C-containing LiFePO4 materials — Part I: Mechano-chemical synthesis and structural characterization

C-LiFePO4 composites were synthesized by mechano-chemical activation using iron and lithium phosphates, and also cellulose as carbon precursor; this mixture was treated with 2 thermal treatments ('slow' or 'fast'treatment) and 2 temperatures (575 deg C or 800 deg C). The four syn...

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Veröffentlicht in:	Solid state ionics 2008-10, Vol.179 (35-36), p.2020-2026
Hauptverfasser:	MACCARIO, M, CROGUENNEC, L, WATTIAUX, A, SUARD, E, LECRAS, F, DELMAS, C
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Sprache:	eng
Schlagworte:	Chemical Sciences Material chemistry
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container_end_page	2026
container_issue	35-36
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container_title	Solid state ionics
container_volume	179
creator	MACCARIO, M CROGUENNEC, L WATTIAUX, A SUARD, E LECRAS, F DELMAS, C
description	C-LiFePO4 composites were synthesized by mechano-chemical activation using iron and lithium phosphates, and also cellulose as carbon precursor; this mixture was treated with 2 thermal treatments ('slow' or 'fast'treatment) and 2 temperatures (575 deg C or 800 deg C). The four synthesized samples were pure olivine-type materials (XRD), but chemical analyses and Mossbauer spectroscopy show Li/Fe and P/Fe ratios larger than 1 and the presence of 5-6 at.% of Fe3+. Three hypotheses were considered to explain the presence of Fe3+ ions: (i) a chemical formula Li1 + xFe1 - xPO4 for the olivine-type phase, (ii) a mixture of olivine-type LiFePO4 and Fe3+ containing impuritie(s) or (iii) LiFePO4 with Fe3+ surface defects. These hypotheses were checked using different characterization methods such as X-ray diffraction, neutron diffraction and magnetic measurements, hypothesis (i) was shown not to be valid but none of hypotheses (ii) and (iii) was definitely confirmed. One can assume either the presence of a Fe3+-rich phase (amorphous or nanocrystalline) or the occurrence of surface defects which can play a significant role as far as nanomaterials are concerned.
doi_str_mv	10.1016/j.ssi.2008.07.004
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title	C-containing LiFePO4 materials — Part I: Mechano-chemical synthesis and structural characterization
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