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Structural and Magnetic Properties of Perovskite Functional Nanomaterials La(1−x)R(x)FeO(3) (R = Co, Al, Nd, Sm) Obtained Using Sol-Gel

Perovskite is the largest mineral on earth and has a variety of excellent physical and chemical properties. La(1−x)R(x)FeO(3) (R = Co, Al, Nd, Sm) were synthesized using the sol-gel method and analyzed by XRD, TG-DTA, and VSM. With the increase in the Co(2+) doping content, the diffraction peak drif...

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Autores principales: Yang, Fang, Yang, Xingxing, Su, Kaimin, Lin, Jinpei, He, Yun, Lin, Qing
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2023
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10420255/
https://www.ncbi.nlm.nih.gov/pubmed/37570715
http://dx.doi.org/10.3390/molecules28155745
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author Yang, Fang
Yang, Xingxing
Su, Kaimin
Lin, Jinpei
He, Yun
Lin, Qing
author_facet Yang, Fang
Yang, Xingxing
Su, Kaimin
Lin, Jinpei
He, Yun
Lin, Qing
author_sort Yang, Fang
collection PubMed
description Perovskite is the largest mineral on earth and has a variety of excellent physical and chemical properties. La(1−x)R(x)FeO(3) (R = Co, Al, Nd, Sm) were synthesized using the sol-gel method and analyzed by XRD, TG-DTA, and VSM. With the increase in the Co(2+) doping content, the diffraction peak drifted in the direction of a larger angle. The grain size of La(1−x)R(x)FeO(3)(R = Co) is mainly concentrated between 50.7 and 133.5 nm. As the concentration of Co(2+) increased, the magnetic loop area and magnetization increased. La(1−x)R(x)FeO(3)(R = Al) is an orthorhombic perovskite structure, the grain size decreased with the increase in Al(3+) doping concentration, and the minimum crystallite is 17.9 nm. The magnetic loop area and magnetization increased with the increase in Al(3+) ion concentration. The enclosed area of the M-H curve of the sample decreased, and the ferromagnetic order gradually weakened and tended to be antiferromagnetic, which may be due to the increase in sintering temperature, decrease in the iron oxide composition, and changes in the magnetic properties. Proper doping can improve the magnetization of La(1−x)R(x)FeO(3)(R = Nd), refine the particles, and obtain better magnetic performance. As the Nd(3+) ion concentration increased, the magnetic properties of the samples increased. Ms of La(0.85)Co(0.15)FeO(3) prepared by different calcination time increases with the increase in calcination time. As the Sm(3+) ion concentration increased, the magnetic properties of the samples increased. Proper doping can improve the magnetization of La(1−x)R(x)FeO(3)(R = Sm), refine the particles, and generate better magnetic performance.
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spelling pubmed-104202552023-08-12 Structural and Magnetic Properties of Perovskite Functional Nanomaterials La(1−x)R(x)FeO(3) (R = Co, Al, Nd, Sm) Obtained Using Sol-Gel Yang, Fang Yang, Xingxing Su, Kaimin Lin, Jinpei He, Yun Lin, Qing Molecules Article Perovskite is the largest mineral on earth and has a variety of excellent physical and chemical properties. La(1−x)R(x)FeO(3) (R = Co, Al, Nd, Sm) were synthesized using the sol-gel method and analyzed by XRD, TG-DTA, and VSM. With the increase in the Co(2+) doping content, the diffraction peak drifted in the direction of a larger angle. The grain size of La(1−x)R(x)FeO(3)(R = Co) is mainly concentrated between 50.7 and 133.5 nm. As the concentration of Co(2+) increased, the magnetic loop area and magnetization increased. La(1−x)R(x)FeO(3)(R = Al) is an orthorhombic perovskite structure, the grain size decreased with the increase in Al(3+) doping concentration, and the minimum crystallite is 17.9 nm. The magnetic loop area and magnetization increased with the increase in Al(3+) ion concentration. The enclosed area of the M-H curve of the sample decreased, and the ferromagnetic order gradually weakened and tended to be antiferromagnetic, which may be due to the increase in sintering temperature, decrease in the iron oxide composition, and changes in the magnetic properties. Proper doping can improve the magnetization of La(1−x)R(x)FeO(3)(R = Nd), refine the particles, and obtain better magnetic performance. As the Nd(3+) ion concentration increased, the magnetic properties of the samples increased. Ms of La(0.85)Co(0.15)FeO(3) prepared by different calcination time increases with the increase in calcination time. As the Sm(3+) ion concentration increased, the magnetic properties of the samples increased. Proper doping can improve the magnetization of La(1−x)R(x)FeO(3)(R = Sm), refine the particles, and generate better magnetic performance. MDPI 2023-07-29 /pmc/articles/PMC10420255/ /pubmed/37570715 http://dx.doi.org/10.3390/molecules28155745 Text en © 2023 by the authors. https://creativecommons.org/licenses/by/4.0/Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Yang, Fang
Yang, Xingxing
Su, Kaimin
Lin, Jinpei
He, Yun
Lin, Qing
Structural and Magnetic Properties of Perovskite Functional Nanomaterials La(1−x)R(x)FeO(3) (R = Co, Al, Nd, Sm) Obtained Using Sol-Gel
title Structural and Magnetic Properties of Perovskite Functional Nanomaterials La(1−x)R(x)FeO(3) (R = Co, Al, Nd, Sm) Obtained Using Sol-Gel
title_full Structural and Magnetic Properties of Perovskite Functional Nanomaterials La(1−x)R(x)FeO(3) (R = Co, Al, Nd, Sm) Obtained Using Sol-Gel
title_fullStr Structural and Magnetic Properties of Perovskite Functional Nanomaterials La(1−x)R(x)FeO(3) (R = Co, Al, Nd, Sm) Obtained Using Sol-Gel
title_full_unstemmed Structural and Magnetic Properties of Perovskite Functional Nanomaterials La(1−x)R(x)FeO(3) (R = Co, Al, Nd, Sm) Obtained Using Sol-Gel
title_short Structural and Magnetic Properties of Perovskite Functional Nanomaterials La(1−x)R(x)FeO(3) (R = Co, Al, Nd, Sm) Obtained Using Sol-Gel
title_sort structural and magnetic properties of perovskite functional nanomaterials la(1−x)r(x)feo(3) (r = co, al, nd, sm) obtained using sol-gel
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10420255/
https://www.ncbi.nlm.nih.gov/pubmed/37570715
http://dx.doi.org/10.3390/molecules28155745
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