Process intensification technologies for CO2 capture and conversion – a review

Abdullahi Adamu, Fernando Russo-Abegão, Kamelia Boodhoo
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引用次数: 55

Abstract

With the concentration of CO2 in the atmosphere increasing beyond sustainable limits, much research is currently focused on developing solutions to mitigate this problem. Possible strategies involve sequestering the emitted CO2 for long-term storage deep underground, and conversion of CO2 into value-added products. Conventional processes for each of these solutions often have high-capital costs associated and kinetic limitations in different process steps. Additionally, CO2 is thermodynamically a very stable molecule and difficult to activate. Despite such challenges, a number of methods for CO2 capture and conversion have been investigated including absorption, photocatalysis, electrochemical and thermochemical methods. Conventional technologies employed in these processes often suffer from low selectivity and conversion, and lack energy efficiency. Therefore, suitable process intensification techniques based on equipment, material and process development strategies can play a key role at enabling the deployment of these processes. In this review paper, the cutting-edge intensification technologies being applied in CO2 capture and conversion are reported and discussed, with the main focus on the chemical conversion methods.

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二氧化碳捕集与转化过程强化技术综述
随着大气中二氧化碳浓度的增加超过了可持续的极限,目前许多研究都集中在开发缓解这一问题的解决方案上。可能的策略包括将排放的二氧化碳封存在地下深处长期储存,并将二氧化碳转化为增值产品。这些解决方案的传统工艺通常具有高资本成本,并且在不同的工艺步骤中存在动力学限制。此外,二氧化碳在热力学上是一种非常稳定的分子,很难被激活。尽管面临这样的挑战,许多二氧化碳捕获和转化的方法已经被研究,包括吸收、光催化、电化学和热化学方法。在这些过程中采用的传统技术往往选择性和转化率低,而且缺乏能源效率。因此,基于设备、材料和工艺开发策略的合适的工艺强化技术可以在实现这些工艺的部署方面发挥关键作用。本文综述了目前应用于CO2捕集与转化的强化技术,重点介绍了化学转化技术。
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