Application of Evolutionary Rietveld Method Based XRD Phase Analysis and a Self-Configuring Genetic Algorithm to the Inspection of Electrolyte Composition in Aluminum Electrolysis Baths

Application of Evolutionary Rietveld Method Based XRD Phase Analysis and a Self-Configuring Genetic Algorithm to the Inspection of Electrolyte Composition in Aluminum Electrolysis Baths

The technological inspection of the electrolyte composition in aluminum production is performed using calibration X-ray quantitative phase analysis (QPA). For this purpose, the use of QPA by the Rietveld method, which does not require the creation of multiphase reference samples and is able to take...

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Main Authors: Igor Yakimov, Aleksandr Zaloga, Petr Dubinin, Oksana Bezrukovа, Aleksandr Samoilo, Sergey Burakov, Eugene Semenkin, Maria Semenkina, Eugene Andruschenko
Format: Article
Language:English
Published: MDPI AG 2018-10-01
Series:Crystals
Subjects:
x-ray powder diffraction
rietveld method
quantitative XRD phase analysis
aluminum electrolyte
cryolite ratio
genetic algorithms
self-configuration
Online Access:https://www.mdpi.com/2073-4352/8/11/402
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spelling doaj-f9aa88ab018b4b758f4317f7954fdb542020-11-24T21:59:56ZengMDPI AGCrystals2073-43522018-10-0181140210.3390/cryst8110402cryst8110402Application of Evolutionary Rietveld Method Based XRD Phase Analysis and a Self-Configuring Genetic Algorithm to the Inspection of Electrolyte Composition in Aluminum Electrolysis BathsIgor Yakimov0Aleksandr Zaloga1Petr Dubinin2Oksana Bezrukovа3Aleksandr Samoilo4Sergey Burakov5Eugene Semenkin6Maria Semenkina7Eugene Andruschenko8Department of Research, Siberian Federal University, 660041 Krasnoyarsk, RussiaDepartment of Research, Siberian Federal University, 660041 Krasnoyarsk, RussiaDepartment of Research, Siberian Federal University, 660041 Krasnoyarsk, RussiaDepartment of Research, Siberian Federal University, 660041 Krasnoyarsk, RussiaDepartment of Research, Siberian Federal University, 660041 Krasnoyarsk, RussiaDepartment of Systems Analysis and Operations Research, Siberian State University of Science and Technology, 660037 Krasnoyarsk, RussiaDepartment of Systems Analysis and Operations Research, Siberian State University of Science and Technology, 660037 Krasnoyarsk, RussiaDepartment of Systems Analysis and Operations Research, Siberian State University of Science and Technology, 660037 Krasnoyarsk, RussiaDepartment of Research, Siberian Federal University, 660041 Krasnoyarsk, RussiaThe technological inspection of the electrolyte composition in aluminum production is performed using calibration X-ray quantitative phase analysis (QPA). For this purpose, the use of QPA by the Rietveld method, which does not require the creation of multiphase reference samples and is able to take into account the actual structure of the phases in the samples, could be promising. However, its limitations are in its low automation and in the problem of setting the correct initial values of profile and structural parameters. A possible solution to this problem is the application of the genetic algorithm we proposed earlier for finding suitable initial parameter values individually for each sample. However, the genetic algorithm also needs tuning. A self-configuring genetic algorithm that does not require tuning and provides a fully automatic analysis of the electrolyte composition by the Rietveld method was proposed, and successful testing results were presented.https://www.mdpi.com/2073-4352/8/11/402x-ray powder diffractionrietveld methodquantitative XRD phase analysisaluminum electrolytecryolite ratiogenetic algorithmsself-configuration
collection DOAJ
language English
format Article
sources DOAJ
author Igor Yakimov
Aleksandr Zaloga
Petr Dubinin
Oksana Bezrukovа
Aleksandr Samoilo
Sergey Burakov
Eugene Semenkin
Maria Semenkina
Eugene Andruschenko
spellingShingle Igor Yakimov
Aleksandr Zaloga
Petr Dubinin
Oksana Bezrukovа
Aleksandr Samoilo
Sergey Burakov
Eugene Semenkin
Maria Semenkina
Eugene Andruschenko
Application of Evolutionary Rietveld Method Based XRD Phase Analysis and a Self-Configuring Genetic Algorithm to the Inspection of Electrolyte Composition in Aluminum Electrolysis Baths
Crystals
x-ray powder diffraction
rietveld method
quantitative XRD phase analysis
aluminum electrolyte
cryolite ratio
genetic algorithms
self-configuration
author_facet Igor Yakimov
Aleksandr Zaloga
Petr Dubinin
Oksana Bezrukovа
Aleksandr Samoilo
Sergey Burakov
Eugene Semenkin
Maria Semenkina
Eugene Andruschenko
author_sort Igor Yakimov
title Application of Evolutionary Rietveld Method Based XRD Phase Analysis and a Self-Configuring Genetic Algorithm to the Inspection of Electrolyte Composition in Aluminum Electrolysis Baths
title_short Application of Evolutionary Rietveld Method Based XRD Phase Analysis and a Self-Configuring Genetic Algorithm to the Inspection of Electrolyte Composition in Aluminum Electrolysis Baths
title_full Application of Evolutionary Rietveld Method Based XRD Phase Analysis and a Self-Configuring Genetic Algorithm to the Inspection of Electrolyte Composition in Aluminum Electrolysis Baths
title_fullStr Application of Evolutionary Rietveld Method Based XRD Phase Analysis and a Self-Configuring Genetic Algorithm to the Inspection of Electrolyte Composition in Aluminum Electrolysis Baths
title_full_unstemmed Application of Evolutionary Rietveld Method Based XRD Phase Analysis and a Self-Configuring Genetic Algorithm to the Inspection of Electrolyte Composition in Aluminum Electrolysis Baths
title_sort application of evolutionary rietveld method based xrd phase analysis and a self-configuring genetic algorithm to the inspection of electrolyte composition in aluminum electrolysis baths
publisher MDPI AG
series Crystals
issn 2073-4352
publishDate 2018-10-01
description The technological inspection of the electrolyte composition in aluminum production is performed using calibration X-ray quantitative phase analysis (QPA). For this purpose, the use of QPA by the Rietveld method, which does not require the creation of multiphase reference samples and is able to take into account the actual structure of the phases in the samples, could be promising. However, its limitations are in its low automation and in the problem of setting the correct initial values of profile and structural parameters. A possible solution to this problem is the application of the genetic algorithm we proposed earlier for finding suitable initial parameter values individually for each sample. However, the genetic algorithm also needs tuning. A self-configuring genetic algorithm that does not require tuning and provides a fully automatic analysis of the electrolyte composition by the Rietveld method was proposed, and successful testing results were presented.
topic x-ray powder diffraction
rietveld method
quantitative XRD phase analysis
aluminum electrolyte
cryolite ratio
genetic algorithms
self-configuration
url https://www.mdpi.com/2073-4352/8/11/402
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