Graphene assisted template based LiMn2O4 flexible cathode electrodes

Summary In this paper, a systematic method has been developed to produce highly flexible and robust graphene/LiMn2O4 (G/LMO) and graphene/LiCr0.05Mn1.95O4 (G/LCMO) free‐standing composite cathode electrodes with increased specific capacity and improved electrochemical capability. Spinel LMO nanorods...

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Veröffentlicht in:International journal of energy research 2018-07, Vol.42 (9), p.2971-2982
Hauptverfasser: Guler, Aslihan, Duman, Seyma Ozcan, Nalci, Deniz, Guzeler, Mustafa, Bulut, Emrah, Guler, Mehmet Oguz, Akbulut, Hatem
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Sprache:eng
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Zusammenfassung:Summary In this paper, a systematic method has been developed to produce highly flexible and robust graphene/LiMn2O4 (G/LMO) and graphene/LiCr0.05Mn1.95O4 (G/LCMO) free‐standing composite cathode electrodes with increased specific capacity and improved electrochemical capability. Spinel LMO nanorods are synthesized by calcination method followed by a hydrothermal reaction technique. As‐synthesized nanorods were then embedded in a graphene layer which will in turn serve as a self‐standing binder‐free cathode electrode. Spinel LMO and LCMO nanorods with a length of 600 nm and width of 50 nm were then homogenously entrapped and distributed within the layers of conductive graphene structure. This hybrid structure will help to eliminate the use of heavy metal current collectors and electrically resistant binders or even conductive additives. A discharge capacity of 114.5 mAh g−1 is obtained after first cycle and %72 capacity retention is obtained after 250 cycles from G/LCMO freestanding samples. The enhancement in the electrochemical properties is due to the unique freestanding structure of the cathode electrodes. Spinel LiCr0.05Mn1.95O4 nanorods are synthesized by calcination method followed by a hydrothermal reaction technique. As‐synthesized nanorods were then embedded in a graphene layer, which will in turn serve as a self‐standing binder‐free cathode electrode. A unique freestanding structure has shown a discharge capacity of 114.5 mAh g−1 after the first cycle and 72% capacity retention is obtained after 250 cycles.
ISSN:0363-907X
1099-114X
DOI:10.1002/er.4043