Densification of MnZn ferrite sintered under multi-physical field coupling

Ankang Du, Gang Yang, Dong Lu, Yi Qin, Yi Yang

Research output: Contribution to journalArticle

2 Citations (Scopus)

Abstract

This work provides a novel idea of fabricating MnZn bulk ferrite materials. MnZn ferrite powders with a composition of Zn0.8Mn0.2Fe2O4 (wt%) are sintered to form cylindrical bulk ferrite with diameters of 1.0mm, and heights of 1.0mm under multi-physical field coupling with Gleeble-1500D thermal simulation instrument. The results show that sintered ferrite has a spinel structure, and that some magnetic properties like maximum energy product and remanence of the Multi-physical Field Coupling sintered sample are better than that obtained by conventional sintering. Densification process and solid phase reaction are promoted by alternating magnetic field and high frequency wave generated by AC current.
LanguageEnglish
Pages212-217
Number of pages6
JournalApplied Mechanics and Materials
Volume271-272
DOIs
Publication statusPublished - 2013

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Densification
Ferrite
Remanence
Powders
Magnetic properties
Sintering
Magnetic fields
Chemical analysis

Keywords

  • densification
  • MnZn ferrite sintered
  • multi-physical
  • field coupling

Cite this

Du, Ankang ; Yang, Gang ; Lu, Dong ; Qin, Yi ; Yang, Yi . / Densification of MnZn ferrite sintered under multi-physical field coupling. In: Applied Mechanics and Materials. 2013 ; Vol. 271-272. pp. 212-217.
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Densification of MnZn ferrite sintered under multi-physical field coupling. / Du, Ankang; Yang, Gang; Lu, Dong; Qin, Yi; Yang, Yi .

In: Applied Mechanics and Materials, Vol. 271-272, 2013, p. 212-217.

Research output: Contribution to journalArticle

TY - JOUR

T1 - Densification of MnZn ferrite sintered under multi-physical field coupling

AU - Du, Ankang

AU - Yang, Gang

AU - Lu, Dong

AU - Qin, Yi

AU - Yang, Yi

PY - 2013

Y1 - 2013

N2 - This work provides a novel idea of fabricating MnZn bulk ferrite materials. MnZn ferrite powders with a composition of Zn0.8Mn0.2Fe2O4 (wt%) are sintered to form cylindrical bulk ferrite with diameters of 1.0mm, and heights of 1.0mm under multi-physical field coupling with Gleeble-1500D thermal simulation instrument. The results show that sintered ferrite has a spinel structure, and that some magnetic properties like maximum energy product and remanence of the Multi-physical Field Coupling sintered sample are better than that obtained by conventional sintering. Densification process and solid phase reaction are promoted by alternating magnetic field and high frequency wave generated by AC current.

AB - This work provides a novel idea of fabricating MnZn bulk ferrite materials. MnZn ferrite powders with a composition of Zn0.8Mn0.2Fe2O4 (wt%) are sintered to form cylindrical bulk ferrite with diameters of 1.0mm, and heights of 1.0mm under multi-physical field coupling with Gleeble-1500D thermal simulation instrument. The results show that sintered ferrite has a spinel structure, and that some magnetic properties like maximum energy product and remanence of the Multi-physical Field Coupling sintered sample are better than that obtained by conventional sintering. Densification process and solid phase reaction are promoted by alternating magnetic field and high frequency wave generated by AC current.

KW - densification

KW - MnZn ferrite sintered

KW - multi-physical

KW - field coupling

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DO - 10.4028/www.scientific.net/AMM.271-272.212

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