碳吸附剂作为解决温室气体环境问题的功能材料

Proceedings of III All-Russian Scientific Conference with International Participation "Science, technology, society: Environmental engineering for sustainable development of territories" Pub Date : 1900-01-01 DOI:10.47813/nto.3.2022.6.259-265

A. Memetova, A. Zelenin, N. Memetov, R. Stolyarov

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引用次数: 0

摘要

用化学活化法从废咖啡渣中获得碳材料，能够成为温室气体甲烷的高效吸附剂。采用罗曼诺夫光谱、x射线相分析和傅里叶变换红外光谱等方法研究了合成工艺条件(活化剂与前驱体的质量比)对吸附剂多孔结构形成的影响。得到了具有不同孔隙层次和不同比表面积的样品，包括微孔吸附剂(SBET: 1131-2251 m2/g;VMIK/VPORE: 100%)和微介孔吸附剂(SBET: 2951-3304 m2/g;Vmik / vpore: 43 - 64%;VMEZ / VPORE: 36 - 57%)。所得的碳材料具有狭窄的孔径分布，可达5 nm。研究了氢氧化钾与前驱体不同比例的化学活化碳吸附剂对温室气体甲烷的吸附。结果表明，在100 bar和298 K温度下，具有高BET比表面积和DFT比孔容(SBET: 3304 m2/g;VPORE: 1.49 cm3/g)。

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Carbon adsorbent as a functional material for solving the environmental problem of greenhouse gases

Carbon materials have been obtained from spent coffee grounds using chemical activation, capable of becoming highly effective adsorbents for the greenhouse gas methane. The influence of the conditions of the synthesis process (the mass ratio of the activating agent to the precursor) on the development of the porous structure of adsorbents was studied using the methods of Romanov spectroscopy, X-ray phase analysis, and Fourier transform infrared spectroscopy. Samples with different pore hierarchies and different specific surface areas were obtained, including microporous adsorbents (SBET: 1131–2251 m2/g; VMIK/VPORE: 100%) and micromesoporous adsorbents (SBET: 2951–3304 m2/g; VMIK/VPORE: 43– 64%; VMEZ/VPORE: 36-57%). The resulting carbon materials have a narrow pore size distribution up to 5 nm. A study was made of the adsorption of the greenhouse gas methane in carbon adsorbents obtained by chemical activation at various ratios of potassium hydroxide to the precursor. It was found that the highest adsorption of methane, equal to 18.6 mmol/g at 100 bar and a temperature of 298 K, is achieved on a sample with high BET specific surface area and DFT specific pore volume (SBET: 3304 m2/g; VPORE: 1,49 cm3/g).

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Proceedings of III All-Russian Scientific Conference with International Participation "Science, technology, society: Environmental engineering for sustainable development of territories"

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