素测定的光谱干扰。本法应用于湖南省粮食中重金属含量调查与评价,获得了令人满意的结果。     

Interferences and Methods for Their Elimination in the Determination of Lanthanum as LaO by Laser-Enhanced Molecular Flame Ionization Spectrometry

Interfering effects of some elements on the determination of lanthanum as LaO in a natural gas–air flame by laser-enhanced molecular ionization spectrometry were studied. It was demonstrated that easily ionized elements (Li, K, Na, Mg) exert an ionization effect; in addition, sodium introduces spectral interference. Techniques were proposed for the elimination of these interfering effects.     

Direct determination of trace elements in niobium,tantalum and their oxides by inductively coupled plasma atomic emission spectrometry after microwave dissolution

Analytical schemes for the determination of trace elements in high-purity niobium, tantalum and their oxides are proposed. The schemes are based on microwave dissolution of the metals and oxides followed by inductively coupled plasma atomic emission spectrometry (ICP-AES) determination of impurities in the solutions. The possibilities of interelement and off-peak background corrections in ICP-AES analysis are discussed. The accuracy of the results obtained is confirmed by the determination of trace elements after a matrix sorption separation procedure. For a number of elements, a comparison of the results obtained by ICP-AES without and with the matrix separation procedure and by electrothermal atomic absorption spectrometry (ETAAS) shows good agreement. The limits of detection for direct ICP-AES determination are in the range 0.4*1.0 μg g⁻¹ for Ba, Ca, Fe, Mg, Mn, Y and La; between 2.0 and 10.0 μ g⁻¹ for B, Cd, Co, Cr, Cu, Hf, Mo, Na, Nb, Ni, Pb, Sr, Ti, Zr and Ta; and for K, Sb and W a detection limit of 20 μ g⁻¹ is achieved. The schemes proposed are intended for rapid routine analysis.     

Spectral interference study of uranium on other analytes by using CCD based ICP-AES

Due to the multi-electronic nature, uranium is having line rich emission spectra and is expected to interfere during the determination of analytes at the trace level in uranium matrix. Therefore, chemical separation of uranium followed by the determination of trace metallic impurities in the raffinate by ICP-AES is generally adopted procedure in nuclear industries. There is restriction on choosing alternate analytical lines of elements by photomultiplier tube based ICP-AES associated with the polychromator while monochromator needs significant time to scan different analytical lines of all the elements. Since charged coupled detector (CCD) consists of array of pixels, it is having more option in choosing alternative analytical lines of the analytes. Therefore, an attempt was made to study the spectral interference of uranium on different analytical lines of analytes viz. Al, Ga, In, Si, Li, Ti, Mg, Sr, K, Ce, Nd, Lu, Sc, V, Er, Y, Ba, Bi, Pb, W, La, Tl, Sn, Yb, Mo, Sb, Pr and Zr; and the correction factors were evaluated (where ever necessary) using CCD based ICP-AES technique. The sensitivity and the detection limits of the analytical channels of the elements in presence of uranium matrix were calculated. The present study also deals with the identification of suitable analytical lines of uranium and its detection limits.     

Automatic selection of internal standards in inductively coupled plasma-mass spectrometry

The automatic selection of internal standards in inductively coupled plasma-mass spectrometry was performed using a cluster analysis algorithm. The samples contained 25 analytes, spanning the atomic mass and ionization potential ranges, and a single interfering element. The interferents examined were Na, Mg, K, Zn, Ba, and Pb. The cluster analysis algorithm used kinetic energy, ionization potential, oxide bond strength, hydride bond strength, and electronegativity, to group the analytes. These variables were weighted differently in the various matrices. The performance of the clustering method and selection of internal standards was good for most analytes in the various matrices.     

Comparative instrumental multi-element analysis I: Comparison of ICP source mass spectrometry with ICP atomic emission spectrometry, ICP atomic fluorescence spectrometry and atomic absorption spectrometry for the analysis of natural waters from a granite region

Summary Multi-element analysis by ICP source mass spectrometry for practically matrix-free natural waters, coming from a granitic area and, therefore, rich in trace elements, has been compared with ICP-atomic emission, ICP atomic fluorescence and atomic absorption spectrometry. The following elements have been investigated and their concentrations are in the decreasing order: Ca, Si, Na, Mg, K, Al; Sr, Mn, Ba, Fe, Rb, Zn, B, U, Y, Li, La, Be, Cs, Co, Cr, V, Sb, Bi, Th, Cu, Cd, Ni, Se, Pb, As, Hg, Mo, Tl, Sn. The concentration ranges were between 10 ppm and <0.01 ppb.As a measure of agreement between the different methods under investigation, two criteria have been used (a) the relative variation coefficient VK (%) of the mean element concentration of an element, determined by different methods in all the 98 water samples and (b) the linear, logarithmic and Spearman rank correlation coefficients between ICP-MS and each of the other methods. Detection limits are given from literature for about 32 elements using different methods.The elements Ca, Na, Mg, K, Mn, Sr, Zn, Fe, Li, Cu have been determined with ICP-MS, ICP-AES and AAS; Al, Ba with ICP-MS and ICP-AES; Si only with ICP-AES, whereas B, Be, Bi, Co, Cr, Cs, Hg, La, Mo, Ni, Pb, Rb, Sb, Sn, Th, Tl, U, V, Y only with ICP-MS. In all 34 of the investigated 36 elements could be analysed by ICP-MS, 14 (from about 20 possible) by AAS, 13 by ICP-AES and 12 by ICP-AFS.The agreement between ICP-MS and ICP-AES as well as between ICP-MS and AAS in most cases is remarkably good according to (a). VK (%) for each element in 98 water samples is in the range from ±2.6 to 10% for Na, Mg, Ca, K, Fe, Sr, Ba, Cu, Li (increasing order). Cd and Zn have unexpectedly higher values (±17.3 and ±20.5%); Cd concentrations are, however, near the detection limit.Comparing the different methods on the basis of correlation coefficients according to (b), gives for the Spearman rank correlation coefficient over the whole range of concentrations, respectively for ICP-MS/ICP-AES, AAS, ICP-AFS in case of Ca: 0.998; 0.984; 0.899; Na: 0.993; 0.991; 0.978; Mg: 0.997; 0.993; 0.959; K: 0.986; 0.942; 0.677; Al: 0.987; -; -; Fe: 0.864; 0.974; 0.701; Mn: 0.989; 0.990; 0.198; Sr: 0.988; 0.992; -; Zn: 0.894; 0.819; 0.300; Cu: -; 0.977; 0.202; Li: -; 0.907; 0.586.It is evident from these trace element concentrations as well as the electrical conductivities, that only about three fourths of the investigated samples are typical granitic waters and the remaining ones are associated with different geological background. The samples have been mainly radon waters with more than 18 nCi/l of Rn-222.

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Vergleichende Instrumentelle Multielementanalyse I: Vergleich von ICP-Massenspektrometrie mit ICP-Atomemissionsspektrometrie, ICP-Atomfluorescenzspektrometrie und Atomabsorptionsspektrometrie zur Analyse natürlicher Wässer aus einem Granitgebiet

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6th Contribution to the principles of trace analysis of elements and radionuclides

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Dedicated to Professor Dr. H. Kelker, Frankfurt, on the occasion of his 65th birthday     

Analysis of molybdenum oxide by inductively coupled plasma atomic emission and mass spectrometry

Procedures for the analysis of molybdenum oxide by of inductively coupled plasma atomic emission spectroscopy (ICP-AES) and mass spectrometry (ICP-MS) are proposed on the basis of preliminary extraction separation of molybdenum from impurity elements. To separate 39 impurity elements (Li, Be, Na, Mg, Al, K, Ca, Sc, Ti, Cr, Mn, Fe, Co, Ni, Zn, Ga, Rb, Sr, Y, Cd, Ba, La, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Pb, Bi, Th, and U), the extraction of molybdenum from hydrochloric acid solutions using 5-n-pentylthio-8-hydroxyquinoline was used. The capacities of both methods ICP-AES and ICP-MS in the analysis of molybdenum oxide analysis were examined without the removal of the matrix and after the extraction separation of molybdenum.