This research uses a scanning tunneling microscope to visualize and measure individual atoms using quantum tunneling. By mapping surfaces atom-by-atom and probing electronic properties, it advances technologies such as nanowires, superconductors, and atomic-scale chips. Understanding materials at the quantum level enables better design of devices that impact energy, computing, and sustainability.

This research uses atomic-scale computer simulations to design safer, more efficient battery electrolytes. By modelling ion movement like a “river” inside a battery, the project identifies top-performing materials before laboratory testing. The goal is to create faster-charging, higher-capacity, non-toxic batteries that support global renewable-energy transitions and a net-zero future.