Organic chromophores show great promise for energy and optoelectronic devices, due to their synthetic tunability and low production costs. In order to achieve this potential, their fundamental photophysical processes must be better understood. It has long been documented that chromophore packing at the molecular level has dramatic effect on electronic...
In nature, materials with complex architectures are formed through hierarchical self-assembly. Therefore, the study and design of hierarchically assembling materials is important in producing materials that mimic biological structures and is a key challenge in biomaterials science and engineering. In articular cartilage, hierarchical assembly of extracellular matrix (ECM) components provides...
One of the grand challenges in materials chemistry and nanochemistry is the development of functional materials through ordered, hierarchical structures using synthetic building blocks. Nature has done this through evolution of molecular components such as nucleic acids, saccharides, lipids, amino acids, and inorganic crystals. The precise spatial positioning of these...
Colloidal crystal engineering with DNA offers new opportunities for materials scientists to build and program the structures of superlattices beyond what can be accomplished in Nature with atomic crystal lattices. Thus far, such materials primarily have been studied for their optical properties due to the insulating nature of the DNA...
Built from non-covalent interactions, supramolecular biomaterials are highly dynamic and tunable, and recent work has shown that they are uniquely capable of mimicking functional biological structures. In this work, supramolecular biomaterials built from self-assembling peptide amphiphiles (PA) were investigated with the goal of precisely tuning their cohesive interactions to optimize...