This research compares ionic polymers to dancers on a crowded floor. When molecular rotation and movement are restricted, viscosity rises and electrical conductivity drops. Using physics-based simulations, the study shows how molecular size and freedom of rotation control material performance, helping guide the design of safer, more efficient batteries.

This research transforms agricultural waste into biochar-based activated carbon for batteries and supercapacitors. By replacing costly materials, it improves energy storage performance while reducing costs, offering a sustainable and affordable solution that turns waste into valuable resources for future energy technologies.

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.

This research develops a high-performance supercapacitor using a conductive iron-based metal–organic framework. By overcoming low electrical conductivity, the material enables rapid charging and long cycle life, achieving storage performance three times higher than existing designs. The work advances next-generation energy storage solutions beyond conventional batteries.

This research develops improved catalysts that convert atmospheric carbon dioxide into sustainable fuel. By analysing how molecular design affects reaction efficiency, selectivity, and durability, the work creates strategies to accelerate the chemical process and prevent breakdown. The findings support large-scale renewable energy storage and help integrate clean fuels into future energy systems.

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.