Using innovative chemical approaches and nanoscale assembly strategies, we are creating a brand new generation of graphene and 2D materials, and developing novel atomically thin nanosheet-based nanostructures with precisely controlled chemical composition, well-defined structural morphology and physical dimensionality for energy oriented nanosystems.

Using innovative chemical approaches and nanoscale assembly strategies, we are creating a brand new generation of graphene and 2D materials, and developing novel atomically thin nanosheet-based nanostructures with precisely controlled chemical composition, well-defined structural morphology and physical dimensionality for energy oriented nanosystems.

Using innovative chemical approaches and nanoscale assembly strategies, we are creating a brand new generation of graphene and 2D materials, and developing novel atomically thin nanosheet-based nanostructures with precisely controlled chemical composition, well-defined structural morphology and physical dimensionality for energy oriented nanosystems.

Through rational assembly and interfacial integration of different 2D layered materials, we are exploring high-energy, new-concept supercapacitors and micro-supercapacitors with integrated features of unprecedented performance, thinness, flexibility, scalability, light weight, and smart functions, for on-chip and bulk applications in diverse electronics and vehicles.

Through rational assembly and interfacial integration of different 2D layered materials, we are exploring high-energy, new-concept supercapacitors and micro-supercapacitors with integrated features of unprecedented performance, thinness, flexibility, scalability, light weight, and smart functions, for on-chip and bulk applications in diverse electronics and vehicles.

Combining the ultrathin structure and unique properties of graphene and 2D materials, we are of great interest in designing and creating high-efficient, low-cost, environmentally friendly, advanced energy batteries, e.g., high-energy lithium secondary batteries, new-type batteries that can challenge the state-of-the-art performance limits of traditional devices and beyond.

Combining the ultrathin structure and unique properties of graphene and 2D materials, we are of great interest in designing and creating high-efficient, low-cost, environmentally friendly, advanced energy batteries, e.g., high-energy lithium secondary batteries, new-type batteries that can challenge the state-of-the-art performance limits of traditional devices and beyond.

Utilizing unique structure and diverseness of 2D nanosheets and their nanohybrids, the as-designed graphene and 2D materials will offer various notable opportunities for other green, clean and sustainable techniques in such as heterogeneous catalysts, CO2 reduction, hydrogen storage, water splitting, water treatment, seawater desalination.