Process optimization and synthesis of lanthanum-cobalt perovskite type nanoparticles (LaCoO3) prepared by modified proteic method: Application of response surface methodology

Due to increasing interest in the application of perovskites as promising adsorbents, the present study looks at how central composite design (CCD), a subset of response surface methodology (RSM), can statistically play a role in producing optimum lanthanum oxide-cobalt perovskite type nanoparticles...

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Bibliographic Details
Published in:The Korean journal of chemical engineering 2019, 36(11), 236, pp.1826-1838
Main Authors: Garba, Zaharaddeen N., Xiao, Wei, Zhou, Weiming, Lawan, Ibrahim, Jiang, Yifan, Zhang, Mingxi, Yuan, Zhanhui
Format: Article
Language:English
Subjects:
Adsorbents
Adsorption
Aqueous solutions
Biotechnology
Catalysis
Chemistry
Chemistry and Materials Science
Cobalt
Dyes
Fourier transforms
Industrial Chemistry/Chemical Engineering
Lanthanum
Lanthanum oxides
Materials Science
Nanoparticles
Optimization
Perovskites
Point charge
Rapid Communication
Response surface methodology
Rhodamine
Roasting
Spectrophotometry
Surface chemistry
Synthesis
화학공학
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Summary:Due to increasing interest in the application of perovskites as promising adsorbents, the present study looks at how central composite design (CCD), a subset of response surface methodology (RSM), can statistically play a role in producing optimum lanthanum oxide-cobalt perovskite type nanoparticles (LaCoO 3 ) by using a modified proteic synthesis method. The optimum LaCoO 3 produced was tested for its capability in removing methyl orange (MO) and rhodamine B (RhB) dyes from aqueous solution. Calcination temperature and calcination time were optimized with the responses being percentage yield, MO and RhB removal. The best temperature and calcination time obtained were 775 °C and 62 mins, respectively, giving good and appreciable values for the three responses. The resulting optimal LaCoO 3 was characterized by Fourier transform infra-red (FTIR), ultraviolet-visible spectrophotometry (UV/vis), scanning electron microscopy (SEM), pH of zero point charge (pH pzc ) as well as BET analysis, yielding a mesoporous adsorbent with surface area of 61.130 m 2 g −1 as well as 223.55 and 239.45 mg g −1 as the monolayer adsorption capacity values for MO and RhB, respectively. Freundlich model was the best in describing the equilibrium adsorption data with respect to both MO and RhB with the kinetic data for the two dyes both obeying pseudo-second-order kinetics model.
ISSN:0256-1115
1975-7220
DOI:10.1007/s11814-019-0400-1