Structural, magnetic and dielectric features of Cu, Al substituted Ca-hexaferrites for magnetic and energy applications

M. M. Moharam; I. Ahmad; G. F.B. Solre; S. U. Asif; E. A.M. Saleh

doi:10.1007/s12648-024-03534-4

Structural, magnetic and dielectric features of Cu, Al substituted Ca-hexaferrites for magnetic and energy applications

M. M. Moharam, I. Ahmad, G. F.B. Solre, S. U. Asif, E. A.M. Saleh

Chemistry

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

4 Scopus citations

Abstract

The sol–gel method was used in our work to develop Ca_1-xCu_xFe_12-xAl_xO₁₉ (x = 0.0, 0.05, 0.10, 0.15, 0.20) hexaferrites nanoparticles. The microstructure, phase, and magnetic characteristics of the samples were examined relative to different doping concentrations using SEM, XRD, and VSM techniques. The analysis indicates the presence of Fe₂O₃ phases in all samples. The lattice parameters ‘a’ and ‘c’ were initially reduced and then enhanced with doping level. Similarly, the average crystallite size showed a decline continuously. The remanence as well as saturation magnetization both decline first with the doping level and then rise after reaching their minimum values at x = 0.15. Analogously, as the doping level is raised, the coercivity as well as magneto-crystalline anisotropy field first declines and then increases. The sample with the best magnetic properties is Ca_0.85Cu_0.15Fe_11.85Al_0.15O₁₉ with M_s = 27.954 emu/g, m_B(µ_B) = 5.117B, M_r = 15.676 emu/g, M_r/M_s = 0.577, H_c = 2.726 kOe, and H_a = 0.852 kOe. Dielectric properties suggested the decrease in loss and enhancement in the dielectric constant. Results recommend that M-type hexagonal ferrites could be well adjusted for numerous magnetic usages such as magnetic filters, storage devices and high-performance self-biased circulators and energy applications.

Original language	English
Pages (from-to)	2917-2928
Number of pages	12
Journal	Indian Journal of Physics
Volume	99
Issue number	8
DOIs	https://doi.org/10.1007/s12648-024-03534-4
State	Published - Jul 2025

Keywords

Energy and Industry
Energy storage
Hexaferrites
SDG roadmap
Sustainable development goals

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1007/s12648-024-03534-4

Cite this

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title = "Structural, magnetic and dielectric features of Cu, Al substituted Ca-hexaferrites for magnetic and energy applications",

abstract = "The sol–gel method was used in our work to develop Ca1-xCuxFe12-xAlxO19 (x = 0.0, 0.05, 0.10, 0.15, 0.20) hexaferrites nanoparticles. The microstructure, phase, and magnetic characteristics of the samples were examined relative to different doping concentrations using SEM, XRD, and VSM techniques. The analysis indicates the presence of Fe2O3 phases in all samples. The lattice parameters {\textquoteleft}a{\textquoteright} and {\textquoteleft}c{\textquoteright} were initially reduced and then enhanced with doping level. Similarly, the average crystallite size showed a decline continuously. The remanence as well as saturation magnetization both decline first with the doping level and then rise after reaching their minimum values at x = 0.15. Analogously, as the doping level is raised, the coercivity as well as magneto-crystalline anisotropy field first declines and then increases. The sample with the best magnetic properties is Ca0.85Cu0.15Fe11.85Al0.15O19 with Ms = 27.954 emu/g, mB(µB) = 5.117B, Mr = 15.676 emu/g, Mr/Ms = 0.577, Hc = 2.726 kOe, and Ha = 0.852 kOe. Dielectric properties suggested the decrease in loss and enhancement in the dielectric constant. Results recommend that M-type hexagonal ferrites could be well adjusted for numerous magnetic usages such as magnetic filters, storage devices and high-performance self-biased circulators and energy applications.",

keywords = "Energy and Industry, Energy storage, Hexaferrites, SDG roadmap, Sustainable development goals",

author = "Moharam, \{M. M.\} and I. Ahmad and Solre, \{G. F.B.\} and Asif, \{S. U.\} and Saleh, \{E. A.M.\}",

note = "Publisher Copyright: {\textcopyright} Indian Association for the Cultivation of Science 2025.",

year = "2025",

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doi = "10.1007/s12648-024-03534-4",

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T1 - Structural, magnetic and dielectric features of Cu, Al substituted Ca-hexaferrites for magnetic and energy applications

AU - Moharam, M. M.

AU - Ahmad, I.

AU - Solre, G. F.B.

AU - Asif, S. U.

AU - Saleh, E. A.M.

N1 - Publisher Copyright: © Indian Association for the Cultivation of Science 2025.

PY - 2025/7

Y1 - 2025/7

N2 - The sol–gel method was used in our work to develop Ca1-xCuxFe12-xAlxO19 (x = 0.0, 0.05, 0.10, 0.15, 0.20) hexaferrites nanoparticles. The microstructure, phase, and magnetic characteristics of the samples were examined relative to different doping concentrations using SEM, XRD, and VSM techniques. The analysis indicates the presence of Fe2O3 phases in all samples. The lattice parameters ‘a’ and ‘c’ were initially reduced and then enhanced with doping level. Similarly, the average crystallite size showed a decline continuously. The remanence as well as saturation magnetization both decline first with the doping level and then rise after reaching their minimum values at x = 0.15. Analogously, as the doping level is raised, the coercivity as well as magneto-crystalline anisotropy field first declines and then increases. The sample with the best magnetic properties is Ca0.85Cu0.15Fe11.85Al0.15O19 with Ms = 27.954 emu/g, mB(µB) = 5.117B, Mr = 15.676 emu/g, Mr/Ms = 0.577, Hc = 2.726 kOe, and Ha = 0.852 kOe. Dielectric properties suggested the decrease in loss and enhancement in the dielectric constant. Results recommend that M-type hexagonal ferrites could be well adjusted for numerous magnetic usages such as magnetic filters, storage devices and high-performance self-biased circulators and energy applications.

AB - The sol–gel method was used in our work to develop Ca1-xCuxFe12-xAlxO19 (x = 0.0, 0.05, 0.10, 0.15, 0.20) hexaferrites nanoparticles. The microstructure, phase, and magnetic characteristics of the samples were examined relative to different doping concentrations using SEM, XRD, and VSM techniques. The analysis indicates the presence of Fe2O3 phases in all samples. The lattice parameters ‘a’ and ‘c’ were initially reduced and then enhanced with doping level. Similarly, the average crystallite size showed a decline continuously. The remanence as well as saturation magnetization both decline first with the doping level and then rise after reaching their minimum values at x = 0.15. Analogously, as the doping level is raised, the coercivity as well as magneto-crystalline anisotropy field first declines and then increases. The sample with the best magnetic properties is Ca0.85Cu0.15Fe11.85Al0.15O19 with Ms = 27.954 emu/g, mB(µB) = 5.117B, Mr = 15.676 emu/g, Mr/Ms = 0.577, Hc = 2.726 kOe, and Ha = 0.852 kOe. Dielectric properties suggested the decrease in loss and enhancement in the dielectric constant. Results recommend that M-type hexagonal ferrites could be well adjusted for numerous magnetic usages such as magnetic filters, storage devices and high-performance self-biased circulators and energy applications.

KW - Energy and Industry

KW - Energy storage

KW - Hexaferrites

KW - SDG roadmap

KW - Sustainable development goals

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