This research develops sustainable screen materials using nanoscale “sponges” that trap light-emitting molecules. By converting these materials into ultra-thin nanosheets, the study offers brighter, longer-lasting, and energy-efficient alternatives to toxic, non-renewable screen components, reducing environmental impact while supporting future global screen demand.

This research improves data center energy efficiency by analyzing processor instruction sequences. By identifying and fusing recurring instruction patterns, existing general-purpose processors can execute workloads more efficiently. Even small gains at the instruction level can significantly reduce energy consumption, operating costs, and carbon emissions across large-scale data centers.

Rising global electricity demand requires materials that conduct efficiently at extreme temperatures. This research develops scalable metal–ceramic composite conductors with tunable electrical properties by controlling particle interfaces and packing. These materials overcome limitations of metals and semiconductors, enabling efficient, affordable energy technologies for high-temperature industrial applications.

This research explores chemical recycling, a process that breaks mixed plastic waste into molecular components and converts them back into high-quality plastic. The method reduces energy use and emissions, enabling a circular plastic economy. The goal is a sustainable, economically viable system that shifts responsibility across communities rather than individuals.

This research improves aviation efficiency by using tiny vortex generators to control turbulent airflow over airplane wings. These structures reduce drag, save fuel, and cut carbon emissions—potentially eliminating 600,000 tons of CO₂ annually. It's a small aerodynamic change with a massive global impact for greener, more sustainable air travel.