Graphene for Battery and Energy Storage Research

Energy and environment are the eternal themes of human development. As the global population grows, the demand for energy production and storage continues to increase. There is a huge demand for cleaner and greener new energy alternatives. The emergence of graphene is unleashing the possibility of its application in the energy field, which can create a greener, more efficient and sustainable future. Compared with traditional energy materials such as metals and metal oxides, graphene-based products with different structures (2D and 3D graphene) can effectively enhance the conversion and storage of green energy.

Accelerate Energy Study Using Graphene
Graphene and related materials (GRM) have high surface area, large electrical conductivity, lightweight properties, chemical stability and high mechanical flexibility, which play a key role in meeting this demand for energy generation and storage. At present, many scholars in the world study and modify graphene. Graphene-based supercapacitors are expected to replace traditional capacitors in the use of new energy, and realize their applications in smart grid energy storage systems, energy transmission systems, wind energy, photovoltaic power generation energy storage systems, and distributed power generation energy storage systems. It can well improve energy storage efficiency and reduce energy loss during transmission and waste in energy consumption.

Graphene for Battery and Energy Storage Research

Graphene is currently known as the material with the best electrical conductivity, while it is also the material with the smallest electrical resistivity in the world. These excellent properties make graphene applicable in high-performance batteries, supercapacitors and other fields. 

Graphene for Heating Membrane Research

The excellent thermal and electrical properties of graphene can quickly distribute heat to the entire graphene heating membrane. When the two ends of the membrane are energized, the carbon molecules in the membrane undergo Brownian motion to generate heat energy and form electrothermal conversion. The electric heating membrane can instantly heat up and maintain a higher temperature.