Publication detail

Machine learning in laser-induced breakdown spectroscopy as a novel approach towards experimental parameter optimization

PROCHAZKA, D. POŘÍZKA, P. HRUŠKA, J. NOVOTNÝ, K. HRDLIČKA, A. KAISER, J.

Original Title

Machine learning in laser-induced breakdown spectroscopy as a novel approach towards experimental parameter optimization

Type

journal article in Web of Science

Language

English

Original Abstract

Similar to other analytical techniques, the performance of laser-induced breakdown spectroscopy (LIBS) is significantly influenced by the selection of optimal experimental parameters. The optimization of LIBS is challenging because the laser-matter interaction and subsequent plasma formation are influenced not only by selected experimental parameters but also by the physical and mechanical properties of the sample. The goal of this work is to develop an artificial neural network (ANN) that is able to predict the signal-to-noise ratio (SNR) of selected spectral lines based on specific experimental parameters (laser pulse energy and gate delay) and on the sample's physical and mechanical properties. The ANN training was based on input data obtained from a high number of measurements of three certified materials with highly different mechanical and physical properties (low alloyed steel, glass, and aluminium alloy) with 2079 combinations of experimental parameters - gate delay (GD) and laser pulse energy (E). The ANN was optimized in terms of the number of neurons and hidden layers. The minimal number of input data points was studied with emphasis on the ANN prediction accuracy expressed as the determination coefficient R-2 (predicted vs. measured values). The number of input data points was studied from three points of view - a minimal number of experimental parameters for one matrix, a minimal amount of data from different matrices, and a minimal number of different spectral lines. It has been shown that at least 20 different combinations of experimental parameters are necessary for one matrix to obtain reasonable performance of the ANN. However, only ten combinations are needed when a new matrix is added to the working model. It has also been shown that the prediction accuracy is poor for spectral lines which were not part of the training data. Finally, the ANN was utilized to predict the SNR of selected spectral lines in a specific range of experimental parameters. The parameters with the maximal SNR were studied, and the values were discussed with an emphasis on sample properties. It has been concluded that the optimization process can be substituted or significantly shortened by means of the ANN.

Keywords

LIBS; Neural Network; Machine Learning; Experimental parameters

Authors

PROCHAZKA, D.; POŘÍZKA, P.; HRUŠKA, J.; NOVOTNÝ, K.; HRDLIČKA, A.; KAISER, J.

Released

27. 1. 2022

Publisher

ROYAL SOC CHEMISTRY

Location

CAMBRIDGE

ISBN

1364-5544

Periodical

Journal of Analytical Atomic Spectrometry

Year of study

2022

Number

37

State

United Kingdom of Great Britain and Northern Ireland

Pages from

603

Pages to

612

Pages count

10

URL

https://pubs.rsc.org/en/content/articlelanding/2022/JA/D1JA00389E

BibTex

@article{BUT177086,
  author="David {Prochazka} and Pavel {Pořízka} and Jakub {Hruška} and Karel {Novotný} and Aleš {Hrdlička} and Jozef {Kaiser}",
  title="Machine learning in laser-induced breakdown spectroscopy as a novel approach towards experimental parameter optimization",
  journal="Journal of Analytical Atomic Spectrometry",
  year="2022",
  volume="2022",
  number="37",
  pages="603--612",
  doi="10.1039/d1ja00389e",
  issn="1364-5544",
  url="https://pubs.rsc.org/en/content/articlelanding/2022/JA/D1JA00389E"
}