The world’s growing population faces looming food shortages and the pressing need for cheap and sustainable energy sources. Reliable conversion of sunlight–our most abundant energy source–into fuel can address these threats. However, reliable energy conversion requires knowing how to tailor, at an atomic level, photoprotection cycles limiting food production and energy flow in solar cells that convert sunlight into fuel. I will harness the power of generalized master equations to develop efficient, atomically resolved theories and analysis tools that cut the cost of experiments needed to reveal how to employ chemical modifications to manipulate photoprotection cycles in plants and the photocatalytic activity of metal oxides. Our developments will offer transformative insights into fundamental excitation dynamics in complex materials, enabling the boosting of photosynthetic crop production and optimization of environmentally friendly semiconductors that split water into clean fuels.
Awards and Achievements
- DOE Early Career Award
- The Marinus Smith Award