Wet-chemistry methods are employed to synthesize diverse nanomaterials, including metal oxides, two-dimensional materials, graphene, MXenes, gold nanostars, and nanofibers.

 Our synthesis platforms enable precise control over chemical composition, crystallographic structures, and electronic properties. 

Structural, morphological, process-variable, and surface engineering approaches are applied to optimize electronic structures and physicochemical properties at the nanoscale.

Through systematic structural design, we maximize the functional performance of advanced materials. 

We develop advanced electrode materials and interfacial engineering strategies for next-generation energy storage devices. 

Our research focuses on achieving high-rate charge storage and long-term stability in integrated and miniaturized micro-supercapacitors. 

High-performance electrocatalysts for hydrogen and oxygen reactions are investigated to realize efficient water-splitting systems.

We also design functional energy harvesting materials and devices to advance sustainable power generation technologies.