Understanding the characteristics of SO2 capture: Effect of solar-assisted adsorbent, isotherms, kinetics, thermodynamics, and mechanism

IF 6.2 2区工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY

alexandria engineering journal Pub Date : 2025-05-16 DOI:10.1016/j.aej.2025.05.031

Divya Baskaran , L. Nagarajan , Panchamoorthy Saravanan , Hun-Soo Byun

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引用次数: 0

Abstract

The study contributed to developing sustainable clean energy technologies by providing a novel approach for SO₂ capture, which is essential for reducing emissions and mitigating climate change. Due to its high stability and corrosion resistance, reduced graphene oxide (RGO) is preferred for SO₂ capture. In this study, GO was reduced sustainably using sunlight (SARGO) and was employed for SO₂ adsorption. By using various characterization techniques, it was confirmed that the synthesized SARGO adsorbent has a mesoporous structure with potential functional groups, great thermal stability, high surface area (713.4 m²/g), pore size (4.89 nm), and pore volume (0.79 cm³/g). The maximum adsorption capacity and efficiency were 23.72 mg/g and 93.8 %. Sips isotherm and Pseudo-second order kinetic models are more appropriate for relating the SO₂ adsorption to the SARGO adsorbent. Along with thermodynamic studies, the adsorption mechanism and photoreduction mechanism were detailed. The SO₂ adsorption process belongs to exothermic, spontaneous, and physical adsorption. Further, the obtained wide functional groups of O–H, –COOH, and –O– are favorable for SO₂ adsorption onto the adsorbent via hydrogen bonding, acid-base interactions, dipole-dipole interactions, and covalent bonds. SARGO has excellent reusability and stability for industrial applications. The approximate cost was roughly calculated to be $1.25/mg of SO₂ adsorbed onto SARGO adsorbent. The study findings successfully demonstrated the potential for environmental engineering, particularly in air pollution control, sustainable energy, and clean technologies, emphasizing the potential of solar-assisted adsorbents for reducing emissions and optimizing industrial processes. The study provided a thorough understanding of the adsorbent characteristics, including isotherms, kinetics, thermodynamics, and mechanisms, offering valuable insights for industrial applications.

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了解二氧化硫捕获特性：太阳能辅助吸附剂的影响、等温线、动力学、热力学和机理

该研究通过提供一种新的二氧化硫捕获方法，为开发可持续清洁能源技术做出了贡献，这对减少排放和减缓气候变化至关重要。由于其高稳定性和耐腐蚀性，还原氧化石墨烯（RGO）是SO2捕获的首选材料。在本研究中，利用阳光对氧化石墨烯进行可持续还原（SARGO），并将其用于SO2吸附。通过各种表征技术，证实了合成的SARGO吸附剂具有具有势官能团的介孔结构，热稳定性好，比表面积高（713.4 m2/g），孔径大（4.89 nm），孔容大（0.79 cm3/g）。最大吸附量和效率分别为23.72 mg/g和93.8 %。Sips等温线和拟二级动力学模型更适合于将SO2吸附与SARGO吸附剂联系起来。在热力学研究的基础上，详细介绍了吸附机理和光还原机理。SO2吸附过程属于放热吸附、自发吸附和物理吸附。此外，得到的O-H、- cooh和- o -宽官能团有利于通过氢键、酸碱相互作用、偶极-偶极相互作用和共价键将SO2吸附在吸附剂上。SARGO在工业应用中具有出色的可重用性和稳定性。粗略计算，SARGO吸附剂吸附二氧化硫的成本约为1.25美元/毫克。研究结果成功地展示了环境工程的潜力，特别是在空气污染控制、可持续能源和清洁技术方面，强调了太阳能辅助吸附剂在减少排放和优化工业过程方面的潜力。该研究提供了对吸附剂特性的全面了解，包括等温线、动力学、热力学和机理，为工业应用提供了有价值的见解。

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来源期刊

alexandria engineering journal Engineering-General Engineering

CiteScore

11.20

自引率

4.40%

发文量

1015

审稿时长

43 days

期刊介绍： Alexandria Engineering Journal is an international journal devoted to publishing high quality papers in the field of engineering and applied science. Alexandria Engineering Journal is cited in the Engineering Information Services (EIS) and the Chemical Abstracts (CA). The papers published in Alexandria Engineering Journal are grouped into five sections, according to the following classification: • Mechanical, Production, Marine and Textile Engineering • Electrical Engineering, Computer Science and Nuclear Engineering • Civil and Architecture Engineering • Chemical Engineering and Applied Sciences • Environmental Engineering