In order to meet the common demand for high specific energy and high power of power battery technology in the field of new energy vehicles, aerospace, and other fields, we research and develop a new generation of high specific capacity electrode materials using graphene, which breaks through the bottleneck of energy density and power density of current power batteries, and realizes the application in electric vehicles and electric aircraft.
In order to ensure the safety, reliability, and service life of marine engineering equipment, we research and develop a new generation of functional heavy anti-corrosion coatings using graphene. These coatings have the characteristics of corrosion resistance, wear resistance, impact resistance, and anti-adhesion, and can meet the application requirements of complex marine and coastal environments. By breaking the foreign technology monopoly in high-end anti-corrosion coatings, we aim to serve the national strategy of building a marine power. The development of these coatings will result in a doubled service life of corrosion resistance.
To address the issue of dependence on imported high value-added functional organic polymer materials, research and development have been carried out to create graphene-modified rubber, plastics, and chemical fiber materials with superior properties such as conductivity, antistatic, thermal conductivity, and mechanical strength. This has significantly enhanced China's international competitiveness and independent capabilities in high-end rubber and plastic materials, enabling the widespread application of these materials in high-end equipment and civil fields.
To address the common demand for efficient thermal management technology in new-generation electronic communication equipment and optoelectronic devices, research and development have been conducted on graphene-based thermal interface materials with ultra-high thermal conductivity, low interfacial thermal resistance, and excellent mechanical properties. This breakthrough has solved the bottleneck problem of relying on imported high-performance thermal management materials and is now serving industries such as 5G/6G communications, aerospace, and national defense.
In response to the urgent demand for high-performance structural and functional integrated composite materials in the aerospace field, graphene fibers with high conductivity, high thermal conductivity, and high strength were developed. Under the premise of equivalent mechanical properties, the conductivity and thermal conductivity are increased by more than one order of magnitude compared with conventional carbon fibers, creating a new generation of carbon fiber technology that is completely self-controlled. This breakthrough can overcome the limitations of traditional carbon fiber composite materials and meet the urgent demand for high-strength, high-conductivity, and lightweight composite materials in the new generation of spacecraft and ultra-high-speed aerospace weapons, etc.