Application of TLC and LA ICP SF MS for speciation of S, Ni and V in petroleum samples

Vorapalawut, Nopparat; Martinez, Mauro; Pohl, Paweł; Caetano, Manuel; Chirinos, José; Arnaudguilhem, Carine; Bouyssière, Brice; Shiowatana, Juwadee; Łobiński, Ryszard

doi:10.1016/j.talanta.2012.04.040

Cited by 31 publications

(34 citation statements)

References 29 publications

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“…The LA technique provides spatially resolved detection of trace elements with LoDs in the ng per g range or below. Various substrates including organic materials [12,13] have been applied to LA-ICP-MS.…”

Section: Introductionmentioning

confidence: 99%

LA-ICP-MS of rare earth elements concentrated in cation-exchange resin particles for origin attribution of uranium ore concentrate

Asai

Limbeck

2015

Talanta

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Section: Introductionmentioning

confidence: 99%

LA-ICP-MS of rare earth elements concentrated in cation-exchange resin particles for origin attribution of uranium ore concentrate

Asai

Limbeck

2015

Talanta

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“…The use of TLC-LA-ICP-MS could provide quantitative information of gold nanoparticles (AuNPs) by separating them from gold ions, as well as AuNP size information by using a specific mobile phase in the TLC separation [36]. TLC was also employed in fractionation studies of S, Ni, and V in petroleum using LA-sector field ICP-MS [37].…”

Section: La-icp-ms Applicationsmentioning

confidence: 99%

Laser Chemical Elemental Analysis: From Total to Images

Amais¹,

Francischini²,

Moreau³

et al. 2021

Practical Applications of Laser Ablation

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This book chapter focuses on laser ablation employed in elemental analysis and discusses the fundamentals and instrumentation of the laser-induced breakdown spectroscopy (LIBS) and laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) techniques. The analytical performance of such techniques, challenges related to calibration, and strategies to improve sensitivity are discussed. In addition, the processes involved in data acquisition and imaging for acquiring the elemental spatial distribution are highlighted, and some representative examples in environmental, biological, medical, and forensic researches are presented.

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“…Vorapalawut et al 62 developed a method by which Fe, Ni, S and V distribution in various fractions of crude oils could be characterized using a combination of thin layer chromatography (TLC) and LA-ICP-MS. Crude oils and their fractions (saturated, aromatic, resin and asphaltene) were placed on an activated silica gel plate and separated using a selection of different solvents. Each band of material was then placed on a microscope slide and analysed using LA-SF-ICP-MS. Optimization of the LA process indicated that a scan process of 80 mm s À1 , a laser energy of 50% (0.45 mJ) and a spot size of 200 mm were optimal.…”

Section: Fuels and Lubricantsmentioning

confidence: 99%

Atomic spectrometry update. Review of advances in the analysis of metals, chemicals and materials

Carter

Fisher

Gibson

et al. 2013

J. Anal. At. Spectrom.

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Non-ferrous metals 2 Industrial chemicals 2.1 Fuels and lubricants 2.1.1 Petroleum products-gasoline, diesel, gasohol and exhaust particulates 2.1.2 Fuel-coal, peat and other solid fuels 2.1.3 Oils-crude oil, lubricants 2.1.4 Alternative fuels 2.2 Organic chemicals and solvents 2.2.1 The analysis of archaeological, cultural heritage and art objects 2.2.2 Remote analysis of harmful materials 2.2.3 Speciation 2.2.4 Applications requiring minimal sample preparation 2.2.5 Applications requiring analyte extraction or sample dissolution 2.3 Inorganic chemicals and acids 2.3.1 Coupled techniques 2.3.2 Forensic applications 2.3.3 Remote analyses of inorganic materials 2.3.4 Other applications of the analysis of inorganic materials 2.3.5 Analysis of nano-structures 2.4 Nuclear materials 2.4.1 Reviews, overviews and CRMs 2.4.2 Nuclear safeguards and forensics 2.4.3 Other nuclear applications 3 Materials 3.1 Ceramics and refractories 3.1.1 Analysis of archaeological, cultural heritage and art objects 3.2 Thin Films and Depth Proling 3.2.1 Laser-based techniques 3.2.2 Glow discharge and plasma techniques 3.3 Glasses 3.3.1 Laser-based techniques 3.3.2 Other techniques 3.3.3 Analysis of archaeological, cultural heritage and art objects 3.4 Catalysts 3.4.1 Surface Characterisation 3.4.2 Sampling and sample preparation 3.4.3 MiscellaneousThis review period has seen some changes to the format of the review. These changes are intended to more accurately reflect the current state of analytical research in the analysis of metals, chemicals and materials. As a consequence, the title of the review and some of the section headings have been altered to reflect this. Significant areas of growth include the use of LIBS in remote

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Application of TLC and LA ICP SF MS for speciation of S, Ni and V in petroleum samples

Cited by 31 publications

References 29 publications

LA-ICP-MS of rare earth elements concentrated in cation-exchange resin particles for origin attribution of uranium ore concentrate

LA-ICP-MS of rare earth elements concentrated in cation-exchange resin particles for origin attribution of uranium ore concentrate

Laser Chemical Elemental Analysis: From Total to Images

Atomic spectrometry update. Review of advances in the analysis of metals, chemicals and materials

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