date: 2018-11-20T15:17:41Z
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pdf:docinfo:title: Synthesis of Microspherical LiFePO4-Carbon Composites for Lithium-Ion Batteries
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subject: This paper reports an ?all in one? procedure to produce mesoporous, micro-spherical LiFePO4 composed of agglomerated crystalline nanoparticles. Each nanoparticle is individually coated with a thin glucose-derived carbon layer. The main advantage of the as-synthesized materials is their good performance at high charge-discharge rates. The nanoparticles and the mesoporosity guarantee a short bulk diffusion distance for both lithium ions and electrons, as well as additional active sites for the charge transfer reactions. At the same time, the thin interconnected carbon coating provides a conductive framework capable of delivering electrons to the nanostructured LiFePO4.
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dc:title: Synthesis of Microspherical LiFePO4-Carbon Composites for Lithium-Ion Batteries
modified: 2018-11-20T15:17:41Z
cp:subject: This paper reports an ?all in one? procedure to produce mesoporous, micro-spherical LiFePO4 composed of agglomerated crystalline nanoparticles. Each nanoparticle is individually coated with a thin glucose-derived carbon layer. The main advantage of the as-synthesized materials is their good performance at high charge-discharge rates. The nanoparticles and the mesoporosity guarantee a short bulk diffusion distance for both lithium ions and electrons, as well as additional active sites for the charge transfer reactions. At the same time, the thin interconnected carbon coating provides a conductive framework capable of delivering electrons to the nanostructured LiFePO4.
pdf:docinfo:subject: This paper reports an ?all in one? procedure to produce mesoporous, micro-spherical LiFePO4 composed of agglomerated crystalline nanoparticles. Each nanoparticle is individually coated with a thin glucose-derived carbon layer. The main advantage of the as-synthesized materials is their good performance at high charge-discharge rates. The nanoparticles and the mesoporosity guarantee a short bulk diffusion distance for both lithium ions and electrons, as well as additional active sites for the charge transfer reactions. At the same time, the thin interconnected carbon coating provides a conductive framework capable of delivering electrons to the nanostructured LiFePO4.
pdf:docinfo:creator: Linghui Yu, Dandan Cai, Haihui Wang, Maria-Magdalena Titirici
meta:author: Linghui Yu, Dandan Cai, Haihui Wang, Maria-Magdalena Titirici
meta:creation-date: 2013-07-22T08:57:20Z
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Creation-Date: 2013-07-22T08:57:20Z
Author: Linghui Yu, Dandan Cai, Haihui Wang, Maria-Magdalena Titirici
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dc:description: This paper reports an ?all in one? procedure to produce mesoporous, micro-spherical LiFePO4 composed of agglomerated crystalline nanoparticles. Each nanoparticle is individually coated with a thin glucose-derived carbon layer. The main advantage of the as-synthesized materials is their good performance at high charge-discharge rates. The nanoparticles and the mesoporosity guarantee a short bulk diffusion distance for both lithium ions and electrons, as well as additional active sites for the charge transfer reactions. At the same time, the thin interconnected carbon coating provides a conductive framework capable of delivering electrons to the nanostructured LiFePO4.
Keywords: energy storage; nanomaterials; lithium-ion batteries; LiFePO4
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dc:creator: Linghui Yu, Dandan Cai, Haihui Wang, Maria-Magdalena Titirici
description: This paper reports an ?all in one? procedure to produce mesoporous, micro-spherical LiFePO4 composed of agglomerated crystalline nanoparticles. Each nanoparticle is individually coated with a thin glucose-derived carbon layer. The main advantage of the as-synthesized materials is their good performance at high charge-discharge rates. The nanoparticles and the mesoporosity guarantee a short bulk diffusion distance for both lithium ions and electrons, as well as additional active sites for the charge transfer reactions. At the same time, the thin interconnected carbon coating provides a conductive framework capable of delivering electrons to the nanostructured LiFePO4.
dcterms:created: 2013-07-22T08:57:20Z
Last-Modified: 2018-11-20T15:17:41Z
dcterms:modified: 2018-11-20T15:17:41Z
title: Synthesis of Microspherical LiFePO4-Carbon Composites for Lithium-Ion Batteries
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pdf:docinfo:keywords: energy storage; nanomaterials; lithium-ion batteries; LiFePO4
pdf:docinfo:modified: 2018-11-20T15:17:41Z
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creator: Linghui Yu, Dandan Cai, Haihui Wang, Maria-Magdalena Titirici
dc:subject: energy storage; nanomaterials; lithium-ion batteries; LiFePO4
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