Graphene is a two-dimensional carbon nanomaterial with a hexagonal honeycomb lattice composed of carbon atoms and sp² hybrid orbitals.
Applications of Graphene
Graphene has excellent optical, electrical, and mechanical properties, and has important application prospects in materials science, micro-nano processing, energy, biomedicine, and drug delivery. It is considered a revolutionary material in the future. Graphene is one of the materials with the highest known strength. It also has good toughness and can be bent. The theoretical Young's modulus of graphene is 1.0 TPa and the inherent tensile strength is 130 GPa. Graphene has very good thermal conductivity. Graphene has very good optical properties, the absorption rate is about 2.3% in a wide wavelength range, and it looks almost transparent.
Graphite-corp provides different kinds of graphite powder, such as natural graphite powder, modified artificial graphite, natural compound graphite powder, etc.
Battery energy field: Graphene has high conductivity and specific surface area and can be used to manufacture high-efficiency batteries and supercapacitors. Graphene batteries charge much faster than traditional batteries, with higher energy density and longer service life.
Field of semiconductor electronic devices: Graphene's excellent conductivity and good light transmittance make it an ideal material for manufacturing the next generation of high-speed, low-power semiconductor electronic devices, such as transistors, field effect transistors, integrated circuits, etc.
Biomedical field: Graphene is biocompatible and biodegradable and can be used to prepare biomedical materials such as drug delivery systems, biosensors, and bioimaging agents.
Composite materials field: Graphene has high strength and flexibility and can be added to other materials to enhance their properties. For example, adding graphene to plastics can create high-strength, lightweight composite materials for use in structural materials such as aircraft and automobiles.
Sensing and detection fields: Graphene's high sensitivity and fast response characteristics can be used to manufacture highly sensitive sensors and detectors. For example, graphene can be used to detect gases and biomolecules and can also be used to create photodetectors and optical modulators.
Optical field: Graphene has excellent light absorption and light transmittance and can be used to manufacture transparent photoelectric films and optoelectronic devices, such as solar cells, LEDs, etc.
Thermal management field: Graphene has high thermal conductivity and can efficiently manage heat dissipation. Adding graphene to insulation materials can improve their insulation properties while using graphene to make radiators can improve their heat dissipation efficiency.
The field of manufacturing other two-dimensional materials: Graphene can be used as a "parent" material to manufacture other two-dimensional materials, such as boron nitride, molybdenum disulfide, etc., through chemical vapor deposition, molecular beam epitaxy, and other methods.
Bioengineering field: Graphene can simulate biological systems to a certain extent, so it can be used in bioengineering, such as building artificial muscles, neurons, etc., in biomedical engineering.
Environmental management field: Graphene has a large specific surface area and adsorption capacity and can be used in water treatment and air purification fields. For example, using graphene in water treatment can remove heavy metal ions and organic pollutants.
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