Biopolymer-supramolecular polymer hybrids for photocatalytic hydrogen production.
Jacob E KupferbergZois SyrgiannisLuka ĐorđevićEric P BrucknerTyler J JaynesHakim H HaEvan QiKristen S WekAdam J DannenhofferNicholas A SatherH Christopher FryLiam C PalmerSamuel I StuppPublished in: Soft matter (2024)
Solar generation of H 2 is a promising strategy for dense energy storage. Supramolecular polymers composed of chromophore amphiphile monomers containing perylene monoimide (PMI) have been reported as crystalline light-harvesting assemblies for aqueous H 2 -evolving catalysts. Gelation of these supramolecular polymers with multivalent ions creates hydrogels with high diffusivity but insufficient mechanical stability and catalyst retention for reusability. We report here on using sodium alginate (SA) biopolymer to both induce supramolecular polymerization of PMI and co-immobilize them with catalysts in a robust hydrogel with high diffusivity that can also be 3D-printed. Faster mass transfer was achieved by controlling the material macrostructure by reducing gel diameter and microstructure by reducing biopolymer loading. Optimized gels produce H 2 at rates rivaling solution-based PMI and generate H 2 for up to 6 days. The PMI assemblies in the SA matrix create a percolation network capable of bulk-electron transfer under illumination. These PMI-SA materials were then 3D-printed on conductive substrates to create 3D hydrogel photoelectrodes with optimized porosity. The design of these versatile hybrid materials was bioinspired by the soft matter environment of natural photosynthetic systems and opens the opportunity to carry out light-to-fuel conversion within soft matter with arbitrary shapes and particular local environments.
Keyphrases
- energy transfer
- highly efficient
- electron transfer
- water soluble
- wound healing
- tissue engineering
- hyaluronic acid
- drug delivery
- reduced graphene oxide
- room temperature
- visible light
- quantum dots
- metal organic framework
- ionic liquid
- white matter
- transition metal
- drug release
- carbon dioxide
- multiple sclerosis
- optical coherence tomography