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Powder Metallurgy
ArticleName Oxide powders production from iron chloride
DOI 10.17580/cisisr.2018.01.06
ArticleAuthor I. Y. Motovilov, V. A. Luganov, B. Mishra, T. A. Chepushtanova
ArticleAuthorData

Kazakh national research technical university named after K. I. Satpaev (Almaty, Kazakhstan):

I. Yu. Motovilov, Doctoral student Ph.D. in metallurgy, Chair “Metallurgical furnaces, heat engineering and technology of special materials”, e-mail: motovilov88@inbox.ru
V. A. Luganov, Dr. Eng., Prof., Chair “Metallurgical furnaces, heat engineering and technology of special materials”
T. A. Chepushtanova, Cand. Eng., Associate Prof., Head of the Chair “Metallurgical furnaces, heat engineering and technology of special materials”


Worcester polytechnic university (Worcester, MA, USA):

B. Mishra, Dr. Eng., Prof., Director of the Institute for metal processing

Abstract

This article presents the results of the high-temperature hydrolysis process of FeCl2×4H2O and the study of iron oxide powder properties produced. It is observed that the process has a topochemical character and proceeds in a diffusion zone. Conditions sufficient for practically complete decomposition of FeCl2×4H2O are a temperature in the range of 803–903 K and a duration of 40 minutes. The powder, obtained as a result of high-temperature hydrolysis of FeCl2×4H2O, is represented by an ultradisperse powder of iron oxides of 10–100 nm in size (average — 20 nm), having a basically round shape. The results of microprobe, X-ray phase analyzes, magnetic susceptibility analysis, and Mössbauer spectroscopy have revealed that the product of hightemperature hydrolysis consists of a mixture of iron oxides consisting of magnetite and hematite.

keywords Ferrous chloride, ferric chloride, hydrolysis, nanoparticles, magnetite, hematite
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Full content Oxide powders production from iron chloride
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