Post-Combustion Capture of Carbon Dioxide by Natural and Synthetic Organic Polymers

Sudip Ghosh, M. Ghosh
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Abstract

The elevation of carbon dioxide (CO2) levels in the atmosphere is responsible for global warming which in turn causes abrupt climate change and consequently poses a threat to living organisms in the coming years. To reduce CO2 content in the atmosphere CO2 capture and separation is highly necessary. Among various methods of CO2 capture post-combustion capture is very much useful because of its operational simplicity and applicability in many industries and power sectors, such as coal-fired power plants. Polymers with high surface area, high volume and narrow pores are ideal solid sorbents for adsorption-driven post-combustion CO2 capture. Natural polymers, such as polysaccharides are cheap, abundant, and can be modified by various methods to produce porous materials and thus can be effectively utilized for CO2 capture while the surface area and the pore size of synthetic porous organic polymers can be tuned precisely for high CO2 capturing capacity. A significant amount of research activities has already been established in this field, especially in the last ten years and are still in progress. In this review, we have introduced the latest developments to the readers about synthetic techniques, post-synthetic modifications and CO2 capture capacities of various biopolymer-based materials and synthetic porous organic polymers (POPs) published in the last five years (2018–2022). This review will be beneficial to the researchers to design smart polymer-based materials to overcome the existing challenges in carbon capture and storage/sequestration.
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燃烧后二氧化碳的天然和合成有机聚合物捕获
大气中二氧化碳(CO2)水平的升高是造成全球变暖的原因,而全球变暖又导致气候突变,从而在未来几年对生物构成威胁。为了降低大气中的二氧化碳含量,二氧化碳的捕获和分离是非常必要的。在各种二氧化碳捕集方法中,燃烧后捕集因其操作简单和适用于许多工业和电力部门,如燃煤电厂而非常有用。具有高表面积、高体积和窄孔隙的聚合物是理想的固体吸附剂,用于吸附驱动的燃烧后CO2捕获。天然聚合物,如多糖,价格便宜,储量丰富,并且可以通过各种方法进行改性,从而可以有效地用于CO2捕获,而合成的多孔有机聚合物的表面积和孔径可以精确调节,以获得高CO2捕获能力。在这一领域已经开展了大量的研究活动,特别是在过去十年中,并且仍在进行中。在这篇综述中,我们向读者介绍了最近五年(2018-2022)发表的各种生物聚合物基材料和合成多孔有机聚合物(POPs)的合成技术、合成后改性和二氧化碳捕获能力的最新进展。这一综述将有助于研究人员设计智能聚合物基材料,以克服目前在碳捕获和储存/封存方面的挑战。
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