Scientists Create Cleaner Polymers To Absorb CO2 and Improve Energy Tech

A method for synthesising highly pure porous organic polymers (POPs) has been developed by researchers at Tohoku University, offering applications in reducing greenhouse gas emissions. These polymers, known for their high porosity, have the capability to capture pollutants like carbon dioxide while maintaining strong thermal and chemical stability. Unlike previous synthesis methods that left behind metal impurities, the new approach ensures a cleaner structure, making them more efficient for gas separation, energy storage, and fuel cell applications.

Synthesis Process and Findings

According to the study published in Small, conventional POP synthesis relied on oxidation reactions involving metal salts or coupling reactions using organometallic catalysts. These processes often resulted in residual metal impurities that hindered the polymers’ porosity. In contrast, the research team employed iodine as an oxidant, which allowed for the complete removal of residual impurities through ethanol washing. The newly synthesised polytriphenylamine-based POPs demonstrated the highest specific surface area among reported variants.

As reported by Phys.org, Kouki Oka, a researcher at Tohoku University, stated that the reduction of impurities directly contributed to enhanced porosity, leading to an improved capacity for CO₂ adsorption. He also highlighted that the polymers exhibited unique functionalities, including proton conductivity and a distinct gas adsorption mechanism known as the gate-opening phenomenon. These properties indicate their potential use in advanced energy solutions, including fuel cells and high-performance adsorbents.

Future Implications

As environmental concerns surrounding greenhouse gas emissions persist, the development of pure POPs could pave the way for more efficient and sustainable materials. The findings suggest that ensuring impurity-free synthesis allows these polymers to perform at their full potential, opening new avenues for their application in clean energy technologies and industrial gas separation. Research in this field is expected to continue, focusing on expanding the practical uses of POPs for environmental and energy-related challenges.