Waste biomass-derived activated carbons for selective oxygen adsorption

IF 3.1 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Harshal Kulkarni , Chandresh Bari , Sagnik Mukherjee , Prayag Gajera , Govind Sethia
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Abstract

Activated carbons (ACs) derived from waste rice husk ash (RHA) exhibit remarkable potential for selective oxygen adsorption. The pore morphology of the prepared materials was characterized utilizing BET measurement, t-plot, and BJH-plot suggesting a linear relation between activation temperature and mesopore volume, whereas, micropore volume decreases at activation beyond 550 °C. FT-IR spectroscopy confirms their non-polar surface. Notably, AC-600 achieves an outstanding O2/N2 (0.21/0.78) of 152.7 at 0.01 bar at 25 °C, owing to the non-polar nature of the surface, favouring oxygen adsorption due to its low quadrupole moment. Additionally, the mixed micro and mesoporous structure of AC-600 significantly enhance the oxygen adsorption, showing an ∼18.4% (or 1.2-fold) increase compared to AC-500. However, a ∼32.3% decrease in oxygen uptake was observed for AC-800 due to excessive “burn-off”. Adsorption selectivity, assessed with Ideal Adsorption Solution Theory (IAST) and fitted to the Freundlich isotherm model, and adsorption kinetics, analysed using the pseudo-second-order Lagergren and Webber-Morris intraparticle diffusion models, highlighted the impact of activation temperature on the porosity of the material. Understanding the surface chemistry and pore morphology of activated carbon offers deeper insights to enhance oxygen uptake capacity, advancing the development of sustainable, industrially viable materials for oxygen production.

Abstract Image

用于选择性吸附氧气的废弃生物质衍生活性炭
从废弃稻壳灰(RHA)中提取的活性碳(AC)具有显著的选择性氧气吸附潜力。利用 BET 测量、t-plot 和 BJH-plot 表征了所制备材料的孔隙形态,结果表明活化温度与中孔体积呈线性关系,而活化温度超过 550 ℃ 时,微孔体积会减小。傅立叶变换红外光谱证实了它们的非极性表面。值得注意的是,AC-600 在 25 °C、0.01 巴的条件下,O2/N2(0.21/0.78)达到了 152.7 的优异水平,这是因为其表面具有非极性,其低四极矩有利于氧气的吸附。此外,AC-600 的微孔和介孔混合结构显著提高了氧气吸附能力,与 AC-500 相比,增加了 18.4%(或 1.2 倍)。然而,由于 "烧损 "过多,AC-800 的吸氧量下降了 ∼32.3%。利用理想吸附溶液理论(IAST)评估吸附选择性,并与 Freundlich 等温线模型相匹配;利用伪二阶 Lagergren 和 Webber-Morris 粒子内扩散模型分析吸附动力学,突出了活化温度对材料孔隙率的影响。对活性炭表面化学和孔隙形态的了解为提高氧气吸收能力提供了更深入的见解,推动了可持续的、工业上可行的制氧材料的发展。
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来源期刊
Carbon Trends
Carbon Trends Materials Science-Materials Science (miscellaneous)
CiteScore
4.60
自引率
0.00%
发文量
88
审稿时长
77 days
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