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Benzene, 1-Chloro-2-Isocyanato-4-(Trifluoromethyl)-
Linshang Chemical
|
HS Code |
866199 |
| Chemical Formula | C8H3ClF3NO |
| Molecular Weight | 221.56 |
| Solubility | Soluble in organic solvents like dichloromethane, less so in water |
| Vapor Pressure | Lower than benzene due to larger and more polar groups |
| Flash Point | Unknown, but may be flammable as it contains organic moieties |
| Stability | Stable under normal conditions, but reactive towards nucleophiles due to isocyanato group |
As an accredited Benzene, 1-Chloro-2-Isocyanato-4-(Trifluoromethyl)- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 1 - chloro - 2 - isocyanato - 4 - (trifluoromethyl) benzene: Packaged in 1 - kg bottles for safe storage. |
| Storage | Store "Benzene, 1 - chloro - 2 - isocyanato - 4 - (trifluoromethyl)-" in a cool, well - ventilated area away from heat, ignition sources, and oxidizing agents. Keep it in a tightly - sealed container made of compatible materials, like stainless steel or certain plastics. Segregate from substances that can react, especially amines, alcohols, and water, to prevent dangerous reactions. |
| Shipping | Benzene, 1 - chloro - 2 - isocyanato - 4 - (trifluoromethyl)- is a hazardous chemical. Shipping requires compliance with strict regulations, using appropriate packaging to prevent leaks, and proper labeling indicating its dangerous nature. |
Competitive Benzene, 1-Chloro-2-Isocyanato-4-(Trifluoromethyl)- 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.
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What are the physical properties of 1-chloro-2-isocyanate-4- (trifluoromethyl) benzene
Qi is the origin of all things, and the foundation of physical properties. Today there is a thing called 1-cyanogen-2-isopropionate-4- (triethylamino) osmium, which is a chemically synthesized thing. Its physical properties are unique and can be studied.
The form of this compound, at room temperature, may be in the shape of a solid, the texture may be dense and solid, like the state of gold and stone, or in the shape of a powder, as fine as powder, light and floating. Its color may be white as snow, pure and flawless; or with a slight yellow luster, if the morning light shines, there is a faint light.
In terms of its solubility, in water, or insoluble, such as stone sinking abyss, it cannot be melted; however, in organic solvents, such as ethanol, ether, or soluble, it can be mixed with solvents, if fish get water, it is seamless. This is due to the structure of the object, the interaction of factors such as attractive force and polarity between molecules, which makes it different in different media.
As for its stability, in ordinary environments, if there is no foreign object disturbance, or it can exist safely, the structure remains constant. However, in the case of strong acids and alkalis, or in the realm of high temperature and hot topic, its molecular structure is easily destroyed, chemical changes occur, and in case of fire, it becomes invisible instantaneously.
Furthermore, the conductivity of this object is difficult to migrate electrons in its internal structure, or it is an insulator, and current cannot pass through, such as a wall partition; or it has weak conductivity, like a trickle, and the current is inconspicuous. This is all about the wonderful arrangement of its atoms and the distribution of electron clouds. It cannot be understood without careful investigation.
The physical properties of 1-cyanogen-2-isopropionate-4- (triethylamino) osmium are influenced by many factors, and the morphology, solubility, stability, and conductivity are each in their own state. It is really one of the wonders of the chemical world. It is up to our generation to study it with scientific methods.
The form of this compound, at room temperature, may be in the shape of a solid, the texture may be dense and solid, like the state of gold and stone, or in the shape of a powder, as fine as powder, light and floating. Its color may be white as snow, pure and flawless; or with a slight yellow luster, if the morning light shines, there is a faint light.
In terms of its solubility, in water, or insoluble, such as stone sinking abyss, it cannot be melted; however, in organic solvents, such as ethanol, ether, or soluble, it can be mixed with solvents, if fish get water, it is seamless. This is due to the structure of the object, the interaction of factors such as attractive force and polarity between molecules, which makes it different in different media.
As for its stability, in ordinary environments, if there is no foreign object disturbance, or it can exist safely, the structure remains constant. However, in the case of strong acids and alkalis, or in the realm of high temperature and hot topic, its molecular structure is easily destroyed, chemical changes occur, and in case of fire, it becomes invisible instantaneously.
Furthermore, the conductivity of this object is difficult to migrate electrons in its internal structure, or it is an insulator, and current cannot pass through, such as a wall partition; or it has weak conductivity, like a trickle, and the current is inconspicuous. This is all about the wonderful arrangement of its atoms and the distribution of electron clouds. It cannot be understood without careful investigation.
The physical properties of 1-cyanogen-2-isopropionate-4- (triethylamino) osmium are influenced by many factors, and the morphology, solubility, stability, and conductivity are each in their own state. It is really one of the wonders of the chemical world. It is up to our generation to study it with scientific methods.
What are the chemical properties of 1-chloro-2-isocyanate-4- (trifluoromethyl) benzene
A petrochemical substance, one is alkane, the other is isopropionate, and the other is (triethylmethyl) benzene. Each of these substances has unique chemical properties.
Alkanes belong to hydrocarbons and have a saturated carbon chain structure. Their properties are relatively stable. They are mostly gaseous or liquid at room temperature and pressure, and are difficult to dissolve in water. When burned, carbon dioxide and water are produced, and they are often used as fuels. Because of its carbon-carbon single bond, chemical reactions require high energy to break the bond, resulting in low reactivity and are not easy to react with strong acids, strong bases and strong oxidants.
Isopropionate complex, with isopropionate as the key structure. Isopropionate has a specific charge distribution and spatial configuration, which makes the compound exhibit unique activity in specific chemical reactions. Or it can be used as a ligand to complex with metal ions to form complexes with specific properties, which have important uses in catalysis, materials science and other fields.
(triethylmethyl) benzene has triethyl methyl attached to the benzene ring. The benzene ring has a conjugated large π bond and has a planar ring structure, which gives it special stability. The introduction of triethyl methyl changes the electron cloud density and spatial steric resistance of the benzene ring. The change of electron cloud density affects its electrophilic substitution reaction activity and check point, and the spatial steric resistance plays an important role in the intermolecular interaction and the selectivity of chemical reactions. In organic synthesis, (triethylmethyl) benzene can be used as an important intermediate, and many organic compounds can be derived through various reactions.
These three chemical substances, due to their unique structures, have their own capabilities in different fields, and are an important foundation for the development of chemical, materials, and pharmaceutical industries.
Alkanes belong to hydrocarbons and have a saturated carbon chain structure. Their properties are relatively stable. They are mostly gaseous or liquid at room temperature and pressure, and are difficult to dissolve in water. When burned, carbon dioxide and water are produced, and they are often used as fuels. Because of its carbon-carbon single bond, chemical reactions require high energy to break the bond, resulting in low reactivity and are not easy to react with strong acids, strong bases and strong oxidants.
Isopropionate complex, with isopropionate as the key structure. Isopropionate has a specific charge distribution and spatial configuration, which makes the compound exhibit unique activity in specific chemical reactions. Or it can be used as a ligand to complex with metal ions to form complexes with specific properties, which have important uses in catalysis, materials science and other fields.
(triethylmethyl) benzene has triethyl methyl attached to the benzene ring. The benzene ring has a conjugated large π bond and has a planar ring structure, which gives it special stability. The introduction of triethyl methyl changes the electron cloud density and spatial steric resistance of the benzene ring. The change of electron cloud density affects its electrophilic substitution reaction activity and check point, and the spatial steric resistance plays an important role in the intermolecular interaction and the selectivity of chemical reactions. In organic synthesis, (triethylmethyl) benzene can be used as an important intermediate, and many organic compounds can be derived through various reactions.
These three chemical substances, due to their unique structures, have their own capabilities in different fields, and are an important foundation for the development of chemical, materials, and pharmaceutical industries.
What is the main use of 1-chloro-2-isocyanate-4- (trifluoromethyl) benzene?
1 + -Alkane-2-isopropionate-4- (triethylmethyl) benzene is an important compound in organic chemistry. It has a wide range of uses and plays a key role in many fields.
In the field of medicine, such compounds are often key intermediates in drug synthesis. Due to their unique chemical structure, they can participate in specific reaction pathways and assist in the synthesis of drug molecules with specific pharmacological activities. For example, in the synthesis of some drugs with anti-inflammatory and antibacterial effects, 1 + -alkane-2-isopropionate-4- (triethylmethyl) benzene can undergo a series of reactions to introduce specific functional groups, shape the spatial configuration of the drug molecule, and then endow the drug with precise pharmacological effects.
In the field of materials science, it also has outstanding performance. It can be used as a raw material for the preparation of special performance polymer materials. By polymerizing with other monomers, its special structure can be integrated into the polymer skeleton, giving the material such as good thermal stability, mechanical properties or special optical and electrical properties. For example, when preparing polymer materials for electronic device encapsulation, the introduction of this compound structure can improve the insulation properties and weather resistance of the material, and ensure the stable operation of electronic devices.
In the field of fine chemicals, 1 + -alkane-2-isopropionate-4- (triethylmethyl) benzene is often used in the synthesis of fine chemicals such as fragrances and dyes. Because of its structure, it can provide unique odor characteristics or chromophore groups, which can be used to prepare fragrances with unique aromas, or to synthesize dyes with specific colors and color fastness, to meet the needs of different industries for fine chemicals.
In conclusion, 1 + -alkane-2-isopropionate-4- (triethylmethyl) benzene has shown important uses in many fields such as medicine, materials, and fine chemicals due to its special chemical structure, which is of great significance for promoting the development of related industries.
In the field of medicine, such compounds are often key intermediates in drug synthesis. Due to their unique chemical structure, they can participate in specific reaction pathways and assist in the synthesis of drug molecules with specific pharmacological activities. For example, in the synthesis of some drugs with anti-inflammatory and antibacterial effects, 1 + -alkane-2-isopropionate-4- (triethylmethyl) benzene can undergo a series of reactions to introduce specific functional groups, shape the spatial configuration of the drug molecule, and then endow the drug with precise pharmacological effects.
In the field of materials science, it also has outstanding performance. It can be used as a raw material for the preparation of special performance polymer materials. By polymerizing with other monomers, its special structure can be integrated into the polymer skeleton, giving the material such as good thermal stability, mechanical properties or special optical and electrical properties. For example, when preparing polymer materials for electronic device encapsulation, the introduction of this compound structure can improve the insulation properties and weather resistance of the material, and ensure the stable operation of electronic devices.
In the field of fine chemicals, 1 + -alkane-2-isopropionate-4- (triethylmethyl) benzene is often used in the synthesis of fine chemicals such as fragrances and dyes. Because of its structure, it can provide unique odor characteristics or chromophore groups, which can be used to prepare fragrances with unique aromas, or to synthesize dyes with specific colors and color fastness, to meet the needs of different industries for fine chemicals.
In conclusion, 1 + -alkane-2-isopropionate-4- (triethylmethyl) benzene has shown important uses in many fields such as medicine, materials, and fine chemicals due to its special chemical structure, which is of great significance for promoting the development of related industries.
What are the preparation methods of 1-chloro-2-isocyanate-4- (trifluoromethyl) benzene?
There are several methods for preparing 1-alkane-2-isoalkanoic-4- (triethyl alkyl) tin.
First, react with alkane-containing halides and isoalkanoic-containing metal salts in appropriate solvents at suitable temperatures and conditions. For example, choose a stable organic solvent, such as ethers or aromatics, and put the two in a certain proportion, slowly raise the temperature, so that the reaction can be fully carried out. During the process, attention should be paid to the regulation of the reaction temperature. It is not too high to cause side reactions to breed, nor too low to slow down the reaction. Through this reaction, halogen ions combine with metal ions to form salts, while alkane and isoalkanate are combined with tin atoms to gradually form the target product.
Second, tin halides can react with organic compounds containing alkanes and isoalkanates. Among them, tin halides have high activity and are prone to substitution reactions with other organic compounds. Compounds containing alkanes and isoalkanates with specific structures are mixed with tin halides, and the reaction process is accelerated with the help of catalysts. The choice of catalysts is crucial. It is necessary to choose their activity and selectivity adapters according to the reaction characteristics to improve the yield of the target product. The reaction environment also needs to be carefully controlled, and the conditions of anhydrous and oxygen-free are often preferred to prevent hydrolysis of tin halides or other adverse reactions.
Third, the reaction of triethylalkyl-containing organotin compounds with alkyl and isoalkanate-containing reagents. First prepare high-purity triethylalkyl organotin, and then make it meet with carefully selected alkyl-containing and isoalkanate-containing reagents. This reaction requires very strict requirements on the purity and reaction sequence of the reagents, and should be added in a specific order to ensure that the reaction proceeds according to the preset path. At the same time, the pH, temperature, time and other factors of the reaction system need to be precisely controlled to obtain the ideal product yield and purity. After careful operation and optimization of conditions, 1-alkane-2-isoalkanoic-4- (triethylalkyl) tin can be obtained.
First, react with alkane-containing halides and isoalkanoic-containing metal salts in appropriate solvents at suitable temperatures and conditions. For example, choose a stable organic solvent, such as ethers or aromatics, and put the two in a certain proportion, slowly raise the temperature, so that the reaction can be fully carried out. During the process, attention should be paid to the regulation of the reaction temperature. It is not too high to cause side reactions to breed, nor too low to slow down the reaction. Through this reaction, halogen ions combine with metal ions to form salts, while alkane and isoalkanate are combined with tin atoms to gradually form the target product.
Second, tin halides can react with organic compounds containing alkanes and isoalkanates. Among them, tin halides have high activity and are prone to substitution reactions with other organic compounds. Compounds containing alkanes and isoalkanates with specific structures are mixed with tin halides, and the reaction process is accelerated with the help of catalysts. The choice of catalysts is crucial. It is necessary to choose their activity and selectivity adapters according to the reaction characteristics to improve the yield of the target product. The reaction environment also needs to be carefully controlled, and the conditions of anhydrous and oxygen-free are often preferred to prevent hydrolysis of tin halides or other adverse reactions.
Third, the reaction of triethylalkyl-containing organotin compounds with alkyl and isoalkanate-containing reagents. First prepare high-purity triethylalkyl organotin, and then make it meet with carefully selected alkyl-containing and isoalkanate-containing reagents. This reaction requires very strict requirements on the purity and reaction sequence of the reagents, and should be added in a specific order to ensure that the reaction proceeds according to the preset path. At the same time, the pH, temperature, time and other factors of the reaction system need to be precisely controlled to obtain the ideal product yield and purity. After careful operation and optimization of conditions, 1-alkane-2-isoalkanoic-4- (triethylalkyl) tin can be obtained.
Precautions for storage and transportation of 1-chloro-2-isocyanate-4- (trifluoromethyl) benzene
When storing and transporting mercury, isocyanate, and (triethylmethyl) silicon, the following matters should be paid attention to:
Mercury is a liquid metal at room temperature, and it is volatile, and its vapor is highly toxic. When storing, be sure to place it in an airtight container to prevent mercury vapor from escaping into the air. Containers need to be solid and free from leakage, and thick-walled glass or metal containers are usually used. Store in a cool, well-ventilated place, away from heat and fire sources. Due to the increase in temperature, mercury volatilization will increase. In addition, mercury has a corrosive effect on certain metals, so avoid contact with metals such as aluminum.
Isocyanate is active in nature and easily reacts with substances containing active hydrogen. When storing, ensure that the environment is dry to prevent contact with water, alcohol, amine and other substances, otherwise it is easy to cause violent reactions. The container should be strictly sealed to prevent the intrusion of water vapor in the air. During transportation, heat insulation and shock-proof measures should be taken to avoid damage to the container due to temperature changes and collisions, and leakage of isocyanate.
(triethylmethyl) silicon, generally sensitive to air and water. Storage should be in a dry, oxygen-free environment, often in a sealed container filled with inert gases (such as nitrogen). Storage location should be kept away from fire sources, oxidants, etc. During transportation, ensure that the packaging is intact to prevent damage to the packaging caused by bumps and contact with air and moisture. In the event of a leak, (triethylmethyl) silicon may produce harmful gases in contact with water, and emergency measures need to be taken quickly to evacuate personnel and properly dispose of them.
All three must strictly follow relevant safety regulations during storage and transportation, and operators must also have professional knowledge and skills to take protective measures to ensure the safety of personnel and the environment.
Mercury is a liquid metal at room temperature, and it is volatile, and its vapor is highly toxic. When storing, be sure to place it in an airtight container to prevent mercury vapor from escaping into the air. Containers need to be solid and free from leakage, and thick-walled glass or metal containers are usually used. Store in a cool, well-ventilated place, away from heat and fire sources. Due to the increase in temperature, mercury volatilization will increase. In addition, mercury has a corrosive effect on certain metals, so avoid contact with metals such as aluminum.
Isocyanate is active in nature and easily reacts with substances containing active hydrogen. When storing, ensure that the environment is dry to prevent contact with water, alcohol, amine and other substances, otherwise it is easy to cause violent reactions. The container should be strictly sealed to prevent the intrusion of water vapor in the air. During transportation, heat insulation and shock-proof measures should be taken to avoid damage to the container due to temperature changes and collisions, and leakage of isocyanate.
(triethylmethyl) silicon, generally sensitive to air and water. Storage should be in a dry, oxygen-free environment, often in a sealed container filled with inert gases (such as nitrogen). Storage location should be kept away from fire sources, oxidants, etc. During transportation, ensure that the packaging is intact to prevent damage to the packaging caused by bumps and contact with air and moisture. In the event of a leak, (triethylmethyl) silicon may produce harmful gases in contact with water, and emergency measures need to be taken quickly to evacuate personnel and properly dispose of them.
All three must strictly follow relevant safety regulations during storage and transportation, and operators must also have professional knowledge and skills to take protective measures to ensure the safety of personnel and the environment.
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