This research investigates how electrolyte chemistry influences battery performance through the formation of the solid electrolyte interface (SEI). By developing fluoride-rich electrolytes for lithium metal batteries, the work improves battery stability and efficiency, advancing renewable energy storage, electric transportation, chemical manufacturing, and future energy technologies beyond conventional lithium-ion systems.

This research develops water-free electrolyte systems for electrochemical reactions and energy technologies. By replacing water with more stable solvents, the work enables improved batteries, renewable energy storage, and more efficient chemical manufacturing. Applications include long-range electric vehicles, planetary exploration systems, and lower-cost pharmaceutical production using recyclable chemical reagents.

This research investigates zinc batteries as a safer, cheaper alternative to lithium batteries. By studying the microscopic passive layer formed between zinc and electrolyte, it identifies mechanisms that improve performance and prevent failure. The work aims to enable more reliable, ethical, and fire-safe energy storage technologies through detailed materials analysis.

Batteries charge slowly and degrade over time. This research develops advanced supercapacitors using novel 2D materials and water-based electrolytes. The resulting devices charge rapidly, store five times more energy than conventional supercapacitors, last over 50,000 cycles, and offer a fast, affordable alternative for electric vehicles and energy storage.