0D-3D Superstructure of Biocarbon with FeCl3-Assisted for Electrochemical Symmetrical Supercapacitor

Journal of Chemistry and Environment Pub Date : 2024-03-17 DOI:10.56946/jce.v3i1.298

Sri Ayunda, R. Farma, Aria Yunita, I. Apriyani

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Abstract

Biomass materials exhibit a diversity of macrostructures that can be derived or developed into various 0D-3D nanoscale structural designs with various different dimensions such as spherical, nanofiber, tubular, nanosheet, hierarchical, nanosphere, and honeycomb structures, when converted into activated carbon. This research converts oil palm empty fruit bunch fiber biomass into supercapacitor carbon material by optimizing the chemical activation process by varying the activating reagent. The active carbon conversion process includes precarbonization stages, chemical activation (KOH, FeCl3, and ZnCl2), carbonization, and physical activation. The resulting electrode was confirmed to have a morphology with a 0D to 3D structure (nanosphere, nanofiber and nanopore) due to the FeCl3 activator, so the resulting surface area was high (517.998 m/g). Biomass was successfully converted into carbon which was confirmed through through the resulting physical and electrochemical properties. The electrochemical performance of the sample supercapacitor cell was analyzed in a symmetric two-electrode system in 1 M H2SO4 electrolyte solution. The FeCl3-activated samples shows the highest specific capacitance of 256 F/g at a scan rate of 1 mV/s. In addition, oil palm empty fruit bunch fiber biomass is a potential raw material, as a carbon material for supercapacitor cells with high performance.

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0D-3D 生物碳与 FeCl3 辅助超级电容器的电化学对称结构

生物质材料的宏观结构多种多样，将其转化为活性炭后，可衍生或发展成各种不同尺寸的 0D-3D 纳米级结构设计，如球形、纳米纤维、管状、纳米片状、分层、纳米球和蜂窝状结构。本研究通过改变活化试剂优化化学活化过程，将油棕空果束纤维生物质转化为超级电容器碳材料。活性碳转化过程包括预碳化阶段、化学活化（KOH、FeCl3 和 ZnCl2）、碳化和物理活化。由于使用了 FeCl3 活化剂，所得电极的形态被确认为具有 0D 至 3D 结构（纳米球、纳米纤维和纳米孔），因此表面积较高（517.998 m/g）。生物质成功转化为碳，这一点通过所产生的物理和电化学特性得到了证实。在 1 M H2SO4 电解质溶液中的对称双电极系统中，分析了样品超级电容器电池的电化学性能。在扫描速率为 1 mV/s 时，FeCl3 活性样品的比电容最高，达到 256 F/g。此外，油棕空果束纤维生物质是一种潜在的原材料，可作为高性能超级电容器电池的碳材料。

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Journal of Chemistry and Environment Chemistry and Environmental Sciences-

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期刊介绍： Journal of Chemistry and Environment (ISSN: 2959-0132) is a peer-reviewed, open-access international journal that publishes original research and reviews in the fields of chemistry and protecting our environment for the future in an ongoing way. Our central goal is to provide a hub for researchers working across all subjects to present their discoveries, and to be a forum for the discussion of the important issues in the field. All scales of studies and analysis, from impactful fundamental advances in chemistry to interdisciplinary research across physical chemistry, organic chemistry, inorganic chemistry, biochemistry, chemical engineering, and environmental chemistry disciplines are welcomed. All manuscripts must be prepared in English and are subject to a rigorous and fair peer-review process. Accepted papers will appear online within 3 weeks followed by printed hard copies. Note: There are no Article Publication Charges. (100% waived). Welcome to submit your Mini reviews, full reviews, and research articles. Journal of Chemistry and Environment aims to publish high-quality research in the following areas: (Topics include, but are not limited to, the following) • Physical, organic, inorganic & analytical chemistry • Biochemistry & medicinal chemistry • Environmental chemistry & environmental impacts of energy technologies • Chemical physics, material & computational chemistry • Catalysis, electrocatalysis & photocatalysis • Energy, fuel cells & batteries Journal of Chemistry and Environment publishes: • Full papers • Reviews • Minireviews