便携式x射线荧光光谱仪光谱干扰的近实时管理:在含镍红土矿石中钪定量中的应用

IF 1 4区地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS

Geochemistry-Exploration Environment Analysis Pub Date : 2021-08-01 DOI:10.1144/geochem2021-015

E. Lacroix, J. Cauzid, Y. Teitler, M. Cathelineau

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引用次数: 4

摘要

自从便携式X射线荧光光谱仪（pXRF）问世以来，很少有人研究化学元素之间光谱干扰的影响。本研究旨在改进对这些干扰的管理，以获得更可靠的地球化学分析。我们专门研究了使用Niton XL3t GOLDD对富镍红土样品Sc分析的Ca相关干扰 + pXRF分析仪。使用“土壤”模式对59个造粒样品进行了三种定量方法的测试。第一个被命名为“制造商”，代表由该设备基于感兴趣区域和光谱仪设计期间配置的光谱干扰的多线性校正直接提供的元素量化。第二种方法，“20 Cu”方法，基于PyMCA软件的光谱拟合。第三种方法，“18Fe”方法，将光谱拟合与修改的实验条件相结合。针对每种情况，都制定了量化方法，建立了（i）Ca和Sc校准线和（ii）Ca/Sc阈值，界定了“可靠”、“待确认”和“不可靠”测量的字段。与“制造商”方法相比，“20 Cu”和“18 Fe”方法大大扩展了有关Ca/Sc比率的“可靠测量”领域。“18Fe”方法也被发现提供了最可忽略的测量色散。补充材料：图A-F以及表A和表B可在https://doi.org/10.6084/m9.figshare.c.5511838

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Near real-time management of spectral interferences with portable X-ray fluorescence spectrometers: application to Sc quantification in nickeliferous laterite ores

Since the development of portable X-ray fluorescence (pXRF) spectrometers, few studies have been conducted on the influence of spectral interferences between chemical elements. This study aims to improve the management of these interferences to obtain more reliable geochemical analyses. We specifically investigate Ca-related interferences on Sc analysis for the case of Ni-rich laterite samples using the Niton XL3t GOLDD + pXRF analyser. Three quantification methods were tested on 59 pelletized samples using the ‘Soil’ mode. The first, named ‘Manufacturer’, represents the elemental quantification directly provided by the device based on regions of interest and multilinear corrections of spectral interferences configured during the spectrometer design. The second, the ‘20 Cu’ method, is based on spectral fitting using the PyMCA software. The third, the ‘18 Fe’ method, combines spectral fitting with modified experimental conditions. For each, a quantification methodology was developed, establishing (i) Ca and Sc calibration lines and (ii) Ca/Sc threshold values delimiting fields of ‘reliable’, ‘to be confirmed’ and ‘unreliable’ measurements. The ‘20 Cu’ and ‘18 Fe’ methods greatly extend the ‘reliable measurements’ field concerning the Ca/Sc ratio compared to the ‘Manufacturer’ method. The ‘18 Fe’ method was also found to provide the most negligible measurement dispersion. Supplementary material: Figures A–F and Tables A and B are available at https://doi.org/10.6084/m9.figshare.c.5511838

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来源期刊

Geochemistry-Exploration Environment Analysis 地学-地球化学与地球物理

CiteScore

3.60

自引率

16.70%

发文量

审稿时长

1 months

期刊介绍： Geochemistry: Exploration, Environment, Analysis (GEEA) is a co-owned journal of the Geological Society of London and the Association of Applied Geochemists (AAG). GEEA focuses on mineral exploration using geochemistry; related fields also covered include geoanalysis, the development of methods and techniques used to analyse geochemical materials such as rocks, soils, sediments, waters and vegetation, and environmental issues associated with mining and source apportionment. GEEA is well-known for its thematic sets on hot topics and regularly publishes papers from the biennial International Applied Geochemistry Symposium (IAGS). Papers that seek to integrate geological, geochemical and geophysical methods of exploration are particularly welcome, as are those that concern geochemical mapping and those that comprise case histories. Given the many links between exploration and environmental geochemistry, the journal encourages the exchange of concepts and data; in particular, to differentiate various sources of elements. GEEA publishes research articles; discussion papers; book reviews; editorial content and thematic sets.