Linshang Chemical
PRODUCTS
1-Chloro-3-(Trifluoromethoxy)Benzene
Linshang Chemical
|
HS Code |
356980 |
| Chemical Formula | C7H4ClF3O |
| Molar Mass | 196.55 g/mol |
| Appearance | Colorless to light yellow liquid |
| Boiling Point | 142 - 144 °C |
| Density | 1.35 - 1.37 g/cm³ |
| Solubility In Water | Insoluble |
| Solubility In Organic Solvents | Soluble in common organic solvents like ethanol, ether |
| Flash Point | 36 °C |
| Refractive Index | 1.429 - 1.431 |
As an accredited 1-Chloro-3-(Trifluoromethoxy)Benzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 1 - chloro - 3 - (trifluoromethoxy) benzene, 500g in sealed, chemical - resistant bottle. |
| Storage | 1 - Chloro - 3 - (trifluoromethoxy)benzene should be stored in a cool, well - ventilated area, away from heat sources and open flames. It should be kept in a tightly - sealed container to prevent vapor leakage. Store it separately from oxidizing agents, acids, and bases to avoid potential reactions. Ensure storage areas comply with safety regulations. |
| Shipping | 1 - chloro - 3 - (trifluoromethoxy)benzene is shipped in specialized, tightly - sealed containers. These are designed to prevent leakage, with proper labeling for hazard awareness, and transported following strict chemical shipping regulations. |
Competitive 1-Chloro-3-(Trifluoromethoxy)Benzene 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 1-Chloro-3-(Trifluoromethoxy)Benzene in China?
As a trusted 1-Chloro-3-(Trifluoromethoxy)Benzene 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 1-Chloro-3-(Trifluoromethoxy)Benzene 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-chloro-3- (trifluoromethoxy) benzene?
The main use of 1 + -deuterium-3- (triethoxy) boron is in many chemical synthesis reactions. In the field of organic synthesis, it is often used as a reducing agent, because it can reduce specific carbonyl compounds, such as aldodes and ketones, to corresponding alcohols. Due to its special chemical properties, this process can provide hydrogen atoms to the target molecule to cause a reduction reaction, and has a high selectivity. Under specific conditions, it can precisely act on specific functional groups without affecting other parts of the molecule.
Furthermore, in the field of materials science, it also has important uses. Or can participate in the preparation of specific functional materials, through its reaction with other compounds, impart special properties to the material, such as changing the electrical and optical properties of the material. When preparing semiconductor materials or optically active materials, 1 + -deuterium-3- (triethoxy) boron can be used as a key raw material or auxiliary agent to help build the required molecular structure, and then regulate the properties of the material.
In addition, this compound also plays an important role in some chemical synthesis steps related to pharmaceutical research and development. It can be used to synthesize compounds with specific biological activities, providing the necessary chemical transformation means for the construction of drug molecules. Through fine regulation of the reaction conditions and the reduction properties of 1 + -deuterium-3- (triethoxy) boron, specific structural compounds that meet the needs of medicine can be synthesized, laying the foundation for the development of new drugs.
Furthermore, in the field of materials science, it also has important uses. Or can participate in the preparation of specific functional materials, through its reaction with other compounds, impart special properties to the material, such as changing the electrical and optical properties of the material. When preparing semiconductor materials or optically active materials, 1 + -deuterium-3- (triethoxy) boron can be used as a key raw material or auxiliary agent to help build the required molecular structure, and then regulate the properties of the material.
In addition, this compound also plays an important role in some chemical synthesis steps related to pharmaceutical research and development. It can be used to synthesize compounds with specific biological activities, providing the necessary chemical transformation means for the construction of drug molecules. Through fine regulation of the reaction conditions and the reduction properties of 1 + -deuterium-3- (triethoxy) boron, specific structural compounds that meet the needs of medicine can be synthesized, laying the foundation for the development of new drugs.
What are the physical properties of 1-chloro-3- (trifluoromethoxy) benzene?
Triethoxysilane, also known as 1-chloro-3- (triethoxysilyl) benzene, has the following physical properties:
This substance is a colorless and transparent liquid at room temperature, and it has a special odor. Its density is about 0.99 g/cm ³, which is moderate compared with common organic solvents. The boiling point is between 160 - 165 ° C. This boiling point allows it to undergo gas-liquid transformation under proper heating conditions. The melting point is relatively low, about -70 ° C, which indicates that it can still maintain a liquid state under general low temperature environments.
Triethoxysilane can be miscible with some organic solvents, such as ethanol, ether, etc., and exhibits good solubility. This property helps it participate in the reaction as a reactant or solvent in various organic reaction systems. It is slightly soluble in water and has a small solubility in water. This is due to the large proportion of organic groups in its molecular structure, resulting in weak affinity with water.
In addition, triethoxysilane has a certain volatility. In an open environment, it will gradually evaporate into the air. Due to its special chemical structure, the presence of silicon-oxygen bonds and ethoxy groups allows it to undergo specific chemical reactions when it comes into contact with other substances, which also indirectly affects its physical performance during storage and use. When storing, it needs to be sealed to prevent it from volatilizing and reacting with substances such as moisture in the air, thereby affecting its physical and chemical properties.
This substance is a colorless and transparent liquid at room temperature, and it has a special odor. Its density is about 0.99 g/cm ³, which is moderate compared with common organic solvents. The boiling point is between 160 - 165 ° C. This boiling point allows it to undergo gas-liquid transformation under proper heating conditions. The melting point is relatively low, about -70 ° C, which indicates that it can still maintain a liquid state under general low temperature environments.
Triethoxysilane can be miscible with some organic solvents, such as ethanol, ether, etc., and exhibits good solubility. This property helps it participate in the reaction as a reactant or solvent in various organic reaction systems. It is slightly soluble in water and has a small solubility in water. This is due to the large proportion of organic groups in its molecular structure, resulting in weak affinity with water.
In addition, triethoxysilane has a certain volatility. In an open environment, it will gradually evaporate into the air. Due to its special chemical structure, the presence of silicon-oxygen bonds and ethoxy groups allows it to undergo specific chemical reactions when it comes into contact with other substances, which also indirectly affects its physical performance during storage and use. When storing, it needs to be sealed to prevent it from volatilizing and reacting with substances such as moisture in the air, thereby affecting its physical and chemical properties.
Is 1-chloro-3- (trifluoromethoxy) benzene chemically stable?
Alas, in order to know whether the chemical properties of 1 + -alkane-3- (triethoxy) silicon are stable, it is necessary to study its structure and characteristics in detail. Silicon atoms have a unique electron arrangement, and their outer layers have four electrons, which can form four covalent bonds. In 1 + -alkane-3- (triethoxy) silicon, silicon is connected to triethoxy and alkyl groups.
Oxygen in ethoxy groups has strong electronegativity, which attracts silicon electron clouds, making the density of silicon electron clouds uneven. However, this structure also gives it specific stability. The silicon-oxygen bond energy is quite high. The structure formed by the connection of triethoxy groups to silicon has a certain conjugation effect due to the interaction of oxygen electron pairs with silicon empty orbitals, which can disperse electrons and improve molecular stability.
Furthermore, the presence of alkyl groups partially cancels the attraction of ethoxy groups to silicon electron clouds due to the induction effect of alkyl power supply, and also contributes to the overall stability. Under common conditions, if there is no strengthening effect, such as strong acid, strong base or high temperature, highly active reagents, 1 + -alkane-3- (triethoxy) silicon has relatively stable chemical properties.
However, in certain environments, such as strong acid, ethoxy may hydrolyze, because acid can provide protons and ethoxy oxygen to interact, weakening the silicon-oxygen bond and causing hydrolysis. Under strong alkali conditions, similar reactions may also be triggered. Hydroxide ions in bases have strong nucleophilic properties and can attack silicon atoms and destroy their structures.
In summary, at room temperature and pressure, without the action of special reagents, the chemical properties of 1 + -alkane-3- (triethoxy) silicon are still stable; however, in an extreme chemical environment, its structure may change, and its chemical properties may also change.
Oxygen in ethoxy groups has strong electronegativity, which attracts silicon electron clouds, making the density of silicon electron clouds uneven. However, this structure also gives it specific stability. The silicon-oxygen bond energy is quite high. The structure formed by the connection of triethoxy groups to silicon has a certain conjugation effect due to the interaction of oxygen electron pairs with silicon empty orbitals, which can disperse electrons and improve molecular stability.
Furthermore, the presence of alkyl groups partially cancels the attraction of ethoxy groups to silicon electron clouds due to the induction effect of alkyl power supply, and also contributes to the overall stability. Under common conditions, if there is no strengthening effect, such as strong acid, strong base or high temperature, highly active reagents, 1 + -alkane-3- (triethoxy) silicon has relatively stable chemical properties.
However, in certain environments, such as strong acid, ethoxy may hydrolyze, because acid can provide protons and ethoxy oxygen to interact, weakening the silicon-oxygen bond and causing hydrolysis. Under strong alkali conditions, similar reactions may also be triggered. Hydroxide ions in bases have strong nucleophilic properties and can attack silicon atoms and destroy their structures.
In summary, at room temperature and pressure, without the action of special reagents, the chemical properties of 1 + -alkane-3- (triethoxy) silicon are still stable; however, in an extreme chemical environment, its structure may change, and its chemical properties may also change.
What are the methods for preparing 1-chloro-3- (trifluoromethoxy) benzene?
There are many ways to make calamine in ancient times, and this is what you describe today.
First, take calamine and calcine it with charcoal fire until it turns red. Then put it in vinegar and quench it, and repeat this seven times. When calcining, you need to use martial fire to make it transparent inside and outside; when quenching vinegar, you need to quickly make the texture of calamine brittle. In this process, the amount of vinegar is also exquisite. If there is too much calamine, it is easy to be too soft, and if there is too little, it will not be quenched. After repeated calcining and quenching, the medicinal properties of calamine can be changed, the texture is loose, and it is easier to grind into powder.
Second, first wash the calamine, put it in a jar, add sodium triethoxy borohydride and other agents (ancient methods or other compatible substances, this is based on current chemical principles to speculate that its similar auxiliary substances), and seal the mouth of the jar. Then simmer slowly, you need to be patient, and the heat cannot be rushed. After simmering slowly for a few hours, wait for it to cool, and take out the calamine. At this time, the medicinal properties of calamine are very different from the original, and its effect may be more significant.
Third, soak the calamine with childlike feces. Choose clean childlike feces and immerse the calamine in them. The soaking time should be appropriate. If it is short, the effect will not be complete, and if it is long, it may change. After the soaking is completed, take out the calamine and dry it in the shade. Then bake it with tiles. When baking, the heat is moderate and it should not be scorched. After this step, calamine removes some impurities and has more pure medicinal properties.
All kinds of production methods have their own reasons, all of which are to make the texture and medicinal properties of calamine the best, so as to be suitable for different medicinal needs.
First, take calamine and calcine it with charcoal fire until it turns red. Then put it in vinegar and quench it, and repeat this seven times. When calcining, you need to use martial fire to make it transparent inside and outside; when quenching vinegar, you need to quickly make the texture of calamine brittle. In this process, the amount of vinegar is also exquisite. If there is too much calamine, it is easy to be too soft, and if there is too little, it will not be quenched. After repeated calcining and quenching, the medicinal properties of calamine can be changed, the texture is loose, and it is easier to grind into powder.
Second, first wash the calamine, put it in a jar, add sodium triethoxy borohydride and other agents (ancient methods or other compatible substances, this is based on current chemical principles to speculate that its similar auxiliary substances), and seal the mouth of the jar. Then simmer slowly, you need to be patient, and the heat cannot be rushed. After simmering slowly for a few hours, wait for it to cool, and take out the calamine. At this time, the medicinal properties of calamine are very different from the original, and its effect may be more significant.
Third, soak the calamine with childlike feces. Choose clean childlike feces and immerse the calamine in them. The soaking time should be appropriate. If it is short, the effect will not be complete, and if it is long, it may change. After the soaking is completed, take out the calamine and dry it in the shade. Then bake it with tiles. When baking, the heat is moderate and it should not be scorched. After this step, calamine removes some impurities and has more pure medicinal properties.
All kinds of production methods have their own reasons, all of which are to make the texture and medicinal properties of calamine the best, so as to be suitable for different medicinal needs.
What are the precautions for storing and transporting 1-chloro-3- (trifluoromethoxy) benzene?
When storing and transporting trichloro (triethoxy) silicon, there are several ends that should be paid attention to.
First word storage. This substance should be placed in a cool, dry and well-ventilated place. Because of its active nature, if it is in a high temperature and humid environment, it is prone to deterioration. Under high temperature, it may cause its volatilization to intensify, and there is a risk of triggering chemical reactions; humid environment can make it interact with water vapor, resulting in damage to quality. In addition, the storage place should be far away from fire and heat sources, and it may be flammable. In case of open flames and hot topics, it is easy to cause combustion or even explosion. At the same time, it needs to be stored separately from oxidants, acids, bases, etc. to prevent mutual reaction.
As for transportation, it should not be neglected. Before transportation, it is necessary to ensure that the packaging is complete and sealed to prevent leakage. During transportation, the vehicle should be equipped with the corresponding variety and quantity of fire equipment and leakage emergency treatment equipment. When driving, keep away from fire and heat sources, and the speed of the vehicle should not be too fast. Do not forcibly overtake the car to avoid leakage due to package damage caused by bumps and collisions. If transported by rail, do not slip away for safety.
Escort personnel also need to be familiar with the nature of the transported items, hazard characteristics and emergency response measures. Once there is an accident such as leakage on the way, it can be dealt with quickly and properly to minimize the harm. Overall, during the storage and transportation of trichloro (triethoxy) silicon, care should be taken and relevant procedures should be followed to ensure the safety of personnel, the environment, and items.
First word storage. This substance should be placed in a cool, dry and well-ventilated place. Because of its active nature, if it is in a high temperature and humid environment, it is prone to deterioration. Under high temperature, it may cause its volatilization to intensify, and there is a risk of triggering chemical reactions; humid environment can make it interact with water vapor, resulting in damage to quality. In addition, the storage place should be far away from fire and heat sources, and it may be flammable. In case of open flames and hot topics, it is easy to cause combustion or even explosion. At the same time, it needs to be stored separately from oxidants, acids, bases, etc. to prevent mutual reaction.
As for transportation, it should not be neglected. Before transportation, it is necessary to ensure that the packaging is complete and sealed to prevent leakage. During transportation, the vehicle should be equipped with the corresponding variety and quantity of fire equipment and leakage emergency treatment equipment. When driving, keep away from fire and heat sources, and the speed of the vehicle should not be too fast. Do not forcibly overtake the car to avoid leakage due to package damage caused by bumps and collisions. If transported by rail, do not slip away for safety.
Escort personnel also need to be familiar with the nature of the transported items, hazard characteristics and emergency response measures. Once there is an accident such as leakage on the way, it can be dealt with quickly and properly to minimize the harm. Overall, during the storage and transportation of trichloro (triethoxy) silicon, care should be taken and relevant procedures should be followed to ensure the safety of personnel, the environment, and items.
Scan to WhatsApp
