Quantitative trace elemental analysis by laser-induced breakdown spectroscopy with dried droplet pretreatment

Quantitative trace element analysis is crucial to a range of industries, including food, natural and man-made materials, and biomedicine. For this purpose, we here developed laser-induced breakdown spectroscopy (LIBS) with dried droplet sample pretreatment. This novel method is quantitative and espe...

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Published inJournal of analytical atomic spectrometry Vol. 35; no. 1; pp. 2224 - 223
Main Authors Liu, Yuanchao, Hsieh, Yi-Kong, Chu, Yanwu, Ahmed, Irfan, Hu, Zhenlin, Khan, Muhammad Shehzad, Zhang, Siyu, Manno, Francis A. M, Manno, Sinai H. C, Lian, Meng, Wang, Chu-Fang, Guo, Lianbo, Lau, Condon
Format Journal Article
LanguageEnglish
Published London Royal Society of Chemistry 09.10.2020
Subjects
Analytical chemistry
Atomic properties
Droplets
Filter paper
Inductively coupled plasma mass spectrometry
Laser ablation
Laser induced breakdown spectroscopy
Lasers
Linearity
Mass spectrometry
Pretreatment
Pulsed lasers
Regression analysis
Regression coefficients
Trace elements
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Abstract Quantitative trace element analysis is crucial to a range of industries, including food, natural and man-made materials, and biomedicine. For this purpose, we here developed laser-induced breakdown spectroscopy (LIBS) with dried droplet sample pretreatment. This novel method is quantitative and especially suited to analyzing small solid samples with trace concentrations of low atomic number elements. The dried droplet pretreatment involves acid digesting the sample and allowing a droplet to dry on filter paper free of the analytes. LIBS was then performed on the dried droplet using pulsed laser ablation and spectroscopic detection from 200-1000 nm with 0.1 nm resolution. A standard addition approach was employed to quantify LIBS signals by adding known amounts of analytes into the droplets. The method was demonstrated by measuring sodium, potassium and calcium in four selected samples. All the standard addition calibration curves showed good linearity, with all regression coefficients >0.981 and relative standard deviation <5.6%. Meanwhile, the limit of detection ranges from 0.57 to 14.5 mg kg −1 and the limit of quantification ranges from 1.9 to 48 mg kg −1 . For validation, all samples were also analyzed by inductively coupled plasma mass spectrometry (ICP-MS). The relative error of LIBS compared to ICP-MS was low, <6.3% for all samples. Altogether, LIBS with dried droplet pretreatment is a promising new technique for quantitative trace element analysis of small solids. A dried droplet pre-treatment method for small solid samples containing trace elements, involving acid digestion of the sample followed by drying of a droplet on filter paper free of the analytes and quantitative elemental analysis by LIBS.
AbstractList Quantitative trace element analysis is crucial to a range of industries, including food, natural and man-made materials, and biomedicine. For this purpose, we here developed laser-induced breakdown spectroscopy (LIBS) with dried droplet sample pretreatment. This novel method is quantitative and especially suited to analyzing small solid samples with trace concentrations of low atomic number elements. The dried droplet pretreatment involves acid digesting the sample and allowing a droplet to dry on filter paper free of the analytes. LIBS was then performed on the dried droplet using pulsed laser ablation and spectroscopic detection from 200–1000 nm with 0.1 nm resolution. A standard addition approach was employed to quantify LIBS signals by adding known amounts of analytes into the droplets. The method was demonstrated by measuring sodium, potassium and calcium in four selected samples. All the standard addition calibration curves showed good linearity, with all regression coefficients >0.981 and relative standard deviation <5.6%. Meanwhile, the limit of detection ranges from 0.57 to 14.5 mg kg−1 and the limit of quantification ranges from 1.9 to 48 mg kg−1. For validation, all samples were also analyzed by inductively coupled plasma mass spectrometry (ICP-MS). The relative error of LIBS compared to ICP-MS was low, <6.3% for all samples. Altogether, LIBS with dried droplet pretreatment is a promising new technique for quantitative trace element analysis of small solids.
Quantitative trace element analysis is crucial to a range of industries, including food, natural and man-made materials, and biomedicine. For this purpose, we here developed laser-induced breakdown spectroscopy (LIBS) with dried droplet sample pretreatment. This novel method is quantitative and especially suited to analyzing small solid samples with trace concentrations of low atomic number elements. The dried droplet pretreatment involves acid digesting the sample and allowing a droplet to dry on filter paper free of the analytes. LIBS was then performed on the dried droplet using pulsed laser ablation and spectroscopic detection from 200–1000 nm with 0.1 nm resolution. A standard addition approach was employed to quantify LIBS signals by adding known amounts of analytes into the droplets. The method was demonstrated by measuring sodium, potassium and calcium in four selected samples. All the standard addition calibration curves showed good linearity, with all regression coefficients >0.981 and relative standard deviation <5.6%. Meanwhile, the limit of detection ranges from 0.57 to 14.5 mg kg −1 and the limit of quantification ranges from 1.9 to 48 mg kg −1 . For validation, all samples were also analyzed by inductively coupled plasma mass spectrometry (ICP-MS). The relative error of LIBS compared to ICP-MS was low, <6.3% for all samples. Altogether, LIBS with dried droplet pretreatment is a promising new technique for quantitative trace element analysis of small solids.
Quantitative trace element analysis is crucial to a range of industries, including food, natural and man-made materials, and biomedicine. For this purpose, we here developed laser-induced breakdown spectroscopy (LIBS) with dried droplet sample pretreatment. This novel method is quantitative and especially suited to analyzing small solid samples with trace concentrations of low atomic number elements. The dried droplet pretreatment involves acid digesting the sample and allowing a droplet to dry on filter paper free of the analytes. LIBS was then performed on the dried droplet using pulsed laser ablation and spectroscopic detection from 200-1000 nm with 0.1 nm resolution. A standard addition approach was employed to quantify LIBS signals by adding known amounts of analytes into the droplets. The method was demonstrated by measuring sodium, potassium and calcium in four selected samples. All the standard addition calibration curves showed good linearity, with all regression coefficients >0.981 and relative standard deviation <5.6%. Meanwhile, the limit of detection ranges from 0.57 to 14.5 mg kg −1 and the limit of quantification ranges from 1.9 to 48 mg kg −1 . For validation, all samples were also analyzed by inductively coupled plasma mass spectrometry (ICP-MS). The relative error of LIBS compared to ICP-MS was low, <6.3% for all samples. Altogether, LIBS with dried droplet pretreatment is a promising new technique for quantitative trace element analysis of small solids. A dried droplet pre-treatment method for small solid samples containing trace elements, involving acid digestion of the sample followed by drying of a droplet on filter paper free of the analytes and quantitative elemental analysis by LIBS.
Author Hsieh, Yi-Kong
Khan, Muhammad Shehzad
Guo, Lianbo
Lau, Condon
Wang, Chu-Fang
Hu, Zhenlin
Manno, Francis A. M
Chu, Yanwu
Liu, Yuanchao
Ahmed, Irfan
Lian, Meng
Manno, Sinai H. C
Zhang, Siyu
AuthorAffiliation Department of Biomedical Engineering and Environmental Sciences
Sukkur IBA University
Department of Biomedical Sciences
National Tsing Hua University
City University of Hong Kong
Wuhan National Laboratory for Optoelectronics (WNLO)
Huazhong University of Science and Technology
Department of Physics
Electrical Engineering Department
AuthorAffiliation_xml – name: National Tsing Hua University
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– name: Huazhong University of Science and Technology
– name: Sukkur IBA University
– name: Wuhan National Laboratory for Optoelectronics (WNLO)
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Snippet Quantitative trace element analysis is crucial to a range of industries, including food, natural and man-made materials, and biomedicine. For this purpose, we...
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Publisher
StartPage 2224
SubjectTerms Analytical chemistry
Atomic properties
Droplets
Filter paper
Inductively coupled plasma mass spectrometry
Laser ablation
Laser induced breakdown spectroscopy
Lasers
Linearity
Mass spectrometry
Pretreatment
Pulsed lasers
Regression analysis
Regression coefficients
Trace elements
Title Quantitative trace elemental analysis by laser-induced breakdown spectroscopy with dried droplet pretreatment
URI https://www.proquest.com/docview/2449460690
Volume 35
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link.rule.ids 315,783,787,27937,27938
linkProvider Royal Society of Chemistry
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