Titanium Carbide has the chemical formula, TiC and a molecularweight of 59.89. The grey powder can be used to produce cemented carbide. Particle Size: -325mesh
Purity: 99%

Description of Titanium Carbide powder:

The formula for Titanium carbide is TiC. Its molecular mass is 59.89. Cubic lattice, solid gray-colored, metal-like faces. The titanium carbide melting point Is 3140+-90degC. Titanium carbide Point boiling It is 4820°C. The relative density is 4.93. It is harder than 9. Water insoluble, aqua regia soluble in nitric acids and water. TiC compound Air is stable when it's lower than 800. It can be corrupted when it's higher than 2000.

TiC is titanium carbide. This refractory ceramic material is very hard, with a Mohs 9-9.5, similar to that of tungsten carbide. It appears as a dark powder with a crystal structure of sodium chloride (face center cubic). It has an elastic modulus of around 400 GPa and a shear modus of 188 GPa.

Titanium carbide can be seen in nature as the very rare mineral Rhodochrosite. (TiV, Fe), C. It is located near Uzbekistan's border in the Chagar Region of the Soviet Union. The crystals are 0.1-0.3mm in size.

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Titanium Carbide TiC Pulp - Properties The molecular weight for the chemical TiC formula is 59.89. Gray metallic lustrous crystal solid. The melting point, boiling point, and relative density are 3140-3140. Hardness 9-10. Water insoluble, aqua regia soluble in nitric Acid, and water-insoluble. It reacts with pure oxygen at 1150 and is therefore stable when the temperature is below 800. Also used for the production of cemented carbide.

Technical Parameters of Titanium Carbide Powder TiC Powder:

Ti+C	C	S	Si	O	No Carbon
99.2	19.5	0.02	0.01	0.4	0.2

Production Method of Titanium Carbide TiC Pulver:

Direct carbonization method:

Titanium powder and carbon black are mixed in a certain proportion and heated to high temperatures in an inert gas or vacuum for direct carbonization. The key to this method is to control temperature and time to obtain titanium carbide with excellent properties. At the same time, in order to prevent deflagration and explosion, it is necessary to strictly control the ratio of carbon and titanium and the reaction conditions. Direct carbonization is one of the main methods for preparing titanium carbide in industry.

In the direct carbonization method, titanium powder and carbon black are mixed in a certain proportion to form a mixture. The mixture is then heated in an inert gas or vacuum to high temperatures, usually above 1500 ° C, for direct carbonization. At high temperatures, carbon black reacts with titanium powder to form titanium carbide. In order to obtain high-quality titanium carbide, it is necessary to strictly control the temperature and time, as well as the ratio of carbon to titanium.

Hydrogen carbide process:

The titanium powder is heated to high temperatures together with hydrogen and carbon black so that the titanium reacts with hydrogen and carbon. This method can obtain high-purity titanium carbide but requires the use of high-purity hydrogen, so the cost is higher. At the same time, in order to prevent hydrogen explosions and air pollution, corresponding safety measures and environmental protection measures need to be taken.

In the hydrogen carbide process, titanium powder, hydrogen, and carbon black are mixed in a certain proportion to form a mixture. The mixture is then heated at high temperatures to above about 1000 ° C, causing the titanium to react with hydrogen and carbon. During the reaction, hydrogen can lower the reaction temperature and keep the carbon black in suspension. After the reaction, high-purity titanium carbide is obtained through cooling, separation, and post-treatment.

Chlorination reduction method:

The titanate solution is chlorinated to obtain titanium chloride gas, and then the reduction reaction with carbon at low temperature to produce titanium carbide. This method can obtain high-purity titanium carbide but requires the use of chlorination agents and reducing agents, so the cost is high. At the same time, in order to prevent chlorine gas leakage and air pollution, corresponding safety measures and environmental protection measures need to be taken.

In the chlorination reduction process, the titanate solution is chlorinated to obtain titanium chloride gas. Then, titanium chloride gas is reacted with carbon black to produce titanium carbide through a low-temperature reduction reaction. Reducing agents generally use hydrogen or other reducing gases, such as carbon monoxide. Chlorination agents are generally chlorine gas or hydrogen chloride. After chlorination reduction reaction, after cooling, separation, and post-treatment, high-purity titanium carbide is obtained.

Chemical vapor deposition method:

At high temperatures, titanium compounds and carbide raw materials are deposited on the substrate by chemical reaction to produce titanium carbide coating. This method can produce high purity, high density, and uniform structure of titanium carbide coating but requires the use of high-temperature furnaces and other equipment, so the cost is high.

In chemical vapor deposition, titanium compounds and carbide raw materials are used as precursors to produce chemical reaction gases by heating or plasma excitation. These gases are deposited on the substrate surface and form a titanium carbide coating. In order to obtain a high-quality coating, parameters such as temperature, gas concentration, and deposition time need to be controlled. In addition, it is necessary to select the appropriate matrix material to adapt to different application requirements.

Application of Titanium Carbide TiC Pulver:

Wear-resistant materials: The high hardness and wear-resistant properties of titanium carbide make it widely used in the field of wear-resistant materials. For example, titanium carbide can be used to manufacture wear-resistant devices such as bearings, gears, and tools to improve their service life and performance. In mechanical equipment in chemical, mining, and metallurgical industries, titanium carbide is also often used as a wear-resistant coating material to protect equipment from wear and corrosion.

High-temperature structural materials: Titanium carbide has excellent high-temperature performance and can maintain stable performance in high-temperature environments. Therefore, titanium carbide is widely used in the manufacture of high-temperature structural materials, such as blades and combustion chambers of aerospace engines. Titanium carbide can withstand high temperatures and high stress while having excellent corrosion resistance, making it an ideal choice for high-temperature structural materials.

Electronic materials: Titanium carbide has good thermal conductivity and stable electrical properties, making it widely used in the field of electronic materials. For example, titanium carbide can be used to manufacture integrated circuit boards, radiators for electronic components, and so on. In these applications, titanium carbide can improve the reliability and stability of electronic products while meeting the diversified and high-performance needs of electronic products.

Ceramic materials: Titanium carbide can form a composite material with excellent properties with ceramic materials. For example, titanium carbide ceramic tools have high hardness, high wear resistance, and good thermal conductivity, which can significantly improve the service life and cutting efficiency of the tool. In addition, titanium carbide can also be used to manufacture high-performance products such as ceramic balls.

Other fields: Titanium carbide can also be used in the energy field, such as solar panels, fuel cells, and other efficient energy conversion devices. Titanium carbide's high thermal conductivity enhances the efficiency and longevity of these devices. In addition, titanium carbide can also be used to manufacture catalyst carriers or reaction media, etc., which has certain application prospects in chemical and environmental protection fields.

Titanium Carbide TiC Pulver Storage Conditions
Titanium Carbide TiC Powder needs to be stored in an airtight container. Additionally, it should not be subject to extreme stress.
Packing and Shipping of Antimony Selenide sb2Se3 powder :
Titanium Carbide Powder Packaging: Vacuum Packing, 1kg/bag 25kg/barrel or on your Request
Titanium Carbide TiC Pulver shipping: Could be sent by sea or air as soon as possible after receipt of payment.


Synthetic Chemical Nano Technology Co. Ltd., is a reliable global supplier and manufacturer. They have over 12 years of experience in manufacturing super-high quality chemicals and Nanomaterials. This includes boride, nitride, graphite, sulfide, and 3D printing powders.
We can provide high-quality titanium carbide dust. Please contact us to send an inquiry. ( sales5@nanotrun.com )

Titanium Carbide Properties
Other Titles	titanium(IV) carbide, TiC powder
	12070-08-5
Compound Formula	TiC
Molecular Weight	40.1
Appearance	Black Powder
Melting Point	3160 degC
Boiling Point	4820 degC
Density	4.93 g/cm3
Solubility of H2O	N/A
Exact Content	59.947946
Titanium Carbide Safety & Health Information
Signal word	N/A
Hazard Statements	N/A
Hazard Codes	N/A
Risk Codes	N/A
Safety statements	N/A
Transport Information	N/A

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