利用同位素稀释技术测定土壤中无机锑形态分析过程中的形态转化

Journal of Analytical Sciences, Methods and Instrumentation Pub Date : 2013-05-31 DOI:10.4236/JASMI.2013.32016

Sameer Amereih, T. Meisel, Zaher Barghouthi, W. Wegscheider

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引用次数: 3

摘要

本文开发了一种新的方法来解释土壤样品制备和随后的分离步骤中无机Sb物种的相互转化。Sb(III)和Sb(V)浓度在分析过程的每个研究步骤中使用物种特异性尖峰测定(121Sb(III)富集81.18%，123Sb(V)富集74.04%)。在土壤样品提取前和高效液相色谱分离前分别对这些富集同位素溶液进行加峰。简单地用在线同位素稀释(ID)得到的每个物种的最终浓度减去物种特定ID在分析过程中不同阶段的浓度，就可以估计出每个步骤对物种转化的影响。优化后，利用在线ID法提取土壤样品中无机锑的比例分别为6% Sb(III) (1.3 RSD, n = 3)和43.2% Sb(V) (2.9% RSD, n = 3)。使用上述方法，我们发现在样品制备或物种分离过程中没有将Sb(V)还原为Sb(III)。在提取步骤中，可提取的Sb(III)转化为Sb(V)的比例约为9.3%(4.6%)，而在HPLC分离步骤中未观察到转化。通过补偿样品制备过程中Sb(III)的转变;Sb(III)和Sb(V)的提取率分别为10.6%和38.7%。

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Determination of Inorganic Antimony Species Conversions during Its Speciation Analysis in Soil Using Isotope Dilution Techniques

A new method was developed in this work to account for inorganic Sb species interconversion during soil sample preparation and subsequent separation steps. The Sb(III) and Sb(V) concentrations at each investigated step in the analytical procedure were determined using species specific spikes (121Sb(III) with 81.18% and 123Sb(V) with 74.04% enrichment). The spiking of these enriched isotopes species solutions was done separately before soil sample extraction and before HPLC separation. Simply by subtracting the final concentration of each species done by on-line isotope dilution (ID) from its concentration at different stages of the analytical procedure done by species specific ID, the influence of each step on species transformation can be estimated. After optimization, the extraction procedure for inorganic Sb species 6% Sb(III) (1.3 RSD, n = 3) and 43.2% Sb(V) (2.9% RSD, n = 3) as percent of total Sb were detected in the examined soil sample using online ID. Using the above described methodology we found that there was no reduction of Sb(V) to Sb(III) during sample preparation or species separation. While about 9.3% of extractable Sb (4.6% of total) was converted from Sb(III) to Sb(V) during the extraction step, no conversion during HPLC separation step was observed. By compensating for Sb(III) transformation during the sample preparation step; the extractable Sb(III) and Sb(V) as percent of total Sb yielded 10.6% and 38.7%, respectively.

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Journal of Analytical Sciences, Methods and Instrumentation

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