Spreading a water droplet on the laser-patterned silicon wafer substrate for surface-enhanced laser-induced breakdown spectroscopy

For effective analysis of a small amount of liquid samples such as a single-droplet, surface-enhanced laser-induced breakdown spectroscopy (LIBS) can be considered. In this method, a drop of liquid sample is placed on the solid substrate, dried, and then analyzed by LIBS. However, the dry residues a...

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Veröffentlicht in:	Spectrochimica acta. Part B: Atomic spectroscopy 2015-11, Vol.113, p.70-78
Hauptverfasser:	Bae, Dongsun, Nam, Sang-Ho, Han, Song-Hee, Yoo, Jonghyun, Lee, Yonghoon
Format:	Artikel
Sprache:	eng
Schlagworte:	Droplets Drying Laser induced breakdown Laser-induced breakdown spectroscopy Laser-patterned substrate Liquid droplet analysis Liquids Residues Sample homogeneity Silicon substrates Spectroscopy Wafers
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creator	Bae, Dongsun Nam, Sang-Ho Han, Song-Hee Yoo, Jonghyun Lee, Yonghoon
description	For effective analysis of a small amount of liquid samples such as a single-droplet, surface-enhanced laser-induced breakdown spectroscopy (LIBS) can be considered. In this method, a drop of liquid sample is placed on the solid substrate, dried, and then analyzed by LIBS. However, the dry residues are distributed inhomogeneously and moreover concentrated in a very small area on the substrate surface. This uncontrollable distribution of analytes was identified as one of the main factors deteriorating the surface-enhanced LIBS analysis performances. We demonstrated the effectiveness of a newly devised laser-patterned silicon wafer (LPSW) with 40×40 crossed 1-cm laser-produced trenches in improving the analytical performances of surface-enhanced LIBS. The LPSW substrate spreads dry residues more homogeneously in the well-defined area (1×1cm). This significantly reduces the heterogeneous saturation of the analyte and reference line intensities. In comparison with the results using bare silicon wafer substrates, linear dynamic range of the calibration curve, analysis precision, and sampling efficiency were greatly improved by the LPSW substrates. For the analysis of potassium ion dissolved in a 15-μL water droplet, the limit of detection of 0.23×10−9 mol and the analysis precision of ~4% relative standard deviation were obtained using the LPSW substrates. Consequently, the benefits from the LPSW substrates allow multiple repeatable measurements for a single aqueous solution droplet sample. •A newly devised laser-patterned silicon wafer (LPSW) substrate is applied for LIBS analysis of a water droplet.•The main cause deteriorating the LIBS analysis performances for water droplets was identified.•Strong hydrophilic interaction between the LPSW surface and water droplet was understood.•K in a 15-μL water droplet was analyzed with a LOD of 230 picomoles and 2–6% RSDs.
doi_str_mv	10.1016/j.sab.2015.09.005
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Part B: Atomic spectroscopy</title><description>For effective analysis of a small amount of liquid samples such as a single-droplet, surface-enhanced laser-induced breakdown spectroscopy (LIBS) can be considered. In this method, a drop of liquid sample is placed on the solid substrate, dried, and then analyzed by LIBS. However, the dry residues are distributed inhomogeneously and moreover concentrated in a very small area on the substrate surface. This uncontrollable distribution of analytes was identified as one of the main factors deteriorating the surface-enhanced LIBS analysis performances. We demonstrated the effectiveness of a newly devised laser-patterned silicon wafer (LPSW) with 40×40 crossed 1-cm laser-produced trenches in improving the analytical performances of surface-enhanced LIBS. The LPSW substrate spreads dry residues more homogeneously in the well-defined area (1×1cm). 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subjects	Droplets Drying Laser induced breakdown Laser-induced breakdown spectroscopy Laser-patterned substrate Liquid droplet analysis Liquids Residues Sample homogeneity Silicon substrates Spectroscopy Wafers
title	Spreading a water droplet on the laser-patterned silicon wafer substrate for surface-enhanced laser-induced breakdown spectroscopy
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