Development of High Energy Lithium-Ion Batteries through the Anode Side Substitution of Graphite by Si/C Composite

In this study, the investigation of high capacity and high efficiency silicon and carbon based electrodes prepared by using a wet chemical manufacturing process is presented. The active material consists of a mixture of a carbon coated silicon composite material and artificial graphite. The electrod...

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Veröffentlicht in:	ECS transactions 2017-01, Vol.75 (20), p.21-30
Hauptverfasser:	Dobrowolny, Sascha, Mahlendorf, Falko, Heinzel, Angelika
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Sprache:	eng
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creator	Dobrowolny, Sascha Mahlendorf, Falko Heinzel, Angelika
description	In this study, the investigation of high capacity and high efficiency silicon and carbon based electrodes prepared by using a wet chemical manufacturing process is presented. The active material consists of a mixture of a carbon coated silicon composite material and artificial graphite. The electrode provides a reversible capacity of about 1100 mAh⋅g-1 with a coulombic efficiency of about 99% in average for more than 300 cycles. The developed silicon carbon anode is combined with a lithium iron phosphate cathode to build lithium ion batteries. Investigations focus on the influence of the balancing of the anode and cathode in full cells on the electrochemical performance. A full cell on the basis of the developed silicon carbon anode shows improved energy density compared to a graphite-lithium iron phosphate full cell for over more than 200 cycles.
doi_str_mv	10.1149/07520.0021ecst
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title	Development of High Energy Lithium-Ion Batteries through the Anode Side Substitution of Graphite by Si/C Composite
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