Applications of Porous Organic Polymers and Frameworks for CO2 Capture: A Comprehensive Review

Abstract

One of the most critical environmental challenges currently is the increase in atmospheric CO₂ levels. Significant research efforts have been directed toward advanced porous materials, especially porous organic polymers (POPs), which are considered highly promising for CO₂ capture due to their exceptional porosity, versatility of their structure, and remarkable physicochemical properties. Recent progress in POPs, particularly the crystalline class such as covalent triazine frameworks (CTFs) and covalent organic frameworks (COFs), has demonstrated considerable potential for CO₂ capture. COFs, characterized by their well-ordered structures, exhibit remarkable properties including large surface areas and ease to tether surface functionalities. Interestingly, surface functionalization methods, such as the addition of amine (–NH₂) groups and in situ modification with hydroxyl (–OH), carbonyl (–CHO) and carboxyl (–COOH) groups, have been found to significantly improve CO₂ adsorption capacity of POPs. The advancement of COFs and CTFs, and generally POPs, offers a promising approach to tackling the challenges of CO₂ capture, aiding efforts to lower greenhouse gas emissions and address environmental issues. This review explores the application of POPs for CO₂ capture, focusing on the role of surface functionalization. Additionally, we examine the mechanisms of how functional groups enhance CO₂ capture and categorize them accordingly. Various CO₂ capture technologies are also discussed. Finally, we identify key challenges and future research directions, such as developing novel functionalization strategies, hybrid materials, and the application of machine learning.