Covalent Organic Frameworks: The Rising‐Star Platforms for the Design of CO₂ Separation Membranes

Abstract: Membrane‐based carbon dioxide (CO2) capture and separation technologies have aroused great interest in industry and academia due to their great potential to combat current global warming, reduce energy consumption in chemical separation of raw materials, and achieve carbon neutrality. The emerging covalent organic frameworks (COFs) composed of organic linkers via reversible covalent bonds are a class of porous crystalline polymers with regular and extended structures. The inherent structure and customizable or… Show more

“…Rational selection of organic linkers and introduction of additional hydrogen bonding among frameworks can effectively improve MOFs and COFs' stability. [56] For example, Banerjee et al first reported the ketoenamine-linked COFs with high chemical stability owing to the irreversible nature of the whole reaction without an imine bond. [57] An easy way to measure the chemical stability of separators is by observing the corrosion resistance and the rate of expansion and contraction after soaking in the liquid electrolyte for some time.…”

Application of Metal/Covalent Organic Frameworks in Separators for Metal‐Ion Batteries

“…Rational selection of organic linkers and introduction of additional hydrogen bonding among frameworks can effectively improve MOFs and COFs' stability. [56] For example, Banerjee et al first reported the ketoenamine-linked COFs with high chemical stability owing to the irreversible nature of the whole reaction without an imine bond. [57] An easy way to measure the chemical stability of separators is by observing the corrosion resistance and the rate of expansion and contraction after soaking in the liquid electrolyte for some time.…”

Application of Metal/Covalent Organic Frameworks in Separators for Metal‐Ion Batteries

“…49–52 The field has also witnessed the utilization of unreacted sites, the introduction of non-interfering functional groups, and post-synthetic modifications that functionalize the pores or transform the linkages. 30,33,53 The functional versatility of such framework materials has led to various applications, including gas adsorption/separation, 54–57 host–guest chemistry, 58–61 sensing, 62–68 ion capture/transport, 69 catalysis, 70–76 and electrochemical applications. 77…”

“…[49][50][51][52] The eld has also witnessed the utilization of unreacted sites, the introduction of noninterfering functional groups, and post-synthetic modications that functionalize the pores or transform the linkages. 30,33,53 The functional versatility of such framework materials has led to various applications, including gas adsorption/separation, [54][55][56][57] host-guest chemistry, 58-61 sensing, [62][63][64][65][66][67][68] ion capture/transport, 69 catalysis, [70][71][72][73][74][75][76] and electrochemical applications. 77 Focussed research activities on COFs that started with the rst report via the formation of dynamic boroxine and boronate ester bonds have now been extended to seeded growth of 2D COFs, graphene nanoribbon 2D COFs, and recently to water harvesting frameworks.…”

Expanding the horizons of covalent organic frameworks: sub-stoichiometric synthesis as an emerging toolkit for functional COFs

“…Biogas is one of the most readily available and widespread renewable energies, and it is usually obtained from the decomposition of biodegradable waste. − Biogas has been expected to replace the conventional fossil fuel . However, CO 2 in biogas not only causes corrosion of equipment and pipelines but also greatly reduces the calorific value of biogas. − Hence, it is required to take CO 2 out of biogas.…”

Low-Resistance Transport Pathways in POSS/CPBI Mixed Matrix Membranes for Efficient CO₂ Separation