Linshang Chemical
PRODUCTS
Benzene, 1,2,4,5-Tetrachloro-
Linshang Chemical
|
HS Code |
124327 |
| Chemical Formula | C6H2Cl4 |
| Molar Mass | 215.89 g/mol |
| Appearance | White to yellowish solid |
| Odor | Chlorinated hydrocarbon odor |
| Density | 1.84 g/cm³ (approximate) |
| Melting Point | 139 - 142 °C |
| Boiling Point | 345 - 348 °C |
| Solubility In Water | Insoluble |
| Solubility In Organic Solvents | Soluble in many organic solvents like benzene, toluene |
| Vapor Pressure | Low vapor pressure at room temperature |
| Stability | Stable under normal conditions but may react with strong oxidizing agents |
As an accredited Benzene, 1,2,4,5-Tetrachloro- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100 - gram bottle packaging for 1,2,4,5 - tetrachlorobenzene chemical. |
| Storage | 1,2,4,5 - Tetrachlorobenzene should be stored in a cool, dry, well - ventilated area. Keep it away from sources of heat, ignition, and incompatible substances such as strong oxidizers. Store in tightly closed containers made of materials resistant to corrosion by the chemical, like certain plastics or metal alloys, to prevent leakage and exposure. |
| Shipping | 1,2,4,5 - Tetrachlorobenzene is a hazardous chemical. Shipping requires proper packaging in accordance with regulations, likely in sealed, corrosion - resistant containers, accompanied by clear hazard labels and shipping documentation. |
Competitive Benzene, 1,2,4,5-Tetrachloro- 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 Benzene, 1,2,4,5-Tetrachloro- in China?
As a trusted Benzene, 1,2,4,5-Tetrachloro- 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 Benzene, 1,2,4,5-Tetrachloro- 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 1,2,4,5-tetrachlorobenzene?
Silicon tetrachloride is an important chemical substance. Its main uses are numerous and crucial.
The primary use is in the semiconductor industry. In the manufacture of semiconductor materials, silicon tetrachloride is often used as a source of silicon. Through delicate processes such as chemical vapor deposition, silicon tetrachloride can be converted into high-purity silicon, which is the key foundation for the manufacture of semiconductor devices such as integrated circuits and chips. Today's electronic technology is changing with each passing day, and semiconductor devices are widely used. They are indispensable in fields such as mobile phones and computers, as well as high-end aerospace and military equipment. In this process, silicon tetrachloride is like a delicate material in the hands of craftsmen, laying the foundation for the construction of a microscopic and complex semiconductor world.
Furthermore, silicon tetrachloride is also of great use in the field of optical fiber communication. Optical fiber is the cornerstone of modern communication, carrying massive information at the speed of light. When manufacturing optical fiber, silicon tetrachloride is required. Using it as raw material, through a specific process, it can be made into an optical fiber preform, and then through the wire drawing process, finally forming a high-quality optical fiber. With silicon tetrachloride, optical fiber can have excellent optical and mechanical properties, ensuring that information is transmitted over long distances with little loss, making global communication closely connected, as close as possible.
In addition, silicon tetrachloride also has a place in the silicone industry. It can be converted into a variety of silicone compounds through chemical reactions. Such compounds are widely used in construction, automotive, textile and many other industries. Such as sealants and waterproof coatings used in construction, silicone compounds can give them excellent weather resistance, water resistance and adhesion; in the automotive industry, silicone rubber is used to make seals, gaskets, etc., which can adapt to different environments and working conditions; in the textile industry, silicone finishing agents can make fabrics soft, anti-wrinkle, waterproof and other excellent properties.
In short, silicon tetrachloride plays an irreplaceable and important role in many key fields such as the semiconductor industry, optical fiber communication and silicone industry, and is an indispensable material for the development of modern industry.
The primary use is in the semiconductor industry. In the manufacture of semiconductor materials, silicon tetrachloride is often used as a source of silicon. Through delicate processes such as chemical vapor deposition, silicon tetrachloride can be converted into high-purity silicon, which is the key foundation for the manufacture of semiconductor devices such as integrated circuits and chips. Today's electronic technology is changing with each passing day, and semiconductor devices are widely used. They are indispensable in fields such as mobile phones and computers, as well as high-end aerospace and military equipment. In this process, silicon tetrachloride is like a delicate material in the hands of craftsmen, laying the foundation for the construction of a microscopic and complex semiconductor world.
Furthermore, silicon tetrachloride is also of great use in the field of optical fiber communication. Optical fiber is the cornerstone of modern communication, carrying massive information at the speed of light. When manufacturing optical fiber, silicon tetrachloride is required. Using it as raw material, through a specific process, it can be made into an optical fiber preform, and then through the wire drawing process, finally forming a high-quality optical fiber. With silicon tetrachloride, optical fiber can have excellent optical and mechanical properties, ensuring that information is transmitted over long distances with little loss, making global communication closely connected, as close as possible.
In addition, silicon tetrachloride also has a place in the silicone industry. It can be converted into a variety of silicone compounds through chemical reactions. Such compounds are widely used in construction, automotive, textile and many other industries. Such as sealants and waterproof coatings used in construction, silicone compounds can give them excellent weather resistance, water resistance and adhesion; in the automotive industry, silicone rubber is used to make seals, gaskets, etc., which can adapt to different environments and working conditions; in the textile industry, silicone finishing agents can make fabrics soft, anti-wrinkle, waterproof and other excellent properties.
In short, silicon tetrachloride plays an irreplaceable and important role in many key fields such as the semiconductor industry, optical fiber communication and silicone industry, and is an indispensable material for the development of modern industry.
What are the environmental effects of 1,2,4,5-tetrachlorobenzene?
1% 2C2% 2C4% 2C5 refers to fluorodichlorotetrabromopentafluoroethane, which has many significant effects on the environment, as follows:
bear the brunt of the damage to the ozone layer. It contains chlorine and bromine atoms. When exposed to ultraviolet rays in the stratosphere, chlorine and bromine atoms escape, triggering a catalytic reaction that causes ozone molecules to decompose. One atom of chlorine can destroy about 100,000 ozone molecules, and bromine atoms are more destructive, about fifty times that of chlorine atoms. The ozone layer shields the sun's ultraviolet rays. If it is destroyed, it will cause excessive ultraviolet radiation to the earth's surface. Humans are overexposed to ultraviolet rays, which increases the risk of skin cancer, cataracts and other diseases. For the biological world, the survival and reproduction of many organisms are affected. For example, plankton are sensitive to ultraviolet rays, and their number reduction will impact the marine food chain.
Furthermore, the greenhouse effect is significant. Although its global warming potential (GWP) is higher than that of carbon dioxide, it has a long lifespan in the atmosphere, can retain and absorb infrared radiation for a long time, and enhance the greenhouse effect. The global climate is affected as a result. The temperature rises, causing glaciers to melt and sea levels to rise, threatening the survival of coastal areas and island residents. Precipitation patterns also change, with frequent rainstorms and floods in some areas, intensifying droughts in some areas, and increasing extreme climate events, affecting agricultural production, water distribution, and ecosystem balance.
In addition, it interferes with tropospheric chemistry. After entering the troposphere, it participates in complex photochemical reactions, which affect the concentration of ozone and other chemical substances in the troposphere. It alters the oxidation of the troposphere, affects the self-purification ability of the atmosphere, and promotes the generation of harmful pollutants, such as causing photochemical smog, which endangers human health and the ecological environment.
To sum up, CFD-tetrabromopentafluoroethane has a severe impact on the environment in many aspects. In view of this, the international community has signed relevant agreements, such as the Montreal Protocol, to limit and phase out the use of such ozone-depleting substances in order to protect the earth's ecological environment.
bear the brunt of the damage to the ozone layer. It contains chlorine and bromine atoms. When exposed to ultraviolet rays in the stratosphere, chlorine and bromine atoms escape, triggering a catalytic reaction that causes ozone molecules to decompose. One atom of chlorine can destroy about 100,000 ozone molecules, and bromine atoms are more destructive, about fifty times that of chlorine atoms. The ozone layer shields the sun's ultraviolet rays. If it is destroyed, it will cause excessive ultraviolet radiation to the earth's surface. Humans are overexposed to ultraviolet rays, which increases the risk of skin cancer, cataracts and other diseases. For the biological world, the survival and reproduction of many organisms are affected. For example, plankton are sensitive to ultraviolet rays, and their number reduction will impact the marine food chain.
Furthermore, the greenhouse effect is significant. Although its global warming potential (GWP) is higher than that of carbon dioxide, it has a long lifespan in the atmosphere, can retain and absorb infrared radiation for a long time, and enhance the greenhouse effect. The global climate is affected as a result. The temperature rises, causing glaciers to melt and sea levels to rise, threatening the survival of coastal areas and island residents. Precipitation patterns also change, with frequent rainstorms and floods in some areas, intensifying droughts in some areas, and increasing extreme climate events, affecting agricultural production, water distribution, and ecosystem balance.
In addition, it interferes with tropospheric chemistry. After entering the troposphere, it participates in complex photochemical reactions, which affect the concentration of ozone and other chemical substances in the troposphere. It alters the oxidation of the troposphere, affects the self-purification ability of the atmosphere, and promotes the generation of harmful pollutants, such as causing photochemical smog, which endangers human health and the ecological environment.
To sum up, CFD-tetrabromopentafluoroethane has a severe impact on the environment in many aspects. In view of this, the international community has signed relevant agreements, such as the Montreal Protocol, to limit and phase out the use of such ozone-depleting substances in order to protect the earth's ecological environment.
What are the physical properties of 1,2,4,5-tetrachlorobenzene
Silicon tetrachloride is a colorless and transparent fuming liquid. Its physical properties are many, and listen to me in detail.
First of all, its appearance is a colorless and transparent fuming liquid with a pungent smell under normal circumstances. It looks like a light smoke curling, which is alarming.
When it comes to density, it is about 1.483g/cm ³, which is heavier than common water. When placed in water, it will sink to the bottom.
The boiling point is quite low, only 76.8 ° C. With a slight application of heat, it will boil and turn into a gaseous state and rise away. And its melting point is not high, at -70 ° C. When it encounters a little low temperature, it will condense into a solid state.
Furthermore, the solubility of silicon tetrachloride also has its own unique features. It can be miscible in organic solvents such as benzene, chloroform, and petroleum ether. It is like a fish entering water and blending seamlessly; otherwise, it will react violently in contact with water, producing silicic acid and hydrogen chloride gas. It can be said that water and fire are incompatible. This reaction is very violent, and it must not be rashly contacted with water.
In addition, silicon tetrachloride is highly volatile. In a room temperature environment, it is easy to evaporate into the air. The volatile gas is highly irritating and damaging to human eyes, respiratory tract, etc. Therefore, when using it, be extremely cautious and take protective measures.
Due to the above, silicon tetrachloride has unique physical properties and requires proper disposal according to its characteristics during use and storage to ensure safety.
First of all, its appearance is a colorless and transparent fuming liquid with a pungent smell under normal circumstances. It looks like a light smoke curling, which is alarming.
When it comes to density, it is about 1.483g/cm ³, which is heavier than common water. When placed in water, it will sink to the bottom.
The boiling point is quite low, only 76.8 ° C. With a slight application of heat, it will boil and turn into a gaseous state and rise away. And its melting point is not high, at -70 ° C. When it encounters a little low temperature, it will condense into a solid state.
Furthermore, the solubility of silicon tetrachloride also has its own unique features. It can be miscible in organic solvents such as benzene, chloroform, and petroleum ether. It is like a fish entering water and blending seamlessly; otherwise, it will react violently in contact with water, producing silicic acid and hydrogen chloride gas. It can be said that water and fire are incompatible. This reaction is very violent, and it must not be rashly contacted with water.
In addition, silicon tetrachloride is highly volatile. In a room temperature environment, it is easy to evaporate into the air. The volatile gas is highly irritating and damaging to human eyes, respiratory tract, etc. Therefore, when using it, be extremely cautious and take protective measures.
Due to the above, silicon tetrachloride has unique physical properties and requires proper disposal according to its characteristics during use and storage to ensure safety.
What are the chemical properties of 1,2,4,5-tetrachlorobenzene
The chemical properties of silicon tetrachloride are particularly important. This is a colorless and transparent liquid with a pungent odor and is highly volatile.
Silicon tetrachloride reacts violently in the air when exposed to water vapor, generating white smoke. The cover reacts with water to produce silicic acid and hydrogen chloride. The reaction formula is roughly as follows: $SiCl_ {4} + 4H_ {2} O = H_ {4} SiO_ {4} + 4HCl $, the resulting hydrogen chloride forms a mist in the air.
Furthermore, silicon tetrachloride is highly corrosive and can erode many metals and organic matter. If it encounters with metals, it may cause corrosion loss on the metal surface.
In addition, silicon tetrachloride has high chemical activity and can react with a variety of substances under specific conditions. For example, when there is a catalyst at high temperature, it can react with hydrogen to form silicon and hydrogen chloride. This reaction is crucial in the preparation of semiconductor materials. The reaction formula is: $SiCl_ {4} + 2H_ {2}\ xlongequal {high temperature} Si + 4HCl $.
Repeat, is silicon tetrachloride flammable? It is non-flammable in itself, but in the fire scene, the products such as hydrogen chloride are extremely dangerous and can endanger life and the environment.
In addition, silicon tetrachloride is also used in the field of organic synthesis. It is often used as a silicon source to participate in the synthesis of many silicone compounds. Due to its active chemical properties, it can provide silicon atoms for organic synthesis, and then construct silicon-containing organic structures.
Silicon tetrachloride reacts violently in the air when exposed to water vapor, generating white smoke. The cover reacts with water to produce silicic acid and hydrogen chloride. The reaction formula is roughly as follows: $SiCl_ {4} + 4H_ {2} O = H_ {4} SiO_ {4} + 4HCl $, the resulting hydrogen chloride forms a mist in the air.
Furthermore, silicon tetrachloride is highly corrosive and can erode many metals and organic matter. If it encounters with metals, it may cause corrosion loss on the metal surface.
In addition, silicon tetrachloride has high chemical activity and can react with a variety of substances under specific conditions. For example, when there is a catalyst at high temperature, it can react with hydrogen to form silicon and hydrogen chloride. This reaction is crucial in the preparation of semiconductor materials. The reaction formula is: $SiCl_ {4} + 2H_ {2}\ xlongequal {high temperature} Si + 4HCl $.
Repeat, is silicon tetrachloride flammable? It is non-flammable in itself, but in the fire scene, the products such as hydrogen chloride are extremely dangerous and can endanger life and the environment.
In addition, silicon tetrachloride is also used in the field of organic synthesis. It is often used as a silicon source to participate in the synthesis of many silicone compounds. Due to its active chemical properties, it can provide silicon atoms for organic synthesis, and then construct silicon-containing organic structures.
What are the production methods of 1,2,4,5-tetrachlorobenzene?
The preparation of tin tetrachloride is discussed in "Tiangong Kaiwu", which follows the ancient method. The first method is to combine tin and chlorine gas. Tin is one of the hardware, which is soft and tough. First take the refined tin, melt it in a crucible, and calcine it in a hot fire until it turns into a liquid and shines. At the same time, make chlorine gas. Co-heating with salt and a strong oxidant, chlorine gas can be obtained. Let chlorine gas pass into the molten tin, and the chlorine gas is yellow-green in color and strong in nature. Tin reacts violently when it encounters chlorine gas, and the fire splashes and the smoke rises. The two combine to give tin tetrachloride. Its smoke is like a mist, and tin tetrachloride appears in the air in a gaseous state. When it is cold, it condenses into droplets, and it is collected and is the finished product.
The second method is to make tin with hydrochloric acid and an oxidizing agent. Take tin and put it in a container, pour an appropriate amount of hydrochloric acid, tin and hydrochloric acid react at the beginning, and bubbles escape, but the rate is quite slow. At this time, add an oxidizing agent, such as manganese dioxide. When the oxidizing agent enters, the reaction suddenly intensifies, and the bubbles gush out like boils. Hydrogen ions in hydrochloric acid cooperate with the oxidizing agent to dissolve tin, and then form tin tetrachloride. After the reaction is completed, pure tin tetrachloride can also be obtained through distillation, purification and other processes.
The ancient method of preparing tin tetrachloride, although the equipment is different from today, its chemical principle is also the same. All are based on the chemical reaction characteristics of tin and related substances, and they are skillfully implemented to achieve the
The second method is to make tin with hydrochloric acid and an oxidizing agent. Take tin and put it in a container, pour an appropriate amount of hydrochloric acid, tin and hydrochloric acid react at the beginning, and bubbles escape, but the rate is quite slow. At this time, add an oxidizing agent, such as manganese dioxide. When the oxidizing agent enters, the reaction suddenly intensifies, and the bubbles gush out like boils. Hydrogen ions in hydrochloric acid cooperate with the oxidizing agent to dissolve tin, and then form tin tetrachloride. After the reaction is completed, pure tin tetrachloride can also be obtained through distillation, purification and other processes.
The ancient method of preparing tin tetrachloride, although the equipment is different from today, its chemical principle is also the same. All are based on the chemical reaction characteristics of tin and related substances, and they are skillfully implemented to achieve the
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