An electrochemical evaluation of nitrogen-doped carbons as anodes for lithium ion batteries

New anode materials beyond graphite are needed to improve the performance of lithium ion batteries (LIBs). Chemical doping with nitrogen has emerged as a simple strategy for enhancing lithium storage in carbon-based anodes. While specific capacity and rate capability are improved by doping, little i...

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Veröffentlicht in:	Carbon (New York) 2020-08, Vol.164, p.261-271
Hauptverfasser:	Gomez-Martin, A., Martinez-Fernandez, J., Ruttert, Mirco, Winter, Martin, Placke, Tobias, Ramirez-Rico, J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Anodes Batteries Carbon Charge density Charge efficiency Cycles Discharge Doping Electric potential Electrochemical analysis Electrode materials Energy consumption Graphite Lithium Lithium-ion batteries Nitrogen Performance enhancement Rechargeable batteries Stability analysis Voltage
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creator	Gomez-Martin, A. Martinez-Fernandez, J. Ruttert, Mirco Winter, Martin Placke, Tobias Ramirez-Rico, J.
description	New anode materials beyond graphite are needed to improve the performance of lithium ion batteries (LIBs). Chemical doping with nitrogen has emerged as a simple strategy for enhancing lithium storage in carbon-based anodes. While specific capacity and rate capability are improved by doping, little is known about other key electrochemical properties relevant to practical applications. This work presents a systematic evaluation of electrochemical characteristics of nitrogen-doped carbons derived from a biomass source and urea powder as anodes in LIB half- and full-cells. Results show that doped carbons suffer from a continuous loss in capacity upon cycling that is more severe for higher nitrogen contents. Nitrogen negatively impacts the voltage and energy efficiencies at low charge/discharge current densities. However, as the charge/discharge rate increases, the voltage and energy efficiencies of the doped carbons outperform the non-doped ones. We provide insights towards a fundamental understanding of the requirements needed for practical applications and reveal drawbacks to be overcome by novel doped carbon-based anode materials in LIB applications. With this work, we also want to encourage other researchers to evaluate electrochemical characteristics besides capacity and cycling stability which are mandatory to assess the practicality of novel materials. [Display omitted]
doi_str_mv	10.1016/j.carbon.2020.04.003
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Chemical doping with nitrogen has emerged as a simple strategy for enhancing lithium storage in carbon-based anodes. While specific capacity and rate capability are improved by doping, little is known about other key electrochemical properties relevant to practical applications. This work presents a systematic evaluation of electrochemical characteristics of nitrogen-doped carbons derived from a biomass source and urea powder as anodes in LIB half- and full-cells. Results show that doped carbons suffer from a continuous loss in capacity upon cycling that is more severe for higher nitrogen contents. Nitrogen negatively impacts the voltage and energy efficiencies at low charge/discharge current densities. However, as the charge/discharge rate increases, the voltage and energy efficiencies of the doped carbons outperform the non-doped ones. We provide insights towards a fundamental understanding of the requirements needed for practical applications and reveal drawbacks to be overcome by novel doped carbon-based anode materials in LIB applications. With this work, we also want to encourage other researchers to evaluate electrochemical characteristics besides capacity and cycling stability which are mandatory to assess the practicality of novel materials. 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We provide insights towards a fundamental understanding of the requirements needed for practical applications and reveal drawbacks to be overcome by novel doped carbon-based anode materials in LIB applications. With this work, we also want to encourage other researchers to evaluate electrochemical characteristics besides capacity and cycling stability which are mandatory to assess the practicality of novel materials. 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subjects	Anodes Batteries Carbon Charge density Charge efficiency Cycles Discharge Doping Electric potential Electrochemical analysis Electrode materials Energy consumption Graphite Lithium Lithium-ion batteries Nitrogen Performance enhancement Rechargeable batteries Stability analysis Voltage
title	An electrochemical evaluation of nitrogen-doped carbons as anodes for lithium ion batteries
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