Linshang Chemical
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2-(Trifluoromethoxy)Chlorobenzene
Linshang Chemical
|
HS Code |
622465 |
| Chemical Formula | C7H4ClF3O |
| Molar Mass | 196.554 g/mol |
| Appearance | Liquid (usually) |
| Boiling Point | Around 156 - 158 °C |
| Density | Data may vary, around 1.4 g/cm³ (estimated) |
| Solubility In Water | Low solubility |
| Solubility In Organic Solvents | Soluble in common organic solvents like ethanol, ether |
| Vapor Pressure | Relatively low at room temperature |
| Flash Point | Data may vary, typically flammable liquid with a flash point in a certain range |
As an accredited 2-(Trifluoromethoxy)Chlorobenzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 500 - gram bottle of 2-(trifluoromethoxy)chlorobenzene, well - sealed for chemical storage. |
| Storage | 2-(Trifluoromethoxy)chlorobenzene should be stored in a cool, well - ventilated area, away from heat sources and open flames. It should be stored in a tightly - sealed container to prevent leakage and evaporation. Keep it separate from oxidizing agents and reactive substances. Comply with local regulations regarding chemical storage to ensure safety. |
| Shipping | 2-(Trifluoromethoxy)chlorobenzene is shipped in accordance with chemical transportation regulations. Packed in suitable containers to prevent leakage, it's transported by means compliant with safety standards for hazardous chemicals. |
Competitive 2-(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.
We will respond to you as soon as possible.
Tel: +8615365006308
Email: info@alchemist-chem.com
Where to Buy 2-(Trifluoromethoxy)Chlorobenzene in China?
As a trusted 2-(Trifluoromethoxy)Chlorobenzene manufacturer, we deliver:
Factory-Direct Value: Competitive pricing with no middleman markups, tailored for bulk orders and project-scale requirements.
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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 2-(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 2- (trifluoromethoxy) chlorobenzene?
(Triethoxy) silane has many functions and is of great importance in many fields.
First, in the field of construction, it is an excellent waterproof agent. It can penetrate into the interior of building materials and generate a hydrophobic siloxane network structure on the surface of pores, which greatly enhances the waterproof performance of materials. For example, building substrates such as masonry and concrete, after being treated with (triethoxy) silane, can effectively resist rain erosion, prevent freezing and thawing damage caused by water penetration, and corrosion of steel bars, which greatly prolongs the service life of buildings. The so-called "water is the enemy of construction, and this agent is the shield against water". With its unique chemical structure, it is closely attached to the surface of the material to build a strong waterproof defense line.
Second, in the coating industry, it is a key adhesion promoter. It can chemically react with the resin in the coating and the hydroxyl group on the surface of the substrate, forming a chemical bond between the coating and the substrate, which significantly improves the adhesion of the coating to the substrate. Whether it is a metal, wood or plastic substrate, after adding (triethoxy) silane, the adhesion performance of the coating is greatly improved, and it is not easy to fall off and peel, making the coating more stable and lasting, just like building a close bridge between the coating and the substrate to ensure the long-term stability of the coating.
Third, in the preparation of composite materials, it acts as a coupling agent. It can establish a communication bridge between inorganic fillers and organic polymer matrices to improve the compatibility and interfacial bonding between the two. When inorganic fillers (such as glass fiber, talc, etc.) are treated with (triethoxy) silane, they can be better dispersed in the organic polymer matrix and enhance the mechanical properties of the composites, such as tensile strength, bending strength, impact strength, etc., which can significantly improve the performance of the composites. It is widely used in aerospace, automobile manufacturing and other fields that require strict material properties.
First, in the field of construction, it is an excellent waterproof agent. It can penetrate into the interior of building materials and generate a hydrophobic siloxane network structure on the surface of pores, which greatly enhances the waterproof performance of materials. For example, building substrates such as masonry and concrete, after being treated with (triethoxy) silane, can effectively resist rain erosion, prevent freezing and thawing damage caused by water penetration, and corrosion of steel bars, which greatly prolongs the service life of buildings. The so-called "water is the enemy of construction, and this agent is the shield against water". With its unique chemical structure, it is closely attached to the surface of the material to build a strong waterproof defense line.
Second, in the coating industry, it is a key adhesion promoter. It can chemically react with the resin in the coating and the hydroxyl group on the surface of the substrate, forming a chemical bond between the coating and the substrate, which significantly improves the adhesion of the coating to the substrate. Whether it is a metal, wood or plastic substrate, after adding (triethoxy) silane, the adhesion performance of the coating is greatly improved, and it is not easy to fall off and peel, making the coating more stable and lasting, just like building a close bridge between the coating and the substrate to ensure the long-term stability of the coating.
Third, in the preparation of composite materials, it acts as a coupling agent. It can establish a communication bridge between inorganic fillers and organic polymer matrices to improve the compatibility and interfacial bonding between the two. When inorganic fillers (such as glass fiber, talc, etc.) are treated with (triethoxy) silane, they can be better dispersed in the organic polymer matrix and enhance the mechanical properties of the composites, such as tensile strength, bending strength, impact strength, etc., which can significantly improve the performance of the composites. It is widely used in aerospace, automobile manufacturing and other fields that require strict material properties.
What are the physical properties of 2- (trifluoromethoxy) chlorobenzene?
(Triethoxy) silane, its physical properties can be studied. Looking at its shape, under normal circumstances, it is mostly a clear and colorless liquid, pure and transparent, such as the clarity of a clear spring, showing its pure state.
Smell it, it has a weak and specific smell, not pungent and intolerable, but it is also different from ordinary tasteless things. Although this smell is light, it can be used to distinguish it.
When it comes to volatility, it is quite volatile and placed in the air, just like the lightness of the elf, which gradually fades into invisibility. This property makes it exist in the surrounding gaseous state, so when using it, pay attention to its volatilization and place it properly.
Then again, its solubility can be miscible with many organic solvents, such as alcohols and ethers, which are like water emulsion blending, and the phase is seamless. However, in water, its solubility is not very good. When it encounters water, it is like the barrier between oil and water, and it is difficult to blend.
When it comes to density, it is lighter than water. If it is based on water, it floats on water, like wood floats on blue waves. This property also makes it look different when the state of matter is separated.
Melting point and boiling point are also key to its characteristics. Its melting point is quite low, and at room temperature, it is in the form of a liquid state, and there is no need for high temperature to melt it. The boiling point is relatively moderate, heated to a specific temperature, and then transformed into gaseous ascension.
(triethoxy) silane's physical properties, morphology, odor, volatilization, solubility, density, and melting and boiling point are all its unique characteristics. Among all kinds of uses, each can show its own ability.
Smell it, it has a weak and specific smell, not pungent and intolerable, but it is also different from ordinary tasteless things. Although this smell is light, it can be used to distinguish it.
When it comes to volatility, it is quite volatile and placed in the air, just like the lightness of the elf, which gradually fades into invisibility. This property makes it exist in the surrounding gaseous state, so when using it, pay attention to its volatilization and place it properly.
Then again, its solubility can be miscible with many organic solvents, such as alcohols and ethers, which are like water emulsion blending, and the phase is seamless. However, in water, its solubility is not very good. When it encounters water, it is like the barrier between oil and water, and it is difficult to blend.
When it comes to density, it is lighter than water. If it is based on water, it floats on water, like wood floats on blue waves. This property also makes it look different when the state of matter is separated.
Melting point and boiling point are also key to its characteristics. Its melting point is quite low, and at room temperature, it is in the form of a liquid state, and there is no need for high temperature to melt it. The boiling point is relatively moderate, heated to a specific temperature, and then transformed into gaseous ascension.
(triethoxy) silane's physical properties, morphology, odor, volatilization, solubility, density, and melting and boiling point are all its unique characteristics. Among all kinds of uses, each can show its own ability.
What are the synthesis methods of 2- (trifluoromethoxy) chlorobenzene?
There are several ways to make di- (triethoxy) silane.
First, it can be obtained by reacting silica powder with ethanol and hydrogen chloride gas under specific conditions. The silica powder is placed in a special reactor, an appropriate amount of hydrogen chloride gas is introduced, and ethanol is added to control the reaction temperature and pressure. During the reaction, silica powder interacts with hydrogen chloride and ethanol, and undergoes a series of complex chemical changes to form di- (triethoxy) silane for life. This process requires precise control of the reaction conditions. If the temperature is too high or too low, the reaction rate may be abnormal and the product is impure.
Second, trichlorosilane and ethanol are used as raw materials. The trichlorosilane is slowly dripped into the ethanol, and a catalyst is used to assist the reaction. The catalyst can reduce the activation energy of the reaction, making the reaction easier to proceed. With the addition of trichlorosilane, the two react rapidly to form di- (triethoxy) silane and hydrogen chloride gas. The generated hydrogen chloride needs to be removed in time to promote the reaction to move in the direction of product formation, and the amount of ethanol needs to be accurately calculated. Excess or deficiency affects the yield and purity of the product.
Third, it can also be prepared by hydrolysis and condensation of silicone-containing organic compounds. First, take a suitable silicone-containing organic compound and hydrolyze it under acidic or basic conditions to break the original chemical bond and form a silicon-containing intermediate. Subsequently, the intermediate is condensed under specific conditions, and the hydroxyl groups interact to dehydrate the water molecules, gradually forming the structure of di- (triethoxy) silane. This method requires quite high requirements on the purity of the reaction conditions and raw materials. The steps of hydrolysis and condensation need to be carefully regulated to obtain high-purity bis- (triethoxy) silane.
The above methods have advantages and disadvantages. In actual preparation, the optimal method should be selected according to the availability of raw materials, cost, product purity requirements and other factors.
First, it can be obtained by reacting silica powder with ethanol and hydrogen chloride gas under specific conditions. The silica powder is placed in a special reactor, an appropriate amount of hydrogen chloride gas is introduced, and ethanol is added to control the reaction temperature and pressure. During the reaction, silica powder interacts with hydrogen chloride and ethanol, and undergoes a series of complex chemical changes to form di- (triethoxy) silane for life. This process requires precise control of the reaction conditions. If the temperature is too high or too low, the reaction rate may be abnormal and the product is impure.
Second, trichlorosilane and ethanol are used as raw materials. The trichlorosilane is slowly dripped into the ethanol, and a catalyst is used to assist the reaction. The catalyst can reduce the activation energy of the reaction, making the reaction easier to proceed. With the addition of trichlorosilane, the two react rapidly to form di- (triethoxy) silane and hydrogen chloride gas. The generated hydrogen chloride needs to be removed in time to promote the reaction to move in the direction of product formation, and the amount of ethanol needs to be accurately calculated. Excess or deficiency affects the yield and purity of the product.
Third, it can also be prepared by hydrolysis and condensation of silicone-containing organic compounds. First, take a suitable silicone-containing organic compound and hydrolyze it under acidic or basic conditions to break the original chemical bond and form a silicon-containing intermediate. Subsequently, the intermediate is condensed under specific conditions, and the hydroxyl groups interact to dehydrate the water molecules, gradually forming the structure of di- (triethoxy) silane. This method requires quite high requirements on the purity of the reaction conditions and raw materials. The steps of hydrolysis and condensation need to be carefully regulated to obtain high-purity bis- (triethoxy) silane.
The above methods have advantages and disadvantages. In actual preparation, the optimal method should be selected according to the availability of raw materials, cost, product purity requirements and other factors.
What are the precautions for storing and transporting 2- (trifluoromethoxy) chlorobenzene?
(Triethoxy) silane, when storing and transporting, there are several ends to pay attention to.
First, it is related to storage. This substance should be stored in a cool, dry and well-ventilated place. If placed in a high temperature or humid place, it may deteriorate. High temperature can accelerate its chemical reaction, or cause adverse events such as decomposition; humid environment can easily make it hygroscopic and hydrolyzed, damaging its quality. And it needs to be kept away from fire and heat sources. Because of its flammability, it may cause combustion and explosion in case of open flames and hot topics.
Second, as far as transportation is concerned. When handling, be sure to load and unload lightly, and do not operate brutally. (Triethoxy) silane leaks due to violent vibration or collision, or damage to the package. Once leaked, not only the material is damaged, but also the surrounding environment and personnel safety may be endangered. Transportation vehicles should also be equipped with corresponding fire equipment and leakage emergency treatment equipment for emergencies. During transportation, it should be protected from exposure to the sun, rain, and high temperature. During summer transportation, it is advisable to choose a cool time in the morning and evening to reduce the possibility of danger caused by high temperature.
Furthermore, the integrity of the package is crucial whether it is stored or transported. The package must be tightly sealed to prevent the intrusion of air, water vapor, etc. If the package is damaged, it should be replaced or repaired in time to ensure that the (triethoxy) silane is in a good state of preservation. And the storage and transportation places should be clearly marked with warning signs to remind personnel to pay attention to the danger and operate with caution.
First, it is related to storage. This substance should be stored in a cool, dry and well-ventilated place. If placed in a high temperature or humid place, it may deteriorate. High temperature can accelerate its chemical reaction, or cause adverse events such as decomposition; humid environment can easily make it hygroscopic and hydrolyzed, damaging its quality. And it needs to be kept away from fire and heat sources. Because of its flammability, it may cause combustion and explosion in case of open flames and hot topics.
Second, as far as transportation is concerned. When handling, be sure to load and unload lightly, and do not operate brutally. (Triethoxy) silane leaks due to violent vibration or collision, or damage to the package. Once leaked, not only the material is damaged, but also the surrounding environment and personnel safety may be endangered. Transportation vehicles should also be equipped with corresponding fire equipment and leakage emergency treatment equipment for emergencies. During transportation, it should be protected from exposure to the sun, rain, and high temperature. During summer transportation, it is advisable to choose a cool time in the morning and evening to reduce the possibility of danger caused by high temperature.
Furthermore, the integrity of the package is crucial whether it is stored or transported. The package must be tightly sealed to prevent the intrusion of air, water vapor, etc. If the package is damaged, it should be replaced or repaired in time to ensure that the (triethoxy) silane is in a good state of preservation. And the storage and transportation places should be clearly marked with warning signs to remind personnel to pay attention to the danger and operate with caution.
What are the effects of 2- (trifluoromethoxy) chlorobenzene on the environment and human health?
The author of "Tiangong Kaiwu", written by Yingxing in the Ming and Song Dynasties, recorded all kinds of skills and products, and described in detail in chemical industry, metallurgy, agriculture, etc. However, there was no "2 - (triethoxy) silane" at that time. Therefore, according to the ancient saying, the impact of "2 - (triethoxy) silane" on the environment and human health can only be deduced rationally.
The husband "2 - (triethoxy) silane", according to its name, is an organic compound containing silicon. Silicon is common in nature, but this compound is artificially synthesized, and its properties may be abnormal.
In terms of the environment, if this substance is released outside or phase with surrounding objects. In the soil, or interact with minerals, microorganisms, etc. Its ethoxy group or hydrolysis, while raw alcohols, alcohols in the water and soil, or affect the growth of vegetation. In water bodies, if this substance enters, or changes the chemical properties of water, it will affect the survival of aquatic organisms. The pH of water, dissolved oxygen, etc. may change as a result, causing water ecological imbalance.
As for personal health, if people touch it, enter through the skin, or irritate the skin, causing redness, swelling, and itching. If inhaled, its volatile gas may hurt the respiratory tract, cause coughing, asthma, and even damage the lungs, affecting respiratory function. If taken by mistake, it will also damage the gastrointestinal tract, causing abdominal pain, vomiting, etc.
However, this is all based on common sense. What is recorded in "Tiangong Kaiwu" is the knowledge and skills of the time, and it has not been compared to this new product. Today's science should use an empirical method to study the definite impact of "2- (triethoxy) silane" on the environment and the human body, so as to ensure the safety of the ecology and the human body.
The husband "2 - (triethoxy) silane", according to its name, is an organic compound containing silicon. Silicon is common in nature, but this compound is artificially synthesized, and its properties may be abnormal.
In terms of the environment, if this substance is released outside or phase with surrounding objects. In the soil, or interact with minerals, microorganisms, etc. Its ethoxy group or hydrolysis, while raw alcohols, alcohols in the water and soil, or affect the growth of vegetation. In water bodies, if this substance enters, or changes the chemical properties of water, it will affect the survival of aquatic organisms. The pH of water, dissolved oxygen, etc. may change as a result, causing water ecological imbalance.
As for personal health, if people touch it, enter through the skin, or irritate the skin, causing redness, swelling, and itching. If inhaled, its volatile gas may hurt the respiratory tract, cause coughing, asthma, and even damage the lungs, affecting respiratory function. If taken by mistake, it will also damage the gastrointestinal tract, causing abdominal pain, vomiting, etc.
However, this is all based on common sense. What is recorded in "Tiangong Kaiwu" is the knowledge and skills of the time, and it has not been compared to this new product. Today's science should use an empirical method to study the definite impact of "2- (triethoxy) silane" on the environment and the human body, so as to ensure the safety of the ecology and the human body.
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