Catalysis Department, Refining Division, Egyptian Petroleum Research Institute, Nasr City, 11727, Cairo, Egypt.
Chemistry Department, Faculty of Science, Cairo University, Giza, Egypt.
Environ Sci Pollut Res Int. 2023 Apr;30(18):53817-53832. doi: 10.1007/s11356-023-26013-5. Epub 2023 Mar 3.
The growing concern about the environmental consequences of anthropogenic CO emissions significantly stimulated the research of low-cost, efficient, and recyclable solid adsorbents for CO capture. In this work, a series of MgO-supported mesoporous carbon nitride adsorbents with different MgO contents (xMgO/MCN) was prepared using a facile process. The obtained materials were tested for CO capture from 10 vol% CO mixture gas with N using a fixed bed adsorber at atmospheric pressure. At 25 ºC, the bare MCN support and unsupported MgO samples demonstrated CO capture capacities of 0.99, and 0.74 mmol g, respectively, which were lower than those of the xMgO/MCN composites.The incorporation of MgO into the MCN improved the CO uptake, and the 20MgO/MCN exhibited the highest CO capture capacity of 1.15 mmol g at 25 °C. The improved performance of the 20MgO/MCN nanohybrid can be possibly assigned to the presence of high content of highly dispersed MgO NPs along with its improved textural properties in terms of high specific surface area (215 mg), large pore volume (0.22 cmg), and abundant mesoporous structure. The efffects of temperature and CO flow rate were also investigated on the CO capture performance of 20MgO/MCN. Temperature was found to have a negative influence on the CO capture capacity of the 20MgO/MCN, which decreased from 1.15 to 0.65 mmol gwith temperature rise from 25 C to 150º C, due to the endothermicity of the process. Similarly, the capture capacity decreased from 1.15 to 0.54 mmol g with the increase of the flow rate from 50 to 200 ml minute respectively. Importantly, 20MgO/MCN showed excellent reusability with consistent CO capture capacity over five sequential sorption-desorption cycles, suggesting its suitability for the practical capture of CO.
人们对人为 CO 排放对环境造成的影响的担忧日益加剧,这极大地刺激了对低成本、高效、可回收的 CO 捕获用固体吸附剂的研究。在这项工作中,采用一种简便的方法制备了一系列具有不同 MgO 含量(xMgO/MCN)的 MgO 负载介孔氮化碳吸附剂。在大气压下,使用固定床吸附器,用 10 体积%CO 混合气体与 N 对所得材料进行 CO 捕获测试。在 25°C 时,裸 MCN 载体和无载体 MgO 样品的 CO 捕获容量分别为 0.99 和 0.74mmol g,低于 xMgO/MCN 复合材料。MgO 的掺入改善了 CO 的吸收,20MgO/MCN 在 25°C 时表现出最高的 CO 捕获容量为 1.15mmol g。20MgO/MCN 纳米杂化物性能的提高可能归因于高含量的高度分散的 MgO NPs 的存在及其在高比表面积(215mg)、大孔体积(0.22cmg)和丰富的介孔结构方面改善的结构性能。还研究了温度和 CO 流速对 20MgO/MCN 的 CO 捕获性能的影响。发现温度对 20MgO/MCN 的 CO 捕获容量有负面影响,由于该过程的吸热性,20MgO/MCN 的 CO 捕获容量从 25°C 升高到 150°C 时从 1.15mmol g 降低到 0.65mmol g。同样,CO 流速从 50ml 分钟增加到 200ml 分钟时,捕获容量从 1.15mmol g 降低到 0.54mmol g。重要的是,20MgO/MCN 在五个连续的吸附-解吸循环中表现出优异的可重复使用性,具有一致的 CO 捕获容量,表明其适合 CO 的实际捕获。
