In the field of materials science, colloidal graphite stands out with its unique properties and wide application. And\u00a0it\u00a0has become the focus of scientific research and engineering. It is different from traditional graphite and other materials from micro to macro, and is indispensable in modern industry and high-tech fields. A deep understanding of it is conducive to material utilization and can also provide inspiration for new material research and development.<\/p>
Colloidal graphite is essentially a highly dispersed graphite colloidal system, composed of graphite particles uniformly dispersed in a specific dispersion medium. Graphite is a dispersed phase, and the dispersion medium is\u00a0water, organic solvents, etc.<\/p>\n
<\/p>\n
As an allotrope of carbon, graphite has a layered structure, the carbon atoms in the layer form a hexagonal planar network with covalent bonds. And its\u00a0layers are acted on by weak van der Waals forces. This\u00a0gives graphite unique properties and lays the foundation for the performance of colloidal graphite. In colloidal graphite, the graphite particle size is in the colloidal category of 1-1000 nanometers. After special treatment and dispersion process, stable suspension forms a uniform and stable solution or suspension.\u00a0This\u00a0combines the characteristics of graphite and the special properties of colloidal, providing the possibility for many fields of application.<\/p>\n
<\/p>\n
Graphite has a layered structure\u00a0and covalent bonds between carbon atoms make each layer have free moving valence electrons. This is similar to metal free electron gas, giving it\u00a0good electrical conductivity. After the colloidal, even if the particles are dispersed, the free electrons can still transfer charge between the particles and the dispersing medium ions. This allows the colloidal graphite to maintain excellent electrical conductivity as a whole. And you can widely use it\u00a0in the manufacture of conductive coatings, electrode materials and other electronic fields.<\/p>\n
<\/p>\n
Due to\u00a0the layered structure of graphite, the van der Waals force between the layers is weak. Each layer is easy to slide relatively, which\u00a0is naturally lubricated, and colloidal graphite also retains this characteristic. When applying it\u00a0to the friction surface, the graphite particles form a lubricating film, reducing the coefficient of friction and wear. Its high dispersion can be evenly distributed on complex surfaces, providing comprehensive and lasting lubrication. And it has significant advantages in special mechanical conditions such as high temperature and high load.<\/p>\n
<\/p>\n
Graphite is a high temperature resistant material. Even at temperatures of thousands of degrees Celsius, the crystal structure remains relatively stable. After making it to the colloidal graphite, it can maintain stable performance\u00a0as long as the dispersion medium can withstand the corresponding temperature. So you can use it\u00a0in scenarios with high thermal stability requirements. Such as high temperature furnace sealing and high temperature equipment heat dissipation.<\/p>\n
<\/p>\n
With the help of special dispersion process and suitable dispersant, graphite particles can be uniformly and stably dispersed in the dispersion medium. And they cannot\u00a0agglomerate and precipitate for a long time, which\u00a0ensures that the performance of colloidal graphite is consistent when stored and used. It is convenient for coating, spraying and other processing operations, and can be uniformly attached to various matrix surfaces. To form a coating or film with uniform performance\u00a0and meet the needs of material uniformity in different scenarios.<\/p>\n
\u00a0<\/b><\/strong><\/p>\n
This\u00a0is a common process for preparing colloidal graphite. Through the ball mill, sand mill and other equipment, long time grinding graphite raw materials, and crushing the large particles gradually to the colloid size range. During grinding, adding an appropriate amount of dispersant and grinding aid can\u00a0prevent graphite particles from reuniting and improve grinding efficiency. Its equipment is simple, the cost is not high, so it is suitable for large-scale production. However, the grinding process is easy to mix impurities, which will affect the purity and performance of colloidal graphite. And it is difficult to accurately control the size distribution of graphite particles, resulting in uneven product quality.<\/p>\n
<\/p>\n
This\u00a0is used to disperse graphite particles by means of ultrasonic cavitation. When the ultrasonic wave propagates in the dispersing medium, it will generate high pressure and low pressure areas to form cavitation bubbles. The bubbles collapse rapidly under high pressure, creating shock waves and microjets.\u00a0This exerts a strong shear force on the graphite particles, causing them to break up and disperse evenly.\u00a0The method can achieve high efficiency dispersion in a short time and obtain colloidal graphite with narrow particle size distribution.\u00a0However, the equipment cost is high, the output is low, and there are certain limitations in mass production.<\/p>\n
<\/p>\n
This\u00a0method destroys or weakens the chemical bond between the graphite layers by chemical reaction. So that the graphite layered structure is stripped to form a single or multi-layer graphene sheet. And then\u00a0it is dispersed into colloidal graphite in the dispersion medium. The common method is REDOX. Firstly,\u00a0oxidize\u00a0graphite<\/a> with a strong oxidizing agent, introducing oxygen-containing functional groups to increase the layer spacing. And then removing the functional groups by reduction reaction\u00a0to get graphene. This method can accurately control the number and size of graphite layers, and the colloidal graphite prepared is of high quality and excellent performance.\u00a0However, the process is complicated, the chemical reagents have the risk of environmental pollution, and the production cost is high.<\/p>\n
You can widely use colloidal graphite in the electronic field because of its excellent electrical conductivity and machinability. For example, it can be used for the manufacture of conductive ink. By printing technology on the substrate to produce circuits, electrodes and other components, it is applied to flexible electronic devices and other products.\u00a0You can also use it\u00a0as an electronic packaging additive to improve electrical conductivity and heat dissipation. And it also ensures\u00a0the stable operation of electronic equipment.<\/p>\n
<\/p>\n
In the field of mechanical engineering, you can use it as\u00a0a lubricant and wear-resistant coating material. For equipment friction parts, it can\u00a0reduce friction, reduce wear\u00a0and\u00a0improve efficiency and life. Coating it on the surface of parts can\u00a0form a wear-resistant coating, which enhances\u00a0hardness and wear resistance. Especially suitable for high temperature, high vacuum and other special mechanical environment.<\/p>\n
<\/p>\n
In the energy field, it\u00a0plays a key role in batteries and solar cells. As a negative electrode material in lithium-ion batteries, it is conducive to lithium ion activity and improves charge and discharge and cycle life. You can use it\u00a0to prepare transparent conductive electrodes in solar cells to improve the photoelectric conversion efficiency.\u00a0And you can also use it\u00a0in supercapacitors, which \u00a0improves\u00a0energy storage performance.<\/p>\n
<\/p>\n
In aerospace, because of its good thermal stability and lubrication, you can use it for engine high-temperature components lubrication and aircraft thermal protection. In biomedicine, it is treated as a drug carrier. Also in construction field, you can add it to the paint, giving it electrical conductivity and antistatic properties, preventing dust adsorption.<\/p>\n
<\/p>\n
Colloidal graphite has unique properties and wide application prospects. And\u00a0it\u00a0plays an important role in electronics<\/a>, machinery, energy and other fields because of its advantages of electrical conductivity and lubricity. It can be prepared by mechanical grinding and other processes to meet different needs. With the development of science and technology, its preparation process will be continuously optimized, and it will have more applications.<\/p>\n