Sono electro-chemical synthesis of LaFeO3nanoparticles for the removal of fluoride: Optimization and modeling using RSM, ANN and GA tools

Shahin Ahmadi; Mohammad Mesbah; Chinenye Adaobi Igwegbe; Chukwuemeka Daniel Ezeliora; Christian Osagie; Nadeem A. Khan; Guilherme L. Dotto; Mehdi Salari; Mohammad Hadi Dehghani

doi:10.1016/j.jece.2021.105320

Sono electro-chemical synthesis of LaFeO₃nanoparticles for the removal of fluoride: Optimization and modeling using RSM, ANN and GA tools

Shahin Ahmadi, Mohammad Mesbah, Chinenye Adaobi Igwegbe^*, Chukwuemeka Daniel Ezeliora, Christian Osagie, Nadeem A. Khan, Guilherme L. Dotto, Mehdi Salari, Mohammad Hadi Dehghani^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

101 Scopus citations

Abstract

The aim of this work was to model, optimize, and compare fluoride removal by LaFeO3-NPs using the RSM (Response Surface Methodology), ANN (Artificial Neural Network), and GA (Genetic Algorithm) techniques.The input variables considered were pH, time, temperature, LaFeO3-NPs dose, and fluoride. The CCD (central composite design) plan was exercised for the analysis of RSM, and ANN to determine their capabilities of prediction of the response. Their performances were evaluated using the regression coefficient (R2), RMSE, SEP, and the AAD. Also, RSM and GA were used to maximize the response and their optimum conditions evaluated. Both RSM (R2 = 0.9970, AAD = 0.00001, RMSE = 0.0037, SEP = 0.0042) and ANN (R2 = 0.9919, AAD = 0.00044, RMSE = 0.0066, SEP = 0.0074) gave high degree of accuracy. The model equation obtained for the process through RSM was adequate. The GA and RSM gave very close values for the optimization of the fluoride reduction process; RSM gave optimum fluoride removal of 96.35% (at pH 8.6, time = 75.03 min, temperature = 34.9 °C, dose = 0.225 g, and concentration = 23.68 mg L-1) while the GA gave 96.30% (at pH 10, time = 120.39 min, temperature = 28.41 °C, dose = 1.030 g, and concentration = 16.31 mg L-1). But from the confirmation experiments, RSM and GA data gave 96.52% and 96.63%, respectively. RSM, ANN, and GA were capable of modeling and optimizing the elimination of fluoride using LaFeO3-NPs.

Original language	English
Article number	105320
Journal	Journal of Environmental Chemical Engineering
Volume	9
Issue number	4
DOIs	https://doi.org/10.1016/j.jece.2021.105320
State	Published - Aug 2021
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2021 Elsevier Ltd.

Keywords

Adsorption
Central composite design
Fluoride
Genetic algorithm
Nanoparticles
Neural network

ASJC Scopus subject areas

Chemical Engineering (miscellaneous)
Waste Management and Disposal
Pollution
Process Chemistry and Technology

Access to Document

10.1016/j.jece.2021.105320

Cite this

Ahmadi, S., Mesbah, M., Igwegbe, C. A., Ezeliora, C. D., Osagie, C., Khan, N. A., Dotto, G. L., Salari, M., & Dehghani, M. H. (2021). Sono electro-chemical synthesis of LaFeO₃nanoparticles for the removal of fluoride: Optimization and modeling using RSM, ANN and GA tools. Journal of Environmental Chemical Engineering, 9(4), Article 105320. https://doi.org/10.1016/j.jece.2021.105320

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title = "Sono electro-chemical synthesis of LaFeO3nanoparticles for the removal of fluoride: Optimization and modeling using RSM, ANN and GA tools",

abstract = "The aim of this work was to model, optimize, and compare fluoride removal by LaFeO3-NPs using the RSM (Response Surface Methodology), ANN (Artificial Neural Network), and GA (Genetic Algorithm) techniques.The input variables considered were pH, time, temperature, LaFeO3-NPs dose, and fluoride. The CCD (central composite design) plan was exercised for the analysis of RSM, and ANN to determine their capabilities of prediction of the response. Their performances were evaluated using the regression coefficient (R2), RMSE, SEP, and the AAD. Also, RSM and GA were used to maximize the response and their optimum conditions evaluated. Both RSM (R2 = 0.9970, AAD = 0.00001, RMSE = 0.0037, SEP = 0.0042) and ANN (R2 = 0.9919, AAD = 0.00044, RMSE = 0.0066, SEP = 0.0074) gave high degree of accuracy. The model equation obtained for the process through RSM was adequate. The GA and RSM gave very close values for the optimization of the fluoride reduction process; RSM gave optimum fluoride removal of 96.35\% (at pH 8.6, time = 75.03 min, temperature = 34.9 °C, dose = 0.225 g, and concentration = 23.68 mg L-1) while the GA gave 96.30\% (at pH 10, time = 120.39 min, temperature = 28.41 °C, dose = 1.030 g, and concentration = 16.31 mg L-1). But from the confirmation experiments, RSM and GA data gave 96.52\% and 96.63\%, respectively. RSM, ANN, and GA were capable of modeling and optimizing the elimination of fluoride using LaFeO3-NPs.",

keywords = "Adsorption, Central composite design, Fluoride, Genetic algorithm, Nanoparticles, Neural network",

author = "Shahin Ahmadi and Mohammad Mesbah and Igwegbe, \{Chinenye Adaobi\} and Ezeliora, \{Chukwuemeka Daniel\} and Christian Osagie and Khan, \{Nadeem A.\} and Dotto, \{Guilherme L.\} and Mehdi Salari and Dehghani, \{Mohammad Hadi\}",

note = "Publisher Copyright: {\textcopyright} 2021 Elsevier Ltd.",

year = "2021",

month = aug,

doi = "10.1016/j.jece.2021.105320",

language = "English",

volume = "9",

journal = "Journal of Environmental Chemical Engineering",

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T1 - Sono electro-chemical synthesis of LaFeO3nanoparticles for the removal of fluoride

T2 - Optimization and modeling using RSM, ANN and GA tools

AU - Ahmadi, Shahin

AU - Mesbah, Mohammad

AU - Igwegbe, Chinenye Adaobi

AU - Ezeliora, Chukwuemeka Daniel

AU - Osagie, Christian

AU - Khan, Nadeem A.

AU - Dotto, Guilherme L.

AU - Salari, Mehdi

AU - Dehghani, Mohammad Hadi

PY - 2021/8

Y1 - 2021/8

N2 - The aim of this work was to model, optimize, and compare fluoride removal by LaFeO3-NPs using the RSM (Response Surface Methodology), ANN (Artificial Neural Network), and GA (Genetic Algorithm) techniques.The input variables considered were pH, time, temperature, LaFeO3-NPs dose, and fluoride. The CCD (central composite design) plan was exercised for the analysis of RSM, and ANN to determine their capabilities of prediction of the response. Their performances were evaluated using the regression coefficient (R2), RMSE, SEP, and the AAD. Also, RSM and GA were used to maximize the response and their optimum conditions evaluated. Both RSM (R2 = 0.9970, AAD = 0.00001, RMSE = 0.0037, SEP = 0.0042) and ANN (R2 = 0.9919, AAD = 0.00044, RMSE = 0.0066, SEP = 0.0074) gave high degree of accuracy. The model equation obtained for the process through RSM was adequate. The GA and RSM gave very close values for the optimization of the fluoride reduction process; RSM gave optimum fluoride removal of 96.35% (at pH 8.6, time = 75.03 min, temperature = 34.9 °C, dose = 0.225 g, and concentration = 23.68 mg L-1) while the GA gave 96.30% (at pH 10, time = 120.39 min, temperature = 28.41 °C, dose = 1.030 g, and concentration = 16.31 mg L-1). But from the confirmation experiments, RSM and GA data gave 96.52% and 96.63%, respectively. RSM, ANN, and GA were capable of modeling and optimizing the elimination of fluoride using LaFeO3-NPs.

AB - The aim of this work was to model, optimize, and compare fluoride removal by LaFeO3-NPs using the RSM (Response Surface Methodology), ANN (Artificial Neural Network), and GA (Genetic Algorithm) techniques.The input variables considered were pH, time, temperature, LaFeO3-NPs dose, and fluoride. The CCD (central composite design) plan was exercised for the analysis of RSM, and ANN to determine their capabilities of prediction of the response. Their performances were evaluated using the regression coefficient (R2), RMSE, SEP, and the AAD. Also, RSM and GA were used to maximize the response and their optimum conditions evaluated. Both RSM (R2 = 0.9970, AAD = 0.00001, RMSE = 0.0037, SEP = 0.0042) and ANN (R2 = 0.9919, AAD = 0.00044, RMSE = 0.0066, SEP = 0.0074) gave high degree of accuracy. The model equation obtained for the process through RSM was adequate. The GA and RSM gave very close values for the optimization of the fluoride reduction process; RSM gave optimum fluoride removal of 96.35% (at pH 8.6, time = 75.03 min, temperature = 34.9 °C, dose = 0.225 g, and concentration = 23.68 mg L-1) while the GA gave 96.30% (at pH 10, time = 120.39 min, temperature = 28.41 °C, dose = 1.030 g, and concentration = 16.31 mg L-1). But from the confirmation experiments, RSM and GA data gave 96.52% and 96.63%, respectively. RSM, ANN, and GA were capable of modeling and optimizing the elimination of fluoride using LaFeO3-NPs.

KW - Adsorption

KW - Central composite design

KW - Fluoride

KW - Genetic algorithm

KW - Nanoparticles

KW - Neural network

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U2 - 10.1016/j.jece.2021.105320

DO - 10.1016/j.jece.2021.105320

M3 - Article

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