Hydrocarbons drive modern society but fuel climate change when burned. This research converts hydrocarbons into carbon nanotubes and clean hydrogen instead. Using laser diagnostics to probe reactors, it reveals how nanotubes form, enabling higher production rates, industrial decarbonization, and advanced materials for a sustainable, low-carbon energy future.

This research explores human motion as a renewable energy source using nanogenerators made from nanomaterials. By converting everyday body movement into electricity, the work demonstrates a novel, sustainable approach to reducing reliance on fossil fuels and supporting a cleaner energy future.

This research develops a theoretical framework for understanding electron–hole interactions in quantum dots, focusing on positive and negative trions. By analytically modeling their behavior under electric and magnetic fields, it bridges gaps between theory and experiment, supporting advances in quantum electronics, energy technologies, and targeted medical applications.