由废弃硬木片制备的具有高比表面积的功能化纳米多孔生物炭用于二氧化碳捕集和超级电容器

Functionalized Nanoporous Biocarbon with High Specific Surface Area Derived from Waste Hardwood Chips for CO Capture and Supercapacitors.

作者信息

Kunjumon Jibi, Maria Ruban Ajanya, Kaur Harleen, Sajan Davidson, Mahasivam Sanje, Bansal Vipul, Singh Gurwinder, Vinu Ajayan

机构信息

Global Innovative Centre for Advanced Nanomaterials (GICAN) College of Science, Engineering, and Environment (CESE) School of Engineering University of Newcastle Callaghan NSW 2308 Australia.

Department of Physics Centre for Sustainable Energy and Environmental Technologies (CE2T) Bishop Moore College Mavelikara Alappuzha Kerala 690110 India.

出版信息

Small Sci. 2025 Jun 24;5(9):2500174. doi: 10.1002/smsc.202500174. eCollection 2025 Sep.

DOI:10.1002/smsc.202500174

PMID:40917403

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12412513/

Abstract

Waste biomass has aroused increasing interest in the production of low-cost materials for CO adsorption and supercapacitors. One of the primary facets in this regard is to develop nanoporous carbons with controlled porosity and high surface area. Herein, waste wood chips are used to synthesize nanoporous biocarbons via a solid-state KOH-based chemical activation. The synthesized materials presented high surface area (3686.10 m g), large pore volume (1.88 cm g), and tunable pore sizes. As a porous solid adsorbent, the optimized material adsorbs 5.59 mmoles of CO per gram at 0 °C/1 bar, which is elevated to 37.47 mmoles g at 0 °C/30 bar along with a good CO/N selectivity within a range ≈25-35 and also displays high recyclability of >99%. Electrochemically, in a three-electrode setup, a high specific capacitance of 261.5 F g/0.5 A g is observed. For a two-electrode setup, a reasonable specific capacitance of 91.67 F g/0.5 A g, energy and power densities (18.33 Wh kg and 2274.94 kW kg), and 87.5% capacity retention after 10 000 cycles are obtained. A low-cost and noncomplicated synthesis and high performance of materials for CO adsorption and supercapacitors make a strong case for their high promise in these fields.

摘要

废弃生物质在用于生产用于 CO 吸附和超级电容器的低成本材料方面引起了越来越多的关注。在这方面的一个主要方面是开发具有可控孔隙率和高比表面积的纳米多孔碳。在此，废弃木屑通过基于 KOH 的固态化学活化用于合成纳米多孔生物碳。合成的材料具有高比表面积（3686.10 m²/g）、大孔体积（1.88 cm³/g）和可调孔径。作为一种多孔固体吸附剂，优化后的材料在 0°C/1 bar 下每克吸附 5.59 毫摩尔的 CO，在 0°C/30 bar 下提高到 37.47 毫摩尔/克，同时在约 25-35 的范围内具有良好的 CO/N 选择性，并且还显示出 >99% 的高可回收性。在电化学方面，在三电极设置中，观察到高比电容为 261.5 F/g/0.5 A/g。对于两电极设置，获得了合理的比电容 91.67 F/g/0.5 A/g、能量和功率密度（18.33 Wh/kg 和 2274.94 kW/kg）以及在 10000 次循环后 87.5% 的容量保持率。低成本、非复杂的合成以及用于 CO 吸附和超级电容器的材料的高性能使其在这些领域具有很高的前景。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/f874/12412513/ef69fc95b02f/SMSC-5-2500174-g005.jpg

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由废弃硬木片制备的具有高比表面积的功能化纳米多孔生物炭用于二氧化碳捕集和超级电容器

Functionalized Nanoporous Biocarbon with High Specific Surface Area Derived from Waste Hardwood Chips for CO Capture and Supercapacitors.

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