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Pine Wood Extracted Activated Carbon through Self‐Activation Process for High‐Performance Lithium‐Ion Battery
Author(s) -
Xia Changlei,
Kang Chiwon,
Patel Mumukshu D.,
Cai Liping,
Gwalani Bharat,
Banerjee Rajarshi,
Shi Sheldon Q.,
Choi Wonbong
Publication year - 2016
Publication title -
chemistryselect
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.437
H-Index - 34
ISSN - 2365-6549
DOI - 10.1002/slct.201600926
Subject(s) - anode , materials science , battery (electricity) , electrochemistry , carbon fibers , pyrolysis , chemical engineering , graphite , lithium (medication) , activated carbon , lithium ion battery , volume (thermodynamics) , energy storage , specific surface area , electrode , process (computing) , nanotechnology , chemistry , composite material , computer science , adsorption , composite number , catalysis , organic chemistry , endocrinology , engineering , operating system , power (physics) , quantum mechanics , medicine , physics
Self‐activation is an ecological friendly and inexpensive process for the fabrication of large scale activated carbon (AC), which precludes the use of activating agents and takes advantage of the emitted gases from the simple pyrolysis of pine wood to stimulate the converted carbon. The tailoring of process parameters such as dwelling time assists in optimizing the pore size distribution comprised of meso‐ and micropores, offering favorable physical properties including specific surface area of 2738 m 2 g −1 and specific pore volume of 2.209 cm 3 g −1 for superior electrochemical performance of Li‐ion batteries. The AC‐based anode shows a high cycling stability with a reversible specific capacity of 384 mAh g −1 at 1C after 200 cycles, which is close to the theoretical specific capacity of graphite. The finding suggests that the self‐activation process, a green, scalable, and efficient process, has great potential to be developed into next‐generation high‐performance electrode materials for electrochemical energy storage devices.