贵金属,分析化学

M. Balcerzak
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引用次数: 4

摘要

本文介绍了贵金属钌(Ru)、铑(Rh)、钯(Pd)、锇(Os)、铱(Ir)、铂(Pt)和金(Au)的分析方法。介绍了稀土金属的发现、自然赋存和主要应用。综述了贵金属的物理和化学性质。贵金属的高贵性和催化活性是其广泛应用的主要特性,例如在各种化学过程中作为催化剂,作为汽车催化剂,在电气和电子工业以及珠宝中。近年来一些铂类化合物(顺铂及其衍生物)作为抗癌药物的应用具有重要意义。复杂基体的种类繁多,分析浓度范围广(从亚ppb到>99.99%),对单一化学试剂的反应活性低,化学相似性大(特别是Ru和Os, Rh和Ir, Pt和Pd对),溶液中铂族金属(铂族金属)的种类和反应速率的复杂性使贵金属的准确测定成为一个难题。由于基质元素和低分析物浓度引起的干扰,直接仪器方法的使用受到限制。取样、样品分解、分离和预富集是大多数分析方法的关键步骤。所使用的消解程序的选择取决于样品基质的性质和分析物的浓度。火分析(铅、铁、铜、镍、锡或硫化镍作为收集剂)、氧化熔合、酸处理和氯化用于消化各种材料。沉淀法、溶剂萃取法和色谱法(离子交换和螯合树脂法、毛细管电泳法)被用于从伴生贱金属中分离贵金属和分离单个贵金属。通常采用以RuO4和OsO4形式蒸馏或萃取的方法,从其他贵金属和贱金属以及彼此之间初步分离钌和锇。使用无机和有机试剂配合物的分光光度法可用于测定ppm水平的贵金属。原子吸收光谱法(火焰和石墨炉)适用于Au、Pd、Rh和Pt(分别为ppm和ppb级)的测定。电感耦合等离子体质谱(ICPMS)可以在大量复杂基质中测定贵金属的超痕量(ppb和亚ppb水平),无论是否采用分离和富集步骤。可通过x射线荧光(XRF)直接在固体样品中或经过预处理程序(火焰测定、共沉淀、色谱预浓缩)确定从百分比到ppm水平的广泛范围的PGM浓度。核技术(主要是中子活化)被用于测定地质样品中低(ppb和亚ppb)水平的贵金属(对Au、Ir、Pd和Os具有高灵敏度)。伏安测量与样品制备相结合,包括将贵金属转化为电化学活性化合物,为测定提供高灵敏度(ppm和ppb水平)。标准标准物质的使用对于检查各种分析技术所得结果的准确性至关重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Noble Metals, Analytical Chemistry of
Analytical methods for the determination of noble (precious) metals: ruthenium (Ru), rhodium (Rh), palladium (Pd), osmium (Os), iridium (Ir), platinum (Pt) and gold (Au) are presented in this article. Discovery, natural occurrence and main applications of the metals are described. Physical and chemical properties of noble metals are summarized. The nobility and catalytic activity of precious metals are the main properties that allow their use in a wide variety of applications, e.g. as catalysts in various chemical processes, as autocatalysts, in the electrical and electronic industry and in jewellery. Recent applications of some platinumcompounds (cisplatin and its derivatives) as anticancer drugs are important. The large variety of complex matrices, wide analytical concentration range (from sub-ppb to >99.99%), low reactivity towards single chemical reagents, great chemical similarities (especially between the pairs Ru and Os, Rh and Ir, Pt and Pd), complexity of platinum group metals (PGMs) species in solutions and rates of reaction make the accurate determination of noble metals a difficult analytical problem. The use of direct instrumental methods is restricted owing to interferences caused by matrix elements and low analyte concentrations. Sampling, sample decomposition, separation and preconcentration are critical steps in the majority of analytical procedures used. The choice of the digestion procedure used depends on the nature of the sample matrix and the analyte concentration. Fire assay (lead, iron, copper, nickel, tin or nickel sulfide as collectors), oxidizing fusion, acids treatment and chlorination are used to digest various materials. Precipitation, solvent extraction and chromatographic methods (ion-exchange and chelating resins, capillary electrophoresis) are applied to separate noble metals from associated base metals and to separate the individual precious metals. Preliminary isolation of ruthenium and osmium from the other noble and base metals, as well as from each other, by distillation or extraction in the form of RuO4 and OsO4, is often applied. Spectrophotometric methods using the complexes with inorganic and organic reagents can be applied to the determination of precious metals at ppm levels. Atomic absorption spectroscopy (AAS) (flame and graphite furnace) is well suited to the determination of Au, Pd, Rh and Pt (ppm and ppb levels, respectively). Ultratraces (ppb and sub-ppb levels) of noble metals can be determined in a large number of complex matrices by inductively coupled plasma mass spectrometry (ICPMS) with or without separation and preconcentration steps. A wide range of PGM concentrations, from percentage to ppm levels, can be determined by X-ray fluorescence (XRF) directly in solid samples or after pretreatment procedures (fire assay, coprecipitation, chromatographic preconcentration). Nuclear techniques (mainly neutron activation) are favored for the determination of low (ppb and sub-ppb) levels of precious metals (high sensitivities for Au, Ir, Pd and Os) in geological samples. Voltammetric measurements in combination with sample preparation, including the transformation of noble metals into electrochemically active compounds, provide high sensitivity (ppm and ppb levels) for the determination. The use of standard reference materials is essential to check the accuracy of the results obtained by various analytical techniques.
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