Linshang Chemical
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4-(Trifluoromethoxy)Chlorobenzene
Linshang Chemical
|
HS Code |
880493 |
| Chemical Formula | C7H4ClF3O |
| Molar Mass | 196.553 g/mol |
| Appearance | Colorless to light yellow liquid |
| Boiling Point | 156 - 158 °C |
| Melting Point | N/A |
| Density | 1.394 g/cm³ |
| Flash Point | 45 °C |
| Solubility In Water | Insoluble |
| Vapor Pressure | N/A |
| Refractive Index | 1.437 |
As an accredited 4-(Trifluoromethoxy)Chlorobenzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100 - gram bottle packaging for 4-(trifluoromethoxy)chlorobenzene chemical. |
| Storage | 4-(Trifluoromethoxy)chlorobenzene should be stored in a cool, well - ventilated area away from heat, sparks, and open flames. Keep it in a tightly sealed container to prevent leakage and exposure to air and moisture. Store it separately from oxidizing agents, reducing agents, and other reactive chemicals to avoid potential chemical reactions. |
| Shipping | 4-(Trifluoromethoxy)chlorobenzene is shipped in tightly sealed, corrosion - resistant containers. Special handling procedures are followed to ensure safety during transit due to its chemical nature. Shipment is compliant with all relevant regulations. |
Competitive 4-(Trifluoromethoxy)Chlorobenzene 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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Tel: +8615365006308
Email: info@alchemist-chem.com
Where to Buy 4-(Trifluoromethoxy)Chlorobenzene in China?
As a trusted 4-(Trifluoromethoxy)Chlorobenzene 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 4-(Trifluoromethoxy)Chlorobenzene 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 4- (trifluoromethoxy) chlorobenzene?
(Triethoxy) silane has a wide range of uses. It plays an indispensable role in the field of construction. It can be used as a waterproof agent and applied to the surface of masonry and concrete to prevent water infiltration and increase its durability. Masonry is exposed to wind and rain for a long time and is easy to be eroded. With this silane, it is like a protective armor, water is difficult to infiltrate, and the masonry is as strong as ever, prolonging the life of the building.
It is also very useful in the automobile manufacturing industry. It can treat the surface of automobile parts and enhance the adhesion of the coating. If the parts are directly painted, or due to the surface properties, the paint is easy to peel off. After (triethoxy) silane treatment, the surface is closely connected to the paint layer, the paint is not easy to take off, the appearance of the car is more lasting and bright, and it has the effect of protecting parts and reducing its damage from environmental erosion.
In the electronics industry, it is also indispensable. It can be used for surface modification of semiconductor materials to optimize their performance. Semiconductor materials are crucial in electronic equipment, and their performance is related to the operation of equipment. After this silane treatment, the surface properties of semiconductors can be precisely regulated, making them more suitable for the needs of electronic components, improving the stability and reliability of electronic equipment, and contributing to the progress of electronic technology.
In the preparation of composite materials, (triethoxy) silane is a key additive. It can improve the bonding force between the reinforcing phase and the matrix, so that the performance of the composite material is better. Such as glass fiber reinforced plastics, if the combination between glass fiber and plastic matrix is not good, the material strength and other properties will be affected. With this silane, the two can be closely connected, giving full play to the glass fiber reinforcement effect, the strength of the composite material is greatly increased, and the application range has to be expanded.
It is also very useful in the automobile manufacturing industry. It can treat the surface of automobile parts and enhance the adhesion of the coating. If the parts are directly painted, or due to the surface properties, the paint is easy to peel off. After (triethoxy) silane treatment, the surface is closely connected to the paint layer, the paint is not easy to take off, the appearance of the car is more lasting and bright, and it has the effect of protecting parts and reducing its damage from environmental erosion.
In the electronics industry, it is also indispensable. It can be used for surface modification of semiconductor materials to optimize their performance. Semiconductor materials are crucial in electronic equipment, and their performance is related to the operation of equipment. After this silane treatment, the surface properties of semiconductors can be precisely regulated, making them more suitable for the needs of electronic components, improving the stability and reliability of electronic equipment, and contributing to the progress of electronic technology.
In the preparation of composite materials, (triethoxy) silane is a key additive. It can improve the bonding force between the reinforcing phase and the matrix, so that the performance of the composite material is better. Such as glass fiber reinforced plastics, if the combination between glass fiber and plastic matrix is not good, the material strength and other properties will be affected. With this silane, the two can be closely connected, giving full play to the glass fiber reinforcement effect, the strength of the composite material is greatly increased, and the application range has to be expanded.
What are the physical properties of 4- (trifluoromethoxy) chlorobenzene?
Tris (hydroxyethyl) aminosilane, which is one of the organosilicon compounds. Its physical properties are particularly important and have a great impact on practical applications.
Looking at its properties, it is mostly colorless to light yellow transparent liquid under normal conditions. This characteristic makes it easy to disperse and mix in many reaction systems, laying a good foundation for the subsequent reaction process.
The boiling point is about a certain range, which determines its volatilization during heating operation. Proper temperature control can effectively utilize it to participate in the reaction, and avoid premature dispersion to ensure that the reaction is fully carried out.
The melting point also has a specific value, which indicates the required conditions for the substance to convert from solid to liquid. Knowing the melting point is of great significance in storage and pre-treatment. It can be properly stored according to it to prevent its state from changing due to improper temperature and affecting the performance of use.
In terms of solubility, it can be soluble in some organic solvents, which is extremely critical. The choice of organic solvent needs to match its solubility in order to make the silane evenly dispersed in the system to achieve good reaction effect or play a specific function. For example, when used as a surface treatment agent, it can better interact with the surface of the material.
In addition, density is also an important physical parameter, reflecting the quality of the substance per unit volume. In the process of accurate proportioning and metering, the consideration of density is indispensable, and it is related to the quality and performance of the final product.
In summary, the physical properties of tris (hydroxyethyl) aminosilane, such as properties, boiling point, melting point, solubility, and density, each have their own uses, and they need to be carefully considered in many fields such as chemical engineering and materials to achieve the best application results.
Looking at its properties, it is mostly colorless to light yellow transparent liquid under normal conditions. This characteristic makes it easy to disperse and mix in many reaction systems, laying a good foundation for the subsequent reaction process.
The boiling point is about a certain range, which determines its volatilization during heating operation. Proper temperature control can effectively utilize it to participate in the reaction, and avoid premature dispersion to ensure that the reaction is fully carried out.
The melting point also has a specific value, which indicates the required conditions for the substance to convert from solid to liquid. Knowing the melting point is of great significance in storage and pre-treatment. It can be properly stored according to it to prevent its state from changing due to improper temperature and affecting the performance of use.
In terms of solubility, it can be soluble in some organic solvents, which is extremely critical. The choice of organic solvent needs to match its solubility in order to make the silane evenly dispersed in the system to achieve good reaction effect or play a specific function. For example, when used as a surface treatment agent, it can better interact with the surface of the material.
In addition, density is also an important physical parameter, reflecting the quality of the substance per unit volume. In the process of accurate proportioning and metering, the consideration of density is indispensable, and it is related to the quality and performance of the final product.
In summary, the physical properties of tris (hydroxyethyl) aminosilane, such as properties, boiling point, melting point, solubility, and density, each have their own uses, and they need to be carefully considered in many fields such as chemical engineering and materials to achieve the best application results.
What are the chemical properties of 4- (trifluoromethoxy) chlorobenzene?
The chemical properties of trichloroacetoxy silane are particularly important. This is a genus of organosilicon compounds with unique reactive properties.
Its hydrolysis property is easy to cause hydrolysis in contact with water. The silicone-chlorine bond (Si-Cl) is broken by water, and the siloxyl group (Si-OH) and hydrogen chloride (HCl). During the hydrolysis process, the hydrogen chloride escapes, and the silanol groups condense with each other to form a silicone bond (Si-O-Si), which can cause cross-linking between molecules to form a polysiloxane structure.
As far as its reaction with alcohols is concerned, it can undergo alcoholysis reaction with alcohols, and the silica-chlorine bond interacts with the hydroxyl group (-OH) of the alcohol. The chlorine atom is replaced by an alkoxy group (-OR), and the silica-ether bond (Si-O-R) is produced. This reaction is controllable and has a wide range of uses in the preparation of organosilicon compounds with specific structures.
In the reaction with compounds containing active hydrogen, the active hydrogen atom can be substituted with the silica-chlorine bond of trichloroacetoxysilane. For example, when reacting with amine compounds, hydrogen on amine nitrogen reacts with silicon-chlorine bonds to obtain products containing silicon-nitrogen bonds (Si-N), which are often specific in the fields of materials science and organic synthesis.
Trichloroacetoxysilane has high reactivity and is often a key raw material in the synthesis and surface modification of silicone materials. However, due to its reactivity, it is necessary to pay attention to the control of conditions when using it, such as reaction temperature, ratio of reactants, choice of solvent, etc., in order to obtain the expected product and achieve the required properties.
Its hydrolysis property is easy to cause hydrolysis in contact with water. The silicone-chlorine bond (Si-Cl) is broken by water, and the siloxyl group (Si-OH) and hydrogen chloride (HCl). During the hydrolysis process, the hydrogen chloride escapes, and the silanol groups condense with each other to form a silicone bond (Si-O-Si), which can cause cross-linking between molecules to form a polysiloxane structure.
As far as its reaction with alcohols is concerned, it can undergo alcoholysis reaction with alcohols, and the silica-chlorine bond interacts with the hydroxyl group (-OH) of the alcohol. The chlorine atom is replaced by an alkoxy group (-OR), and the silica-ether bond (Si-O-R) is produced. This reaction is controllable and has a wide range of uses in the preparation of organosilicon compounds with specific structures.
In the reaction with compounds containing active hydrogen, the active hydrogen atom can be substituted with the silica-chlorine bond of trichloroacetoxysilane. For example, when reacting with amine compounds, hydrogen on amine nitrogen reacts with silicon-chlorine bonds to obtain products containing silicon-nitrogen bonds (Si-N), which are often specific in the fields of materials science and organic synthesis.
Trichloroacetoxysilane has high reactivity and is often a key raw material in the synthesis and surface modification of silicone materials. However, due to its reactivity, it is necessary to pay attention to the control of conditions when using it, such as reaction temperature, ratio of reactants, choice of solvent, etc., in order to obtain the expected product and achieve the required properties.
What is the production method of 4- (trifluoromethoxy) chlorobenzene?
The method of making triethoxysilane is obtained by reacting silicon powder and ethanol as raw materials, accompanied by a copper catalyst, at a specific temperature and pressure.
The process is as follows: First select the silicon powder carefully to ensure that the purity and particle size are appropriate. The purity of the silicon powder is related to the quality of the product, and the particle size affects the reaction rate. After choosing, put it into a special reactor with ethanol in a certain proportion. The amount of ethanol needs to be precisely controlled. Too much or too little can affect the reaction process.
The copper catalyst is taken for the second time, which is the key to the reaction. Its activity and stability affect the reaction efficiency and product yield. Add the catalyst to the reactor in an appropriate proportion and mix it thoroughly with silicon powder and ethanol.
Then, strictly adjust the temperature and pressure of the reactor. If the temperature is too low, the reaction will be slow; if the temperature is too high, side reactions will occur. The same is true for the pressure, which must be maintained in a suitable range to make the reaction proceed smoothly in the direction of generating triethoxysilane.
During the reaction, closely monitor various parameters, such as temperature, pressure, and concentration of reactants. Fine-tune in a timely manner to ensure stable reaction. After the reaction is completed, the product is finely separated by distillation, distillation, and other fine separation processes to remove impurities and obtain pure triethoxysilane.
This preparation method has been studied and improved by many craftsmen and is now mature. It is a common and good method for obtaining triethoxysilane.
The process is as follows: First select the silicon powder carefully to ensure that the purity and particle size are appropriate. The purity of the silicon powder is related to the quality of the product, and the particle size affects the reaction rate. After choosing, put it into a special reactor with ethanol in a certain proportion. The amount of ethanol needs to be precisely controlled. Too much or too little can affect the reaction process.
The copper catalyst is taken for the second time, which is the key to the reaction. Its activity and stability affect the reaction efficiency and product yield. Add the catalyst to the reactor in an appropriate proportion and mix it thoroughly with silicon powder and ethanol.
Then, strictly adjust the temperature and pressure of the reactor. If the temperature is too low, the reaction will be slow; if the temperature is too high, side reactions will occur. The same is true for the pressure, which must be maintained in a suitable range to make the reaction proceed smoothly in the direction of generating triethoxysilane.
During the reaction, closely monitor various parameters, such as temperature, pressure, and concentration of reactants. Fine-tune in a timely manner to ensure stable reaction. After the reaction is completed, the product is finely separated by distillation, distillation, and other fine separation processes to remove impurities and obtain pure triethoxysilane.
This preparation method has been studied and improved by many craftsmen and is now mature. It is a common and good method for obtaining triethoxysilane.
What should be paid attention to when storing and transporting 4- (trifluoromethoxy) chlorobenzene?
When storing and transporting (triethylamino) silicone oil, many key matters must be paid attention to.
First, the storage environment is crucial. This silicone oil should be stored in a cool, dry and well-ventilated place. Do not place it in a high temperature or humid place, because high temperature can easily cause changes in the properties of silicone oil, and humid environment may cause deterioration. If the temperature is too high, the movement of silicone oil molecules will intensify, which may affect its stability; and if humid air is mixed with silicone oil, or chemical reactions such as hydrolysis can damage the quality of silicone oil.
Second, the packaging must be tight. The packaging container should be well sealed to prevent the intrusion of external impurities and avoid the volatilization of silicone oil. Use packaging of suitable materials, such as corrosion-resistant plastic drums or metal drums, and choose according to the characteristics of silicone oil to effectively protect silicone oil. If the packaging is not strict, impurities are mixed in, or there are problems with silicone oil during application, reducing its use efficiency.
Third, care should be taken during transportation. Handle with care to avoid severe vibration and collision. Although silicone oil has certain stability, excessive vibration or collision may cause package damage and silicone oil leakage. At the same time, the transportation tool should also be kept clean and dry to prevent mixing with other chemical substances to prevent adverse reactions. If mixed with incompatible substances, it is very likely to cause chemical reactions, change the properties of silicone oil, and fail to achieve the expected use effect.
Fourth, strictly follow the relevant regulations. Whether it is storage or transportation, it must be carried out in accordance with the relevant regulations and standards of chemicals. Operators should be familiar with the characteristics of silicone oil and safety precautions, and take protective measures, such as wearing appropriate protective gloves, goggles, etc., to ensure personal safety and environmental safety. Ignoring regulations and standards may not only face legal risks, but also easily cause safety accidents during operation, endangering personnel and the environment.
First, the storage environment is crucial. This silicone oil should be stored in a cool, dry and well-ventilated place. Do not place it in a high temperature or humid place, because high temperature can easily cause changes in the properties of silicone oil, and humid environment may cause deterioration. If the temperature is too high, the movement of silicone oil molecules will intensify, which may affect its stability; and if humid air is mixed with silicone oil, or chemical reactions such as hydrolysis can damage the quality of silicone oil.
Second, the packaging must be tight. The packaging container should be well sealed to prevent the intrusion of external impurities and avoid the volatilization of silicone oil. Use packaging of suitable materials, such as corrosion-resistant plastic drums or metal drums, and choose according to the characteristics of silicone oil to effectively protect silicone oil. If the packaging is not strict, impurities are mixed in, or there are problems with silicone oil during application, reducing its use efficiency.
Third, care should be taken during transportation. Handle with care to avoid severe vibration and collision. Although silicone oil has certain stability, excessive vibration or collision may cause package damage and silicone oil leakage. At the same time, the transportation tool should also be kept clean and dry to prevent mixing with other chemical substances to prevent adverse reactions. If mixed with incompatible substances, it is very likely to cause chemical reactions, change the properties of silicone oil, and fail to achieve the expected use effect.
Fourth, strictly follow the relevant regulations. Whether it is storage or transportation, it must be carried out in accordance with the relevant regulations and standards of chemicals. Operators should be familiar with the characteristics of silicone oil and safety precautions, and take protective measures, such as wearing appropriate protective gloves, goggles, etc., to ensure personal safety and environmental safety. Ignoring regulations and standards may not only face legal risks, but also easily cause safety accidents during operation, endangering personnel and the environment.
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