Lignocellulosic Biomass-Derived Graphene: Fabrication, Challenges and Its Potential for Hydrogen Storage Application

Energy Storage Pub Date : 2024-08-27 DOI:10.1002/est2.70019
Anjali Singh, Aman John Tudu, Basant Lal, Shafiul Haque, Bhawna Verma
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Abstract

This review explores the utilization of lignocellulosic biomass (LCB) waste in the fabrication of graphene and its applications in hydrogen storage. Several LCB wastes, such as rice straws, coconut shells, wheat straws, and sugarcane bagasse, along with the methodology used and the characteristics of the final graphene, have been discussed in detail. It was found that the coconut shells produced crumpled multilayered graphene, rice husks (RHs) provided a mix of graphene layers and amorphous carbon, wheat straw yielded few-layered graphene, and sugarcane bagasse contributed to different graphene-like materials. This review has also focused on the various synthesis processes, such as carbonization, hydrothermal carbonization (HTC), chemical activation, pyrolysis, chemical vapor deposition (CVD), and Hummers' method for graphene fabrication from LCB waste, along with their advantages and disadvantages, for a better understanding. Various results have been discussed exploring the use of lignocellulosic biomass-derived graphene (LCB-G) and its various modified forms for hydrogen storage applications. Various challenges in graphene fabrication from LCB, such as low yield, product quality, scalability, use of expensive synthesis methods, and toxic chemicals, along with some potential solutions, have been mentioned. Finally, the review concludes with insights into the future of LCB-G and its role in hydrogen storage while identifying some gaps, such as scalability and product quality, for further research and development.

木质纤维素生物质衍生石墨烯:制造、挑战及其在储氢应用中的潜力
本综述探讨了利用木质纤维素生物质(LCB)废物制造石墨烯及其在储氢中的应用。文中详细讨论了几种木质纤维生物质废物,如稻草、椰子壳、小麦秸秆和甘蔗渣,以及所使用的方法和最终石墨烯的特性。研究发现,椰子壳产生了皱缩的多层石墨烯,稻壳(RHs)提供了石墨烯层和无定形碳的混合物,小麦秸秆产生了少层石墨烯,甘蔗渣则产生了不同的石墨烯类材料。本综述还重点介绍了各种合成工艺,如碳化、水热碳化 (HTC)、化学活化、热解、化学气相沉积 (CVD),以及从 LCB 废物中制造石墨烯的 Hummers 方法及其优缺点,以便更好地理解这些工艺。在探索使用木质纤维素生物质衍生石墨烯(LCB-G)及其各种改性形式进行储氢应用方面,已经讨论了各种成果。还提到了从 LCB 制备石墨烯过程中面临的各种挑战,如产量低、产品质量、可扩展性、使用昂贵的合成方法和有毒化学品,以及一些潜在的解决方案。最后,综述对 LCB-G 的未来及其在储氢中的作用进行了总结,同时指出了一些差距,例如可扩展性和产品质量,以供进一步研究和开发。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
2.90
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