Supramolecular hydrogels have become an important research area in the last decade due to their unique properties including easy preparation, self-healing and stimuli-responsiveness for applications such as sensing, biomaterials, biomedicine, energy conversion, catalysis, etc. Nonetheless, the rational design of the current state-of-the-art of supramolecular hydrogels is limited due to a lack of quantitatively systematic studies of structure-property relationships between microscopic supramolecular motifs and the macroscopic mechanical behaviour. In order to overcome this limitation, the direct visualization and resolution of single molecules by super-resolution microscopy (SRM) can enable in-depth investigations into the structure-property relationships of supramolecular hydrogels with unprecedented temporal and spatial resolution. Through the deep understanding of structure-property relationships, the rational design of supramolecular hydrogels with controlled architecture and function will become possible, bringing new potential for the development of supramolecular materials with desirable applications in many different fields.
This project represents a new research strategy at the frontier of supramolecular chemistry, polymer chemistry and material science, aiming to develop an innovative methodology to probe dynamic host-guest complexation as individual entities and within hydrogels at the molecular level with temporal and spatial resolution; design of supramolecular hydrogels with tuneable dynamics, morphologies and optical properties; gain fundamental knowledge that will serve to the development of technologies in sensing, biomedical and pharmaceutical sector. In this way, the ability to create desirable supramolecular hydrogels with tuneable properties and functions will draw enormous attention from scientists in different fields of chemistry, materials science, engineering and biomedicine, and will also inspire new collaboration within our scientific community. It is also noteworthy that the profound knowledge that we will acquire by studying the rheological behaviour of a range of supramolecular hydrogels will contribute fundamental knowledge to the field of polymer rheology, especially for the class of supramolecular polymers formed from noncovalent interactions.