Linshang Chemical
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Tetrachlorobenzene
Linshang Chemical
|
HS Code |
572352 |
| Chemical Formula | C6H2Cl4 |
| Molar Mass | 215.89 g/mol |
| Appearance | White solid |
| Odor | Pungent |
| Melting Point | 46 - 47 °C |
| Boiling Point | 254 - 255 °C |
| Density | 1.70 g/cm³ |
| Solubility In Water | Insoluble |
| Solubility In Organic Solvents | Soluble |
| Vapor Pressure | Low |
As an accredited Tetrachlorobenzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 500 - gram Tetrachlorobenzene packaged in air - tight, corrosion - resistant containers. |
| Storage | Tetrachlorobenzene should be stored in a cool, dry, well - ventilated area. Keep it away from sources of ignition, heat, and oxidizing agents. Store in tightly - sealed containers, preferably made of corrosion - resistant materials like steel or certain plastics. Separate from incompatible substances to prevent chemical reactions and potential hazards. |
| Shipping | Tetrachlorobenzene, a chemical, is shipped in specialized containers that ensure tight - seal to prevent leakage. It follows strict hazardous material shipping regulations, with proper labeling and handling to safeguard transportation safety. |
Competitive Tetrachlorobenzene prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please call us at +8615365006308 or mail to info@alchemist-chem.com.
We will respond to you as soon as possible.
Tel: +8615365006308
Email: info@alchemist-chem.com
Where to Buy Tetrachlorobenzene in China?
As a trusted Tetrachlorobenzene manufacturer, we deliver:
Factory-Direct Value: Competitive pricing with no middleman markups, tailored for bulk orders and project-scale requirements.
Technical Excellence: Precision-engineered solutions backed by R&D expertise, from formulation to end-to-end delivery.
Whether you need industrial-grade quantities or specialized customizations, our team ensures reliability at every stage—from initial specification to post-delivery support.
As a leading Tetrachlorobenzene supplier, we deliver high-quality products across diverse grades to meet evolving needs, empowering global customers with safe, efficient, and compliant chemical solutions.
What are the main uses of Tetrachlorobenzene?
Tetrachlorobenzene is also an organic compound. Its uses are quite extensive, and it is involved in various fields such as industry, agriculture, and medicine.
In industry, tetrachlorobenzene can be used as a solvent. Because of its good solubility, it can dissolve many organic substances and assist in the progress of chemical reactions. It is also used in the manufacture of coatings, inks, etc., to make products uniform and have excellent properties. And tetrachlorobenzene is an important raw material for the synthesis of other organic compounds. After a series of chemical reactions, compounds with special properties can be prepared, which can be used in the synthesis of polymer materials such as plastics and rubber to improve the heat resistance and chemical corrosion resistance of materials.
In agriculture, tetrachlorobenzene can be used as an insecticide. It can effectively kill a variety of pests, protect crops from pests, and ensure the yield and quality of crops. However, caution is required when using it to prevent adverse effects on the environment and ecology.
In the field of medicine, tetrachlorobenzene can be used as an intermediate for certain drugs after appropriate modification and transformation. With its chemical structure characteristics, it participates in the drug synthesis process and helps to develop drugs for the treatment of specific diseases.
However, it should also be noted that tetrachlorobenzene has certain toxicity. When using and handling, strict safety regulations should be followed to avoid harm to human health and the environment. It degrades slowly in the environment and may accumulate. Therefore, when applying, it is necessary to weigh its advantages and disadvantages and seek greener and environmentally friendly alternatives to achieve the purpose of sustainable development.
In industry, tetrachlorobenzene can be used as a solvent. Because of its good solubility, it can dissolve many organic substances and assist in the progress of chemical reactions. It is also used in the manufacture of coatings, inks, etc., to make products uniform and have excellent properties. And tetrachlorobenzene is an important raw material for the synthesis of other organic compounds. After a series of chemical reactions, compounds with special properties can be prepared, which can be used in the synthesis of polymer materials such as plastics and rubber to improve the heat resistance and chemical corrosion resistance of materials.
In agriculture, tetrachlorobenzene can be used as an insecticide. It can effectively kill a variety of pests, protect crops from pests, and ensure the yield and quality of crops. However, caution is required when using it to prevent adverse effects on the environment and ecology.
In the field of medicine, tetrachlorobenzene can be used as an intermediate for certain drugs after appropriate modification and transformation. With its chemical structure characteristics, it participates in the drug synthesis process and helps to develop drugs for the treatment of specific diseases.
However, it should also be noted that tetrachlorobenzene has certain toxicity. When using and handling, strict safety regulations should be followed to avoid harm to human health and the environment. It degrades slowly in the environment and may accumulate. Therefore, when applying, it is necessary to weigh its advantages and disadvantages and seek greener and environmentally friendly alternatives to achieve the purpose of sustainable development.
What are the environmental impacts of Tetrachlorobenzene?
"Tiangong Wuzi" says: "Benzene tetrachloride is also a chemical product. Its presence in the environment has a huge impact."
Benzene tetrachloride degrades due to its nature. If it enters the soil naturally, it will harm the fertility of the soil. Microorganisms in the soil are like microorganisms, which are generated in the soil, and benzene tetrachloride is distributed in the soil. If it is replaced by benzene tetrachloride, the amount of microorganisms will be reduced, the activity of the soil will be lost, the fertility will drop greatly, and the plant growth will be blocked.
And if benzene tetrachloride enters the water source, the water will be damaged. Aquatic organisms exist without water, and this poison enters, which will harm their physiological functions. If it is damaged, it may cause deformity, or it may multiply, and the balance of aquatic life will be large. If people consume this water, they will also suffer from it, and their liver and other organs will suffer from similar diseases.
Furthermore, benzene tetrachloride will enter the body, causing the body to be disrupted and reversed. Or actinic and other phenomena, causing the human respiratory system to be damaged, and affecting the energy of the body, air, air, and other transportation.
Therefore, benzene tetrachloride is exposed to the environment, soil, water sources, and the body are all affected by it, causing disorder and causing damage to the body.
Benzene tetrachloride degrades due to its nature. If it enters the soil naturally, it will harm the fertility of the soil. Microorganisms in the soil are like microorganisms, which are generated in the soil, and benzene tetrachloride is distributed in the soil. If it is replaced by benzene tetrachloride, the amount of microorganisms will be reduced, the activity of the soil will be lost, the fertility will drop greatly, and the plant growth will be blocked.
And if benzene tetrachloride enters the water source, the water will be damaged. Aquatic organisms exist without water, and this poison enters, which will harm their physiological functions. If it is damaged, it may cause deformity, or it may multiply, and the balance of aquatic life will be large. If people consume this water, they will also suffer from it, and their liver and other organs will suffer from similar diseases.
Furthermore, benzene tetrachloride will enter the body, causing the body to be disrupted and reversed. Or actinic and other phenomena, causing the human respiratory system to be damaged, and affecting the energy of the body, air, air, and other transportation.
Therefore, benzene tetrachloride is exposed to the environment, soil, water sources, and the body are all affected by it, causing disorder and causing damage to the body.
What are the production methods of Tetrachlorobenzene?
Tetrachlorobenzene is also an organic compound. The method of its preparation has coexisted through the ages.
One is the chlorination method of benzene. In the past, benzene was often used as the starting material, and a chlorinating agent, such as chlorine gas, was used in the presence of the catalyst to cause it to chlorinate. The temperature of the reaction, the amount of chlorinating agent and the type of catalyst all have a huge impact on the structure and yield of the product. In this process, chlorine gas is added to the hydrogen on the benzene ring one after another to form tetrachlorobenzene. However, this route is difficult to control, and mixtures of isomers are often obtained. After refining, pure products can be obtained.
The second is the re-chlorination of dichlorobenzene. Select dichlorobenzene as the substrate, and apply it with a chlorinating agent and a catalyst. The advantage of this method is that it can lead to the formation of a specific isomer of tetrachlorobenzene according to the isomerization of dichlorobenzene, and increase its selectivity. For example, re-chlorination of dichlorobenzene, or high selection of a specific tetrachlorobenzene isomer, which is crucial for specific applications.
There are also those who use chlorobenzene as a raw material. After multi-step chlorination, tetrachlorobenzene can also be obtained. However, this path is long and cumbersome, and each section of the reaction needs to be strictly controlled to preserve yield and purity.
In addition, other halogenated aromatic hydrocarbons are also synthesized from tetrachlorob Each of these methods has its own advantages and disadvantages. In actual production, the best method must be selected according to the supply of raw materials, the demand for products, the calculation of costs, and environmental protection regulations.
One is the chlorination method of benzene. In the past, benzene was often used as the starting material, and a chlorinating agent, such as chlorine gas, was used in the presence of the catalyst to cause it to chlorinate. The temperature of the reaction, the amount of chlorinating agent and the type of catalyst all have a huge impact on the structure and yield of the product. In this process, chlorine gas is added to the hydrogen on the benzene ring one after another to form tetrachlorobenzene. However, this route is difficult to control, and mixtures of isomers are often obtained. After refining, pure products can be obtained.
The second is the re-chlorination of dichlorobenzene. Select dichlorobenzene as the substrate, and apply it with a chlorinating agent and a catalyst. The advantage of this method is that it can lead to the formation of a specific isomer of tetrachlorobenzene according to the isomerization of dichlorobenzene, and increase its selectivity. For example, re-chlorination of dichlorobenzene, or high selection of a specific tetrachlorobenzene isomer, which is crucial for specific applications.
There are also those who use chlorobenzene as a raw material. After multi-step chlorination, tetrachlorobenzene can also be obtained. However, this path is long and cumbersome, and each section of the reaction needs to be strictly controlled to preserve yield and purity.
In addition, other halogenated aromatic hydrocarbons are also synthesized from tetrachlorob Each of these methods has its own advantages and disadvantages. In actual production, the best method must be selected according to the supply of raw materials, the demand for products, the calculation of costs, and environmental protection regulations.
What are the physical properties of Tetrachlorobenzene?
Tetrachlorobenzene is an organic compound. Its physical properties are quite unique. Looking at its shape, under normal conditions, tetrachlorobenzene is white crystalline and has a more delicate texture.
When it comes to the melting point, its melting point is quite high, about 50 to 60 degrees Celsius. This characteristic makes tetrachlorobenzene mostly solid at room temperature. The boiling point is relatively higher, reaching about 254 to 255 degrees Celsius. Such a high boiling point makes it difficult to rapidly vaporize under normal heating conditions.
The density of tetrachlorobenzene is greater than that of water. If placed in water, it will sink to the bottom. Its solubility also has characteristics, and its solubility in water is very small. Because it is a non-polar molecule, its polarity is quite different from that of water molecules, so it is difficult to dissolve. However, in organic solvents, such as ethanol, ether, etc., tetrachlorobenzene exhibits good solubility, because it is similar to the molecular force of organic solvents and can be miscible with each other.
Furthermore, tetrachlorobenzene has a certain volatility. Although its volatility is not very strong, some molecules will still escape into the air under specific environments and conditions. Its odor is special and irritating. If people are exposed to an environment containing tetrachlorobenzene vapor for a long time, it may cause adverse effects on the respiratory tract.
In addition, tetrachlorobenzene has relatively high stability. Under normal conditions, its chemical properties are relatively inert, and it is not easy to react violently with common substances. However, under certain high temperatures, high pressures, or the presence of catalysts, it can also participate in some organic reactions, exhibiting its unique chemical activity.
When it comes to the melting point, its melting point is quite high, about 50 to 60 degrees Celsius. This characteristic makes tetrachlorobenzene mostly solid at room temperature. The boiling point is relatively higher, reaching about 254 to 255 degrees Celsius. Such a high boiling point makes it difficult to rapidly vaporize under normal heating conditions.
The density of tetrachlorobenzene is greater than that of water. If placed in water, it will sink to the bottom. Its solubility also has characteristics, and its solubility in water is very small. Because it is a non-polar molecule, its polarity is quite different from that of water molecules, so it is difficult to dissolve. However, in organic solvents, such as ethanol, ether, etc., tetrachlorobenzene exhibits good solubility, because it is similar to the molecular force of organic solvents and can be miscible with each other.
Furthermore, tetrachlorobenzene has a certain volatility. Although its volatility is not very strong, some molecules will still escape into the air under specific environments and conditions. Its odor is special and irritating. If people are exposed to an environment containing tetrachlorobenzene vapor for a long time, it may cause adverse effects on the respiratory tract.
In addition, tetrachlorobenzene has relatively high stability. Under normal conditions, its chemical properties are relatively inert, and it is not easy to react violently with common substances. However, under certain high temperatures, high pressures, or the presence of catalysts, it can also participate in some organic reactions, exhibiting its unique chemical activity.
What are the chemical properties of Tetrachlorobenzene?
Tetrachlorobenzene is also an organic compound. Its chemical properties are particularly important, let me explain in detail.
First of all, its stability. Tetrachlorobenzene has high stability. Due to its molecular structure, the chlorine atom is closely connected to the benzene ring, forming a relatively stable system. This stability makes tetrachlorobenzene not prone to spontaneous chemical changes in many common environments. For example, under normal temperature and pressure, it can be stored for a long time without deterioration.
On its solubility. Tetrachlorobenzene is slightly soluble in water, because water is a polar molecule and tetrachlorobenzene is a non-polar molecule. According to the principle of "similar compatibility", the two are not well soluble. However, it is easily soluble in organic solvents, such as ethanol, ether, acetone, etc. This property makes it often used as a solvent or extractant in the fields of organic synthesis and extraction.
Furthermore, tetrachlorobenzene has a certain chemical activity. Although the benzene ring is inherently stable, the presence of chlorine atoms alters the electron cloud distribution of the benzene ring. Under specific conditions, substitution reactions can occur. For example, under appropriate catalyst and reaction conditions, chlorine atoms can be replaced by other functional groups, resulting in the preparation of various derivatives, which is of great significance in organic synthesis chemistry and can expand the variety and use of compounds.
In addition, tetrachlorobenzene can participate in nucleophilic substitution reactions. Due to the certain electronegativity of chlorine atoms, the electron cloud density on the benzene ring is reduced, making it vulnerable to nucleophilic reagents. This reaction property provides a way for the synthesis of complex organic compounds, through which chemists can build unique molecular structures to meet different industrial and scientific research needs.
In summary, the stability, solubility and specific chemical activity of tetrachlorobenzene make it indispensable in many fields such as chemical industry and scientific research, and provide diverse possibilities for chemical research and industrial production.
First of all, its stability. Tetrachlorobenzene has high stability. Due to its molecular structure, the chlorine atom is closely connected to the benzene ring, forming a relatively stable system. This stability makes tetrachlorobenzene not prone to spontaneous chemical changes in many common environments. For example, under normal temperature and pressure, it can be stored for a long time without deterioration.
On its solubility. Tetrachlorobenzene is slightly soluble in water, because water is a polar molecule and tetrachlorobenzene is a non-polar molecule. According to the principle of "similar compatibility", the two are not well soluble. However, it is easily soluble in organic solvents, such as ethanol, ether, acetone, etc. This property makes it often used as a solvent or extractant in the fields of organic synthesis and extraction.
Furthermore, tetrachlorobenzene has a certain chemical activity. Although the benzene ring is inherently stable, the presence of chlorine atoms alters the electron cloud distribution of the benzene ring. Under specific conditions, substitution reactions can occur. For example, under appropriate catalyst and reaction conditions, chlorine atoms can be replaced by other functional groups, resulting in the preparation of various derivatives, which is of great significance in organic synthesis chemistry and can expand the variety and use of compounds.
In addition, tetrachlorobenzene can participate in nucleophilic substitution reactions. Due to the certain electronegativity of chlorine atoms, the electron cloud density on the benzene ring is reduced, making it vulnerable to nucleophilic reagents. This reaction property provides a way for the synthesis of complex organic compounds, through which chemists can build unique molecular structures to meet different industrial and scientific research needs.
In summary, the stability, solubility and specific chemical activity of tetrachlorobenzene make it indispensable in many fields such as chemical industry and scientific research, and provide diverse possibilities for chemical research and industrial production.
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