Probing Temperature‐Dependence of Hydrogen Bonding in Condensed Polymeric Materials with Aggregation‐Induced Emission

Abstract

AbstractHydrogen bonding is pivotal in chemical and biological systems, yet detecting it in condensed matter, especially polymers, remains challenging. We propose a straightforward method using an aggregation‐induced emission luminogen (AIEgen) probe, demonstrated in a specially designed hydrogen‐bonded polymer with UPy groups. Unlike conventional covalent bonding, our approach involves mixing the AIEgen probe with polymers, inducing a significant change in fluorescence intensity due to the exceptional AIE characteristics. Validation involved comparative analyses with traditional methods, including dynamic mechanical analysis and infrared spectroscopy, across various temperatures. Our AIEgen‐based approach offers a more intuitive assessment of hydrogen bonding dynamics than the complexity of infrared spectroscopy. Importantly, hydrogen‐bonding transition temperatures determined by our AIEgen‐based method are only 6–8 degrees higher than those from dynamic mechanical analyses, confirming accuracy under faster, simpler conditions. This innovative technique not only opens a new avenue for investigating hydrogen bonding dynamics within confined polymer chains but also enhances the precision of transition temperature determination in solid‐state materials. Our study highlights the vital role of hydrogen bonding in functional materials, promising exciting possibilities for further advancements in this field.