Qing-Qing Tian , Xiao-Ming Li , Li-Jing Xie , Fang-Yuan Su , Zong-Lin Yi , Liang Dong , Cheng-Meng Chen
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引用次数: 0
摘要
尽管最近人们对煤的低温碳化产生了兴趣,以制备用于锂离子电池(LIBs)和钠离子电池(SIBs)阳极的无序碳材料,但碳化机理仍知之甚少。我们选择烟煤作为原料,研究了从煤到无序碳的碳化过程中的化学、微晶和孔隙结构的变化。随着温度低于1000°C,这些结构变化显示出层间距(3.69–3.82Å)和缺陷浓度(1.26–1.90)的增加,同时产生了大量的纳米微孔材料。这些变化归因于局部碳层的迁移和小分子的释放。此外,在1000°C和1600°C之间,层间距和缺陷浓度会降低。在LIBs中,在1000°C下碳化的样品显示出最佳的电化学性能,在0.1℃下具有384 mAh g−1的可逆容量和优异的倍率性能,在5℃下保持170 mAh g–1。在SIBs中,在1200°C下碳化的样品在0.1°C下具有270.1 mAh g−1的可逆容量和86.8%的高初始库仑效率。
Insights into the carbonization mechanism of bituminous coal-derived carbon materials for lithium-ion and sodium-ion batteries
Despite recent interest in the low-temperature carbonization of coal to prepare disordered carbon materials for the anodes of lithium-ion (LIBs) and sodium-ion batteries (SIBs), the carbonization mechanism is still poorly understood. We selected bituminous coal as the raw material and investigated the chemical, microcrystal, and pore structure changes during the carbonization process from coal to the resulting disordered carbon. These structural changes with temperature below 1 000 °C show an increase in both interlayer spacing (3.69–3.82 Å) and defect concentration (1.26–1.90), accompanied by the generation of a large amount of nano-microporous materials. These changes are attributed to the migration of the local carbon layer and the release of small molecules. Furthermore, a decrease in interlayer spacing and defect concentration occurs between1 000 °C and 1 600 °C. In LIBs, samples carbonized at 1 000 °C showed the best electrochemical performance, with a reversible capacity of 384 mAh g−1 at 0.1 C and excellent rate performance, maintaining 170 mAh g−1 at 5 C. In SIBs, samples carbonized at 1 200 °C had a reversible capacity of 270.1 mAh g−1 at 0.1 C and a high initial Coulombic efficiency of 86.8%. This study offers theoretical support for refining the preparation of carbon materials derived from coal.
期刊介绍:
New Carbon Materials is a scholarly journal that publishes original research papers focusing on the physics, chemistry, and technology of organic substances that serve as precursors for creating carbonaceous solids with aromatic or tetrahedral bonding. The scope of materials covered by the journal extends from diamond and graphite to a variety of forms including chars, semicokes, mesophase substances, carbons, carbon fibers, carbynes, fullerenes, and carbon nanotubes. The journal's objective is to showcase the latest research findings and advancements in the areas of formation, structure, properties, behaviors, and technological applications of carbon materials. Additionally, the journal includes papers on the secondary production of new carbon and composite materials, such as carbon-carbon composites, derived from the aforementioned carbons. Research papers on organic substances will be considered for publication only if they have a direct relevance to the resulting carbon materials.
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