王水密闭溶矿-电感耦合等离子体原子发射光谱法测定锑矿石中的锑

建立了王水密闭溶矿-电感耦合等离子体原子发射光谱法测定锑矿石中锑的方法。研究了溶矿时间、溶矿温度、溶液的酸度、基体效应对测定的影响。样品的相对误差在1.10%~13.33%,11次独立测定的相对标准偏差均小于2%。经标准物质验证,结果满意。     

电感耦合等离子体原子发射光谱法测定盐酸多巴酚丁胺注射液中硫

采用电感耦合等离子体原子发射光谱法测定注射液中硫元素含量。样品经高压消解处理，并加入体积分数5%的硝酸溶液，使样品中的硫元素氧化为稳定的硫酸根离子，使用电感耦合全谱等离子体发射光谱仪，在180.731nm处测量硫的发射光谱，计算硫元素的质量浓度。硫元素的质量浓度在0～10μg/mL范围内与其对应的发射强度线性相关，线性回归方程为y=54.887x+2.208 6，相关系数0.999 9，方法的检出限为0.007μg/mL，对理论硫元素质量浓度为74.1 mg/L的盐酸多巴酚丁胺注射液加标试验，测定值的相对标准偏差为2.23%(n=7)，加标回收率为103.5%～106.2%。     

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...     

不同介质对电感耦合等离子体发射光谱法测定水中锡元素的影响

选用电感耦合等离子体发射光谱法测定水中锡元素,讨论了硝酸、盐酸两种介质对锡溶液测定及保存的影响。结果表明,选用体积分数为1%~10%的HNO3介质配制质量浓度为0.250~10.0 mg/L的锡溶液,在1%的HNO3中锡溶液浓度仅能稳定5 d,当HNO3的体积分数大于5%时,锡溶液可稳定30 d。选用1%~10%的HCl介质配制质量浓度为0.500~10.0 mg/L的锡溶液,在近一个月的实验周期内浓度值稳定,测定结果的相对标准偏差在0.94%~3.04%之间。作为测定、保存水中锡元素的介质,盐酸比硝酸更为理想。     

电感耦合等离子体–原子发射光谱法同时测定铝合金中9种元素

建立电感耦合等离子体原子发射光谱同时测定铝合金中9种元素含量的方法。铝合金样品采用碱溶法预处理,以质量分数为40%的氢氧化钠溶液溶解,再用盐酸-硝酸混合酸酸化,然后用电感耦合等离子体原子发射光谱法同时测定样品中铁、硅、铜、镁、锰、锌、钛、镍、铬9种元素的含量。各元素的含量与对应的发射强度呈良好的线性关系,相关系数不小于0.9990;各元素检出限为0.0001%~0.0012%。应用该方法测定2个铝合金标准样品,测定结果与标示值一致,相对标准偏差为0.46%~2.14%(n=8)。将该法应用于试样测定时,加标回收率为92%~106%。该方法精密度和准确度高,操作简便、快速,适用于实验室铝合金多元素含量的检测。     

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.     

电感耦合等离子体原子发射光谱法测定氟铍酸铵中的杂质元素

采用电感耦合等离子体原子发射光谱法测定氟铍酸铵中的8种主要杂质元素。以超声辅助溶解样品,然后用电感耦合等离子体原子发射光谱法测定氟铍酸铵中的钠、镁、铝、铬、铁、镍、铜、磷等8种杂质元素,8种元素线性相关系数均大于0.999,测定结果的相对标准偏差为0.65%~1.55%(n=6),检出限在0.2~19.1μg/L之间,定量范围满足氟铍酸铵中8种杂质元素的限量要求。磷的加标回收率为76.7%,其余7种杂质元素的加标回收率在80.9%~95.1%之间,测量准确度满足分析要求。将电感耦合等离子体原子发射光谱法和电感耦合等离子体质谱法进行了比较,两种方法测定结果基本一致。     

电感耦合等离子体质谱法同时测定植物类新食品原料中14种无机元素北大核心CSCD

0.500 0g样品经硝酸3mL、过氧化氢2mL消解后,采用电感耦合等离子体质谱法同时测定样品溶液中Na、Mg、Ca、Al、Cu、Zn、Fe、Mn、Se、Pb、Cd、As、Hg和Cr的含量。采用0.5%(体积分数)硝酸的基体酸度增强分析元素的信号强度;在两次测试之间用100μg·L-1 Au-5%(体积分数)硝酸溶液清洗仪器,降低Hg的吸附效应;利用甲烷碰撞动态反应池技术消除了分析过程中的质谱干扰,选择Sc、Y、In、Bi为内标元素校正基体效应。14种元素的质量浓度在一定范围内与信号强度呈线性关系,检出限(3s)在0.003~0.039μg·L^(-1)之间。方法用于分析国家标准物质GBW 10027,各元素测定值与认定值相符,测定值的相对标准偏差(n=6)在1.6%~14%之间。     

电感耦合等离子体质谱法同时测定植物类新食品原料中14种无机元素

0.500 0g样品经硝酸3mL、过氧化氢2mL消解后,采用电感耦合等离子体质谱法同时测定样品溶液中Na、Mg、Ca、Al、Cu、Zn、Fe、Mn、Se、Pb、Cd、As、Hg和Cr的含量。采用0.5%(体积分数)硝酸的基体酸度增强分析元素的信号强度;在两次测试之间用100μg·L-1 Au-5%(体积分数)硝酸溶液清洗仪器,降低Hg的吸附效应;利用甲烷碰撞动态反应池技术消除了分析过程中的质谱干扰,选择Sc、Y、In、Bi为内标元素校正基体效应。14种元素的质量浓度在一定范围内与信号强度呈线性关系,检出限(3s)在0.003~0.039μg·L~(-1)之间。方法用于分析国家标准物质GBW 10027,各元素测定值与认定值相符,测定值的相对标准偏差(n=6)在1.6%~14%之间。     

电感耦合等离子体原子发射光谱法测定钛白粉中的微量元素

采用电感耦合等离子体原子发射光谱法测定钛白粉中微量元素(硅、铝、钨、锑、铁、铬、锆、铌)。样品(0.200 0g)经硝酸5mL、氢氟酸1mL低于70℃溶解后,用水定容至100mL。此溶液可供电感耦合等离子体原子发射光谱法测定8种微量元素,并选择了合适的分析谱线,以标准加入法补偿基体效应制作工作曲线。各元素的检出限(3s)在0.000 1%~0.008 0%之间,测定值的相对标准偏差(n=8)均小于1.7%。用标准加入法做锑、铁、铬、锆、铌的回收试验,测得回收率在90.0%~105%之间。按上述方法分析样品中硅、铝、钨元素的含量,测定值与化学法的测定结果一致。     

Desolvation of acid solutions in inductively coupled plasma atomic emission spectrometry by infrared radiation. Comparison with a system based on microwave radiation

The behaviour of an infrared desolvation system with acid solutions in inductively coupled plasma atomic emission spectrometry (ICP-AES) is evaluated, and the influence of the liquid uptake rate and of the nature and concentration of the acid on the solvent and analyte transport rates and on the analytical figures of merit is studied. The results are compared with those obtained with a desolvation system based on the absorption of microwave radiation. The infrared desolvation system performs best at low sample uptake rates (0.4 ml min⁻¹) and its behaviour strongly depends on the nature and concentration of the solution used. With nitric and hydrochloric solutions, there is almost no effect of the acid concentration on the emission intensity, while for sulfuric and perchloric acids the signal decreases as the acid concentration is increased. These effects seem to be related with the different capability of the acid aerosols to be heated in an IR field. The microwave desolvation system seems to be more prone to matrix (acid) effects, specially when using sulfuric and perchloric acids, resulting in emission intensities which are usually lower than those obtained with the infrared desolvation system, though their limits of detection are quite similar.     

ICP emission spectrometric analysis of rare earth elements in permanent magnet alloys

An analytical method for the determination of rare earth elements (REE) in a NdFeB permanent magnet alloy by ICP emission spectrometry is described. Spectral interferences, arising from overlapping, as well as matrix effects have been studied. Considering spectral interferences, sensitivities of spectral lines, background intensities and the chemical composition of the sample investigated, optimum spectral lines for each REE have been selected. Because of an unfavourable concentration ratio in samples of a NdFeB permanent magnet alloy, a preliminary separation of matrix elements from rare earth elements by ion chromatography is necessary. Different modes of elution (isocratic and gradient) with -hydroxy-isobutyric acid and different columns (NUCLEOSIL, SULFOPROPYL SI-100, DIONEX HPIC-CS3) have been tested. Optimum separation conditions have been chosen for each element and the separation efficiency at equal or different concentrations of the selected elements have been established. Although the separation of REEs resulted in partly overlapping peaks, the ratio between analyte and interferent is improved and the spectral interferences are diminished. The results obtained are in good agreement with certified values.     

Matrix effects in the analysis of biological matrices by axial view inductively coupled plasma optical emission spectrometry

We are reporting observations of positive and negative variations of emission line intensities during the determination of boron and titanium in biological matrices by axial view inductively coupled plasma optical emission spectrometry with segmented charge-coupled device detection. The study included the testing of several elements (yttrium, palladium and platinum) and analytical wavelengths for internal standardization, aiming to compensate for variations in signal recovery due to matrix interferences. Human albumin was chosen as principal matrix component to assess the effect of variable chemical and instrumental operating conditions on boron response. A parametric study was performed by considering the application of two different nebulizer–aerosol chamber systems, the effect of plasma operating conditions on analyte and internal standard signals and the influence of common blood plasma electrolytes, added as salts of alkaline or alkaline earth elements. The pneumatic injection systems tested were a standard cross-flow nebulizer with a Scott type spray chamber and a concentric Meinhard type device coupled to a glass cyclonic spray chamber. The change from standard (i.e. medium RF power and relatively high aerosol carrier gas flow rate) to robust (i.e. higher RF power and lower carrier gas flow rate) conditions contributed to large, non-correlated variations in boron intensities and in some of the analyte/internal standard ratios. Significant memory effects were observed for injection of boron solutions prepared with boric acid and containing small amounts of acid, but those effects were negligible when the boron carrier compound was boronophenylalanyne. The injection of titanium solutions did not produce analyte carry-over effects. When internal standards were employed, a less effective signal compensation was consistently observed for boron at higher albumin concentrations when the difference in energies of the lines was between 4.5 and 6 eV. This effect was enhanced for some line pairs when robust conditions are employed. Differences in the response between nebulizers were minor, with a slight advantage in sensitivity for the cross-flow/Scott system. Yttrium was found to be useful for signal compensation in the determination of boron and titanium in blood and human plasma provided that the equivalent concentration of albumin in the nebulized sample dilutions was kept below 0.2% w/v. Simultaneous measurement of a reference strontium line was found to be useful as an additional verification of the response of yttrium as internal standard.     

Laser defocusing effects on laser ablation inductively coupled plasma-atomic emission spectrometry: different ablation interactions between the laser and low-alloy steel, Fe pellets, and a pond sediment pellet.

The ablation interaction between a laser and solid samples, which affects the analytical performance for laser ablation inductively coupled plasma atomic emission spectrometry (LA-ICP-AES), was studied. The emission intensities of elements observed by LA-ICP-AES (LA-ICP-AES element signal intensities) for different solid samples were measured under different laser defocusing conditions with a fixed laser output energy. It was found that the optimum laser defocusing conditions were dependent on the different solid samples with different sample characteristics, and also on the different elements with different elemental characteristics in each solid sample. A low-alloy steel, pellets containing different Fe concentrations (0 - 100% Fe pellet), and a pond sediment pellet were used as different solid samples. The variations of the LA-ICP-AES Fe signal intensities observed under different laser defocus conditions were completely different between the low-alloy steel and the pond sediment pellet. The changes in the LA-ICP-AES Fe signal intensities for 90 and 100% Fe pellets were similar to that of the low-alloy steel. However, pellets with lower Fe concentrations (less than 70%) showed different trends and the defocusing behavior became closer to that of the pond sediment pellet. The LA-ICP-AES signal intensities of other elements were also evaluated, and were compared for different solid samples and different defocusing behavior. It was observed that the changes in the LA-ICP-AES signal intensities of almost all elements in the pond sediment pellet showed a similar trend to those of Fe for different laser defocus positions; that is, the elemental fractionation for these elements in the pond sediment pellet seemed to be relatively small. On the contrary, it was found that the LA-ICP-AES Si, Ti, and Zr signal intensities for low-alloy steel showed different trends compared to those of other elements, including Fe, under different defocusing conditions; that is, the elemental fractionation observed for the low-alloy steel was larger than that of the pond sediment pellet. From these results, different ablation interactions between the laser and the different solid samples were considered, and attributed to the sample characteristics, such as the matrix, hardness, and conductivity. Elemental fractionation was attempted to be explained by using elemental characteristics, such as the melting point and ionization energy of the elements.     

Matrix effects during trace element analysis in plant samples by inductively coupled plasma atomic emission spectrometry with axial view configuration and pneumatic nebulizer

Plant sample matrix effects have been investigated during trace element analysis by inductively coupled plasma atomic emission spectrometry with axial view and pneumatic nebulizer. Eight elements often analyzed in environmental samples were studied: As, Cd, Co, Cr, Cu, Ni, Pb and Se. To simulate the effects caused by digested plant samples, the spectral line profiles of analytes were measured on solutions containing various concentrations of elements encountered in plant matrix such as K, Ca and Mg. Depressions in the emission intensities occurred and were more dramatic with high concentrations of the concomitant species. The inter-element effects were found to be caused by the matrix amount entering into the central channel of the plasma. In fact, energy consumed for droplets desolvation and particles of salts vaporization leads to lower plasma temperatures and produce changes in excitation mechanisms. Ion emissions were especially affected. The matrix effects can be removed using a high generator power (1.4 kW) and a moderate uptake flow rate of solution into the plasma (pump speed: 15 rev./min). The use of the natural plant sample led to the same conclusions. These operating conditions decreased the sensitivity but routine analyses of the plant material could be carried out.     

Inductively coupled plasma optical emission spectrometric determination of trace elements in sediments after sequential selective extraction: effects of reagents and major elements on the analytical signal

The interfering effects due to the reagents and matrix elements associated with a four step sequential extraction procedure on ICPOES determination of trace elements were investigated in a systematic way. The emission lines were selected in order to include the most interesting elements for environmental studies (Zn, Pb, Ni, Cr, V and Cu) and the concentrations ranged according with the values occurring in the real samples. In order to distinguish between chemical and physical interfering effects, the Mg 280.270–Mg 285.213 line intensity ratio was measured, in each condition. Both pneumatic and ultrasonic nebulization were considered for comparison. It was found that both the elements which constitute the sample and the reagents which are added during the sample preparation steps significantly influence the emission intensity of all the analytes, depending on the analytical concentration and the nebulization system. Generally, the signal variations were higher with ultrasonic nebulization. Concerning the interference mechanism, it was found that the effect of the major elements (Na, K, Mg, Ca, Al and Fe) is essentially related to a change of the aerosol generation and transport processes. Differently, acetic acid, ammonium acetate and hydroxylamine hydrochloride significantly improved the plasma excitation conditions, depending on their concentration. A change of the sample introduction efficiency due to the presence of these reagents was also evident. On the contrary, the effect of hydrochloric and nitric acid emerged to be related only to the processes occurring in the sample introduction system.     

Determination of ultratrace impurity elements in high purity niobium materials by on-line matrix separation and direct injection/inductively coupled plasma mass spectrometry

The determination of 52 impurity elements in niobium materials (niobium metal, niobium oxide (V), and niobium pentaethoxide) was performed by inductively coupled plasma mass spectrometry (ICP-MS) with on-line anion exchange matrix separation as well as direct nebulization. Niobium material samples were decomposed with a mixture of hydrofluoric acid and nitric acid to prepare 10% niobium solutions. In the on-line anion exchange matrix separation/ICP-MS, the niobium and hydrofluoric acid concentrations in sample solution were adjusted to 5% and ca. 8 M, respectively. The solution was then injected into the carrier stream from the sample loop of injection valve to pass through an anion exchange resin column. In the anion exchange separation, niobium in the fluoro-complex form was adsorbed on the resin, while impurity elements were eluted. The eluted elements were introduced into ICP-MS for the determination of 25 impurity elements. On the other hand, 27 impurity elements could not be separated well from niobium matrix under the above anion exchange conditions, and then the sample solution with the niobium concentration of max. 0.2% containing internal standard elements was injected from the sample loop of injection valve directly to introduce into ICP-MS. As a result, 52 impurity elements in three kinds of niobium materials could be determined at the ng g⁻¹ level.     

Determination of Sb, Ni and V in slurry from airborne particulate material collected on filter by graphite furnace atomic absorption spectrometry

A microdigestion procedure performed directly in the autosampler cup is proposed. Small quartz filter pieces loaded with the particulate material are transferred to the cup. The sample is digested by a mixture of nitric, sulfuric and hydrofluoric acid (1:1:1) under sonication. After the addition of a boric acid solution the elements are determined by graphite furnace atomic absorption spectrometry using the autosampler to deliver the slurry into the furnace. A mixture of palladium and magnesium nitrates was used as a modifier for Sb. Spiking studies showed recoveries close to 100% using aqueous analytical curves for Ni and Sb. For V, an analytical curve in the blank slurry, obtained by submitting an unloaded filter to the same procedure, was used. The method was applied to two standard reference materials, Coal Fly Ash (NIST 1633a) and Urban Particulate (NIST 1648) and the concentrations showed good agreement with the certified or recommended values using aqueous analytical solutions.     

Using a two-jet arc plasmatron for determining the trace element composition of powdered biological samples

Weak effects of organic matrix and the chain length of the organic substituent on the analytical line intensities of the elements in the exciting emission spectra in a two-jet arc plasmatron were found. Using animal organs, hair, and plants as examples, it was demonstrated that the plasmatron is promising for determining trace elements in powdered biological samples without sample dissolution.     

微波等离子体炬耦合方式的研究

采用气动雾化连续进样、端视观测法,考察了微波等离子体炬原子发射光谱法中等离子体Ar线的背景发射以及Al,Mg,V等元素的信号发射强度随天线耦合连接点位置的不同而发生的变化.结果表明,当天线位于炬管顶端,即天线距离活塞3λ/4和λ/4时均能获得较好的等离子体,λ/4略好,信号发射强度和信背也较大,只是精密度略差一些.初步探讨了MPT炬管的电磁场结构.