Solar-Driven C-H Functionalization Reactions. This project aims to investigate the functionalization reaction of unreactive C-H bonds using light as the source of energy. Light is a transformative change to synthesis as thermal activation is exchanged to solar activation. The latter gives access to excited state chemistry and enables reaction steps that are thermally inaccessible. It is a key strategy to leverage synthesis to the demands of the 21st century and to minimise its ecologic footprint ....Solar-Driven C-H Functionalization Reactions. This project aims to investigate the functionalization reaction of unreactive C-H bonds using light as the source of energy. Light is a transformative change to synthesis as thermal activation is exchanged to solar activation. The latter gives access to excited state chemistry and enables reaction steps that are thermally inaccessible. It is a key strategy to leverage synthesis to the demands of the 21st century and to minimise its ecologic footprint. At the same time this strategy provides a lever to profoundly impact and drive new concepts in synthesis. Significant benefits are expected, such as increase in fundamental knowledge on photochemical processes, but also the access to new materials for applications as drugs or OLEDs.Read moreRead less
Sulfur-based materials for infrared optics and thermal imaging. This project aims to investigate novel sulfur polymers for use in infrared optics and thermal imaging. Current thermal imaging lenses are made in energy-intensive processes from expensive semiconductors and toxic chalcogenide glasses. In contrast, highly abundant elemental sulfur can be converted into polymers that are highly transparent to mid- and long-wave infrared light, providing a promising low-cost alternative. In developing ....Sulfur-based materials for infrared optics and thermal imaging. This project aims to investigate novel sulfur polymers for use in infrared optics and thermal imaging. Current thermal imaging lenses are made in energy-intensive processes from expensive semiconductors and toxic chalcogenide glasses. In contrast, highly abundant elemental sulfur can be converted into polymers that are highly transparent to mid- and long-wave infrared light, providing a promising low-cost alternative. In developing this technology, expected outcomes include novel methods to manufacture polymers from low-cost sulfur and their use as lenses for thermal imaging. Significant benefits are expected, such as access to low-cost, recyclable materials for thermal imaging required in surveillance, diagnostics, and spectroscopy.Read moreRead less