• Home
  • Browse
    • Current Issue
    • By Issue
    • By Author
    • By Subject
    • Author Index
    • Keyword Index
  • Journal Info
    • About Journal
    • Aims and Scope
    • Editorial Board
    • Editorial Staff
    • Publication Ethics
    • Indexing and Abstracting
    • Related Links
    • FAQ
    • Peer Review Process
    • News
  • Guide for Authors
  • Submit Manuscript
  • Reviewers
  • Contact Us
 
  • Login
  • Register
Home Articles List Article Information
  • Save Records
  • |
  • Printable Version
  • |
  • Recommend
  • |
  • How to cite Export to
    RIS EndNote BibTeX APA MLA Harvard Vancouver
  • |
  • Share Share
    CiteULike Mendeley Facebook Google LinkedIn Twitter
Arab Journal of Nuclear Sciences and Applications
Articles in Press
Current Issue
Journal Archive
Volume Volume 52 (2019)
Volume Volume 51 (2018)
Issue Issue 4
Issue Issue 3
Issue Issue 2
Hemeda, O., Tawfik, A., Henaish, A., Salem, B. (2018). Strong correlations between Structural and Magnetic Properties of Zn and Zr Substituted CuFe2O4 for Magnetic Temperature Controller applications. Arab Journal of Nuclear Sciences and Applications, 51(3), 22-31. doi: 10.21608/ajnsa.2018.1933.1005
Osama Hemeda; AbdElraouf Tawfik; Ahmed Maher Henaish; Basant Salem. "Strong correlations between Structural and Magnetic Properties of Zn and Zr Substituted CuFe2O4 for Magnetic Temperature Controller applications". Arab Journal of Nuclear Sciences and Applications, 51, 3, 2018, 22-31. doi: 10.21608/ajnsa.2018.1933.1005
Hemeda, O., Tawfik, A., Henaish, A., Salem, B. (2018). 'Strong correlations between Structural and Magnetic Properties of Zn and Zr Substituted CuFe2O4 for Magnetic Temperature Controller applications', Arab Journal of Nuclear Sciences and Applications, 51(3), pp. 22-31. doi: 10.21608/ajnsa.2018.1933.1005
Hemeda, O., Tawfik, A., Henaish, A., Salem, B. Strong correlations between Structural and Magnetic Properties of Zn and Zr Substituted CuFe2O4 for Magnetic Temperature Controller applications. Arab Journal of Nuclear Sciences and Applications, 2018; 51(3): 22-31. doi: 10.21608/ajnsa.2018.1933.1005

Strong correlations between Structural and Magnetic Properties of Zn and Zr Substituted CuFe2O4 for Magnetic Temperature Controller applications

Article 3, Volume 51, Issue 3, July 2018, Page 22-31  XML PDF (499.93 K)
Document Type: Original Article
DOI: 10.21608/ajnsa.2018.1933.1005
Authors
Osama Hemeda; AbdElraouf Tawfik; Ahmed Maher Henaish email ; Basant Salem
Physics Department, Faculty of Science, Tanta University, Egypt
Abstract
The effects of tetravalent and divalent substitution on the physical properties of Cu ferrites prepared by double sintering ceramic technique have been investigated. It was found that substitution of Zn and Zr enhanced simultaneously sintering process and crystallization. The initial permeability drops sharply at certain temperature for stoichiometric composition, which make Zn/Zr co-doped NiFe2O4 spinel ferrites a very promising candidate for magnetic switch, magnetic temperature transducer (MTT) and temperature sensitive controller devices. So we can control the change of Curie temperature by simply controlling the contents of Zn and Zr within CuFe2O4. From magnetic hysteresis loop measurements, magnetic moment increases by Zn and Zr substitution.
The chemical composition heat treatment and type of substituted ions affect the intrinsic parameters of ferrites such as magnetization, initial permeability, Curie temperature, grain size and structural properties strongly [1]. The hysteresis loop is influenced by defects that retard the magnetic domain wall motion within the grains [2]. CuFe2O4 compound is a sheep material and has important magnetic and electrical properties for various technological applications.
The affect of Zn and Zr additives on the structure and magnetic properties of LiZnFe2O4 were reported [3].
Keywords
CuFe2O4; stoichiometric composition; XRD; SEM; Magnetic properties
Statistics
Article View: 199
PDF Download: 93
Home | Glossary | News | Aims and Scope | Sitemap
Top Top

Journal Management System. Designed by NotionWave.