结晶度
纤维素
材料科学
纳米晶材料
石墨烯
化学工程
石墨
碳化
聚合物
层状结构
氧化物
图层(电子)
电容
原材料
催化作用
细菌纤维素
纳米技术
微晶纤维素
燃料电池
氧化石墨
蜡
电化学
薄膜
聚合物结晶
作者
Guangguang Guan,Jiebai Li,Duo Na,Dongyan Liu,Xilin Jia,Yin Guan,Shaorui Chen,Mingyue Zhang,Yangtao Zhou
标识
DOI:10.1016/j.indcrop.2026.123247
摘要
The structures of carbonized products from cellulose are closely correlated with the raw material. In the present work, we proposed a self-reassembly strategy and successfully prepared a novel nano-scale cellulose material which exhibited a crumpled thin layer structure and high crystallinity (> 95%). The nano-cellulose undergoes partial graphitization-related transformation without any catalyst at the temperature lower than 300 ℃, which was extremely lower than the graphite transition temperature for conventional cellulose (> 1800 ℃). On this basis, we prepared a novel graphene oxide with high capacitance capability and ultra-long cycling stability. The present findings not only expand our understanding on the microstructure-property correlations of polymer materials but also are expected to achieve wider applications of nano-cellulose to energy-related areas or intelligent wearable devices. • Dual-dissolution strategy enables precise molecular alignment in nanocrystalline cellulose. • Catalyst-free low-temperature graphitization achieved, eliminating energy-intensive carbonization processes. • Oxygen-graphene architectures achieve high-capacitance, ultra-stable electrochemical performance.
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