Synthesis of micro-FeTi powders by direct electrochemical reduction of ilmenite in CaCl2-NaCl molten salt

Micro-ferrotitanium powders have been prepared by molten salt electrolysis via directly electrochemical reduction of solid ilmenite in eutectic CaCl 2 -NaCl melt at 973 K. In the direct electrochemical reduction process, the reduction of FeTiO 3 first gives rise to the formation of Fe and CaTiO 3 ,...

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Veröffentlicht in:	Ionics 2017-01, Vol.23 (1), p.213-221
Hauptverfasser:	Zhou, Zhongren, Hua, Yixin, Xu, Cunying, Li, Jian, Li, Yan, Zhang, Qibo, Zhang, Yadong, Kuang, Wenhao
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Sprache:	eng
Schlagworte:	Calcium chloride Chemistry Chemistry and Materials Science Condensed Matter Physics Electrochemistry Energy Storage Optical and Electronic Materials Original Paper Renewable and Green Energy
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description	Micro-ferrotitanium powders have been prepared by molten salt electrolysis via directly electrochemical reduction of solid ilmenite in eutectic CaCl 2 -NaCl melt at 973 K. In the direct electrochemical reduction process, the reduction of FeTiO 3 first gives rise to the formation of Fe and CaTiO 3 , which as intermediates will be further deoxidized at the interface of iron metals, solid CaTiO 3 matrix, and electrolyte to directly form ferrotitanium alloy powders in porous structure. Furthering the electrolytic time can promote the dense structure of ilmenite pellet turn to be more porous, indicating pores inside the pellet are sufficient for the diffusion of oxygen ions. Based on the reduction behavior of partially reduced powders in metallic cavity electrode during the cathodic potentiostatic electrolysis, it shows that the slow deoxidization rate is mainly caused by the more and more difficult reduction of CaTiO 3 than that of FeTiO 3 .
doi_str_mv	10.1007/s11581-016-1810-2
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In the direct electrochemical reduction process, the reduction of FeTiO 3 first gives rise to the formation of Fe and CaTiO 3 , which as intermediates will be further deoxidized at the interface of iron metals, solid CaTiO 3 matrix, and electrolyte to directly form ferrotitanium alloy powders in porous structure. Furthering the electrolytic time can promote the dense structure of ilmenite pellet turn to be more porous, indicating pores inside the pellet are sufficient for the diffusion of oxygen ions. 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In the direct electrochemical reduction process, the reduction of FeTiO 3 first gives rise to the formation of Fe and CaTiO 3 , which as intermediates will be further deoxidized at the interface of iron metals, solid CaTiO 3 matrix, and electrolyte to directly form ferrotitanium alloy powders in porous structure. Furthering the electrolytic time can promote the dense structure of ilmenite pellet turn to be more porous, indicating pores inside the pellet are sufficient for the diffusion of oxygen ions. Based on the reduction behavior of partially reduced powders in metallic cavity electrode during the cathodic potentiostatic electrolysis, it shows that the slow deoxidization rate is mainly caused by the more and more difficult reduction of CaTiO 3 than that of FeTiO 3 .</abstract><cop>Berlin/Heidelberg</cop><pub>Springer Berlin Heidelberg</pub><doi>10.1007/s11581-016-1810-2</doi><tpages>9</tpages></addata></record>
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subjects	Calcium chloride Chemistry Chemistry and Materials Science Condensed Matter Physics Electrochemistry Energy Storage Optical and Electronic Materials Original Paper Renewable and Green Energy
title	Synthesis of micro-FeTi powders by direct electrochemical reduction of ilmenite in CaCl2-NaCl molten salt
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