Preparation and Characterization of Pure-Phase Co2Y Ferrite Powders via a Scalable Aqueous Coprecipitation Method

Aqueous chemical coprecipitation methods have been developed to produce large quantities, 12 g per batch, of pure‐phase Ba2Co2Fe12O22 Y‐type hexaferrite powders. X‐ray diffraction studies showed that sintering temperatures as low as 900°C were sufficient to produce a single‐phase Y‐type hexaferrite...

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Veröffentlicht in:	Journal of the American Ceramic Society 2010-10, Vol.93 (10), p.2994-2997
Hauptverfasser:	Daigle, Andrew, DuPre', Eric, Geiler, Anton, Chen, Yajie, Parimi, Pat V., Vittoria, Carmine, Harris, Vincent G.
Format:	Artikel
Sprache:	eng
Schlagworte:	Annealing Batch production Ceramics Coprecipitation Diffraction Ferrite Magnetic properties Sintering (powder metallurgy) X-rays Yttrium
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creator	Daigle, Andrew DuPre', Eric Geiler, Anton Chen, Yajie Parimi, Pat V. Vittoria, Carmine Harris, Vincent G.
description	Aqueous chemical coprecipitation methods have been developed to produce large quantities, 12 g per batch, of pure‐phase Ba2Co2Fe12O22 Y‐type hexaferrite powders. X‐ray diffraction studies showed that sintering temperatures as low as 900°C were sufficient to produce a single‐phase Y‐type hexaferrite material. The method has also been shown to lend itself to efficient scale up, leading to large batch production. The growth of particles as a function of time and temperature in a single‐step sintering process, as opposed to multiple annealing and sintering processes required in conventional ceramic processing, was explored. Size and shape of particles have been characterized by scanning electron microscopy, while the magnetic properties were studied by vibrating sample magnetometry. Measured structural and magnetic properties are closely matched with those of bulk ceramic materials, indicating that the proposed approach may serve as a large‐scale, cost‐effective substitute to conventional ceramic processing of hexagonal ferrite materials.
doi_str_mv	10.1111/j.1551-2916.2010.03958.x
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source	Wiley Online Library Journals Frontfile Complete
subjects	Annealing Batch production Ceramics Coprecipitation Diffraction Ferrite Magnetic properties Sintering (powder metallurgy) X-rays Yttrium
title	Preparation and Characterization of Pure-Phase Co2Y Ferrite Powders via a Scalable Aqueous Coprecipitation Method
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