Linshang Chemical
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2,6-Bis(Trifluoromethyl)Chlorobenzene
Linshang Chemical
|
HS Code |
319325 |
| Chemical Formula | C8H3ClF6 |
| Molar Mass | 258.55 g/mol |
| Appearance | Colorless liquid |
| Boiling Point | 143 - 144 °C |
| Melting Point | N/A |
| Density | 1.53 g/cm³ |
| Vapor Pressure | N/A |
| Water Solubility | Insoluble |
| Flash Point | 46 °C |
| Refractive Index | 1.387 |
As an accredited 2,6-Bis(Trifluoromethyl)Chlorobenzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 250 - gram bottle packaging for 2,6 - bis(trifluoromethyl)chlorobenzene chemical. |
| Storage | 2,6 - bis(trifluoromethyl)chlorobenzene should be stored in a cool, dry, well - ventilated area away from heat sources and open flames. Keep it in a tightly sealed container to prevent vapor leakage. Store it separately from oxidizing agents and incompatible substances to avoid potential chemical reactions. |
| Shipping | 2,6 - bis(trifluoromethyl)chlorobenzene is shipped in sealed, corrosion - resistant containers. It's transported under strict safety protocols, avoiding exposure to heat, ignition sources, and incompatible substances to ensure safe delivery. |
Competitive 2,6-Bis(Trifluoromethyl)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
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As a leading 2,6-Bis(Trifluoromethyl)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 2,6-bis (trifluoromethyl) chlorobenzene?
2% 2C6-bis (triethylamino) naphthalene, which is an important chemical raw material in the field of organic synthesis. Its main uses cover the following ends:
First, it shines brightly in the synthesis of fluorescent materials. Due to its unique electronic structure and optical properties, it can endow fluorescent materials with excellent fluorescence properties, such as high fluorescence quantum yield and good stability. With this, the prepared fluorescent materials can be widely used in many fields. In the field of biological imaging, by labeling biomolecules, accurate detection and imaging of specific substances in living organisms can be achieved, enabling researchers to deeply explore physiological and pathological processes in living organisms; in the field of Light Emitting Diode (LED) manufacturing, as a phosphor material, it can effectively improve the luminous efficiency and color purity of LEDs, contributing to the development of lighting and display technology.
Second, in the field of organic electroluminescent devices (OLEDs), it also occupies a key position. In OLEDs, it can act as a light-emitting layer material or a transport layer material. When used as a light-emitting layer material, it can directly generate high-efficiency electroluminescence phenomena, providing protection for the colorful image of the OLED screen; as a transport layer material, it can accelerate the transmission of electrons or holes, thereby improving the overall performance of the device, such as improving the luminous efficiency, prolonging the service life, etc., which is of great significance for promoting the wide application of OLED technology in the display field.
Third, it plays a significant role in the development of chemical sensors. In view of its sensitive response to specific substances, it can be designed as a chemical sensor for detecting specific molecules or ions in the environment. For example, the detection of certain heavy metal ions can achieve high sensitivity and high selectivity, providing strong technical support for environmental monitoring and food safety testing, and helping to detect potential harmful substances in the environment and food in a timely manner, ensuring human living environment and health safety.
First, it shines brightly in the synthesis of fluorescent materials. Due to its unique electronic structure and optical properties, it can endow fluorescent materials with excellent fluorescence properties, such as high fluorescence quantum yield and good stability. With this, the prepared fluorescent materials can be widely used in many fields. In the field of biological imaging, by labeling biomolecules, accurate detection and imaging of specific substances in living organisms can be achieved, enabling researchers to deeply explore physiological and pathological processes in living organisms; in the field of Light Emitting Diode (LED) manufacturing, as a phosphor material, it can effectively improve the luminous efficiency and color purity of LEDs, contributing to the development of lighting and display technology.
Second, in the field of organic electroluminescent devices (OLEDs), it also occupies a key position. In OLEDs, it can act as a light-emitting layer material or a transport layer material. When used as a light-emitting layer material, it can directly generate high-efficiency electroluminescence phenomena, providing protection for the colorful image of the OLED screen; as a transport layer material, it can accelerate the transmission of electrons or holes, thereby improving the overall performance of the device, such as improving the luminous efficiency, prolonging the service life, etc., which is of great significance for promoting the wide application of OLED technology in the display field.
Third, it plays a significant role in the development of chemical sensors. In view of its sensitive response to specific substances, it can be designed as a chemical sensor for detecting specific molecules or ions in the environment. For example, the detection of certain heavy metal ions can achieve high sensitivity and high selectivity, providing strong technical support for environmental monitoring and food safety testing, and helping to detect potential harmful substances in the environment and food in a timely manner, ensuring human living environment and health safety.
What are the physical properties of 2,6-bis (trifluoromethyl) chlorobenzene?
2% 2C6 -Bis (triethoxysilyl) hexane, this is an organosilicon compound. Its physical properties are quite unique, let me tell them one by one.
Looking at its shape, under room temperature and pressure, it is mostly colorless and transparent liquid, like clear water, free of impurities and different colors, and clean visually. This shape makes it easy to pour, transfer and mix in many industrial operations, providing convenience for practical applications.
When it comes to odor, it emits a weak and special organic smell, is not pungent and strong, and is less irritating to the surrounding environment and the user's olfactory sense. This feature makes it unnecessary for operators to tolerate strong and unpleasant odors during production and use, ensuring a relatively comfortable working environment.
Besides, its boiling point is about a specific temperature range, which varies slightly due to the specific molecular structure and purity. A higher boiling point means that under normal temperature conditions, it has good thermal stability, is not easy to vaporize and evaporate easily, and can maintain a liquid state for a long time, laying the foundation for use in high temperature environments. For example, in some processes that require heat treatment, it can exist stably, participate in reactions or play specific functions.
As for the melting point, it is also in a specific low temperature range. The lower melting point allows the liquid to remain liquid when the temperature drops slightly, so that it will not solidify rapidly and affect the use. Like storage and transportation in cold climate conditions, it will not solidify and block pipelines or containers due to temperature reduction, ensuring smooth logistics and use.
In terms of density, it is relatively stable and has a certain value, so that when mixed with other liquids, it can be layered or uniformly dispersed according to the density difference. When preparing composite materials or performing chemical synthesis, the reaction process and mixing method can be reasonably designed according to this characteristic.
In terms of solubility, it can be dissolved in some organic solvents, such as common alcohols, ethers, etc. This solubility provides a broad application space for it in the fields of organic synthesis, coating preparation, etc. It can be miscible with a variety of organic components, and then build a system with excellent performance. The physical properties of 2% 2C6 -bis (triethoxysilyl) hexane pave the way for its application in many fields such as chemical industry and materials.
Looking at its shape, under room temperature and pressure, it is mostly colorless and transparent liquid, like clear water, free of impurities and different colors, and clean visually. This shape makes it easy to pour, transfer and mix in many industrial operations, providing convenience for practical applications.
When it comes to odor, it emits a weak and special organic smell, is not pungent and strong, and is less irritating to the surrounding environment and the user's olfactory sense. This feature makes it unnecessary for operators to tolerate strong and unpleasant odors during production and use, ensuring a relatively comfortable working environment.
Besides, its boiling point is about a specific temperature range, which varies slightly due to the specific molecular structure and purity. A higher boiling point means that under normal temperature conditions, it has good thermal stability, is not easy to vaporize and evaporate easily, and can maintain a liquid state for a long time, laying the foundation for use in high temperature environments. For example, in some processes that require heat treatment, it can exist stably, participate in reactions or play specific functions.
As for the melting point, it is also in a specific low temperature range. The lower melting point allows the liquid to remain liquid when the temperature drops slightly, so that it will not solidify rapidly and affect the use. Like storage and transportation in cold climate conditions, it will not solidify and block pipelines or containers due to temperature reduction, ensuring smooth logistics and use.
In terms of density, it is relatively stable and has a certain value, so that when mixed with other liquids, it can be layered or uniformly dispersed according to the density difference. When preparing composite materials or performing chemical synthesis, the reaction process and mixing method can be reasonably designed according to this characteristic.
In terms of solubility, it can be dissolved in some organic solvents, such as common alcohols, ethers, etc. This solubility provides a broad application space for it in the fields of organic synthesis, coating preparation, etc. It can be miscible with a variety of organic components, and then build a system with excellent performance. The physical properties of 2% 2C6 -bis (triethoxysilyl) hexane pave the way for its application in many fields such as chemical industry and materials.
What are the synthesis methods of 2,6-bis (trifluoromethyl) chlorobenzene?
The synthesis method of 2% 2C6-bis (triethylamino) anthracene can be obtained by the following steps.
First, anthracene is taken as the starting material. Anthracene has a unique fused cyclic aromatic structure and its chemical properties are relatively stable. However, under specific conditions, it can be functionalized. With an appropriate halogenating agent, such as bromine, in the presence of a catalyst, the 2-position and 6-position of anthracene are halogenated. This reaction needs to be carried out at low temperature and in an inert gas protective atmosphere to prevent side reactions from occurring. After the reaction is completed, 2,6-dihalogenated anthracene intermediates can be obtained.
Then, triethylamine is taken. Triethylamine is an organic base and has nucleophilic properties. Mix it with 2,6-dihalogenated anthracene intermediates in suitable organic solvents such as N, N-dimethylformamide (DMF). Under heating and stirring conditions, the nitrogen atom of triethylamine will attack the carbon atom attached to the halogen atom of dihalogenated anthracene, and a nucleophilic substitution reaction occurs. During this process, the alkyl moiety of triethylamine is introduced to the 2-position and 6-position of anthracene, and then 2% 2C6-bis (triethylamino) anthracene products are formed. After the
reaction is completed, the products can be separated and purified by column chromatography or recrystallization. In column chromatography, an appropriate silica gel is selected as the stationary phase, and an appropriate proportion of organic solvent mixture is used as the mobile phase. According to the difference in the partition coefficient between the product and the impurity in the stationary phase and the mobile phase, the separation of the product and the impurity is achieved. The recrystallization rule is to use the different solubility of the product and the impurity in a specific solvent with temperature to crystallize and precipitate the product from the reaction mixture to achieve the purpose of purification.
First, anthracene is taken as the starting material. Anthracene has a unique fused cyclic aromatic structure and its chemical properties are relatively stable. However, under specific conditions, it can be functionalized. With an appropriate halogenating agent, such as bromine, in the presence of a catalyst, the 2-position and 6-position of anthracene are halogenated. This reaction needs to be carried out at low temperature and in an inert gas protective atmosphere to prevent side reactions from occurring. After the reaction is completed, 2,6-dihalogenated anthracene intermediates can be obtained.
Then, triethylamine is taken. Triethylamine is an organic base and has nucleophilic properties. Mix it with 2,6-dihalogenated anthracene intermediates in suitable organic solvents such as N, N-dimethylformamide (DMF). Under heating and stirring conditions, the nitrogen atom of triethylamine will attack the carbon atom attached to the halogen atom of dihalogenated anthracene, and a nucleophilic substitution reaction occurs. During this process, the alkyl moiety of triethylamine is introduced to the 2-position and 6-position of anthracene, and then 2% 2C6-bis (triethylamino) anthracene products are formed. After the
reaction is completed, the products can be separated and purified by column chromatography or recrystallization. In column chromatography, an appropriate silica gel is selected as the stationary phase, and an appropriate proportion of organic solvent mixture is used as the mobile phase. According to the difference in the partition coefficient between the product and the impurity in the stationary phase and the mobile phase, the separation of the product and the impurity is achieved. The recrystallization rule is to use the different solubility of the product and the impurity in a specific solvent with temperature to crystallize and precipitate the product from the reaction mixture to achieve the purpose of purification.
What are the precautions for storing and transporting 2,6-bis (trifluoromethyl) chlorobenzene?
2% 2C6 -bis (triethylamino) hexane must pay attention to many key matters during storage and transportation.
First, the storage place must be cool, dry and well ventilated. This is because the substance is quite sensitive to temperature and humidity, and high temperature and humidity can easily cause its properties to change, or even cause chemical reactions. If stored in a humid place, moisture may interact with the substance and destroy its chemical structure; high temperature environment may also promote its volatilization, which not only wastes raw materials, but also increases safety hazards.
Second, keep away from fires and heat sources. The substance is flammable, and it is easy to burn and even explode in case of open flames and hot topics. Imagine that in the warehouse, if an unextinguished cigarette butt accidentally falls and comes into contact with this substance, it may ignite a raging fire in an instant, endangering the safety of the surrounding area.
Third, it should be stored separately from oxidants and acids, and should not be mixed. Because of its active chemical nature, it encounters with oxidants or triggers a violent oxidation reaction; contact with acids may also cause chemical reactions, resulting in harmful or unstable products. If it is placed in the same place as a strong oxidant, a slight carelessness may cause danger.
Fourth, when transporting, make sure that the container does not leak, collapse, fall, or damage. Transportation vehicles need to be equipped with the corresponding variety and quantity of fire equipment and leakage emergency treatment equipment. If the container leaks during transportation, the substance evaporates or flows into the environment, which not only pollutes the environment, but also easily causes safety accidents. If the vehicle is driving on the road, once the leakage occurs, it will not only affect the traffic, but also may cause serious harm to the surrounding people and the environment.
Fifth, the transportation process should be driven according to the specified route, and do not stop in residential areas and densely populated areas. This is to avoid accidents during transportation that cause loss of life and property to many people. If an accident occurs in a densely populated area and harmful substances leak, a large number of people will be affected, and the consequences will be unimaginable.
First, the storage place must be cool, dry and well ventilated. This is because the substance is quite sensitive to temperature and humidity, and high temperature and humidity can easily cause its properties to change, or even cause chemical reactions. If stored in a humid place, moisture may interact with the substance and destroy its chemical structure; high temperature environment may also promote its volatilization, which not only wastes raw materials, but also increases safety hazards.
Second, keep away from fires and heat sources. The substance is flammable, and it is easy to burn and even explode in case of open flames and hot topics. Imagine that in the warehouse, if an unextinguished cigarette butt accidentally falls and comes into contact with this substance, it may ignite a raging fire in an instant, endangering the safety of the surrounding area.
Third, it should be stored separately from oxidants and acids, and should not be mixed. Because of its active chemical nature, it encounters with oxidants or triggers a violent oxidation reaction; contact with acids may also cause chemical reactions, resulting in harmful or unstable products. If it is placed in the same place as a strong oxidant, a slight carelessness may cause danger.
Fourth, when transporting, make sure that the container does not leak, collapse, fall, or damage. Transportation vehicles need to be equipped with the corresponding variety and quantity of fire equipment and leakage emergency treatment equipment. If the container leaks during transportation, the substance evaporates or flows into the environment, which not only pollutes the environment, but also easily causes safety accidents. If the vehicle is driving on the road, once the leakage occurs, it will not only affect the traffic, but also may cause serious harm to the surrounding people and the environment.
Fifth, the transportation process should be driven according to the specified route, and do not stop in residential areas and densely populated areas. This is to avoid accidents during transportation that cause loss of life and property to many people. If an accident occurs in a densely populated area and harmful substances leak, a large number of people will be affected, and the consequences will be unimaginable.
What are the effects of 2,6-bis (trifluoromethyl) chlorobenzene on the environment and human health?
2% 2C6-di (triethylamino) fluorone, which has a complex impact on the environment and human health.
At the environmental end, it may pose several hazards. If it flows into water bodies, it is difficult to degrade due to special structures, or cause water pollution to persist. And its residue in water may interfere with aquatic ecology, affect the growth, reproduction, and even change the community structure of aquatic organisms. For soil, it accumulates or changes soil physicochemical properties, hinders the uptake and growth of plant roots on nutrients, and affects the balance of terrestrial ecosystems.
It is related to human health, and its latent risk should not be underestimated. If it enters the human body through respiration, skin contact or accidental ingestion, it may pose a hidden danger. Contact with the skin, or cause allergic reactions, making the skin itchy, red and swollen. Inhalation through the respiratory tract, or irritation of respiratory mucosa, causing cough, asthma and other diseases. Long-term exposure and intake exceeding a certain threshold, because of its complex chemical structure, or interfere with the normal physiological metabolism of the human body, affect the endocrine system, or even have a potential risk of carcinogenesis. Cover because of some chemical groups or the interaction with biological macromolecules in human cells, resulting in abnormal cell proliferation, differentiation, and disease.
Therefore, the production, use and emission of 2% 2C6-bis (triethylamino) fluorone should be treated with caution, and control and monitoring should be strengthened to protect the environment and human health.
At the environmental end, it may pose several hazards. If it flows into water bodies, it is difficult to degrade due to special structures, or cause water pollution to persist. And its residue in water may interfere with aquatic ecology, affect the growth, reproduction, and even change the community structure of aquatic organisms. For soil, it accumulates or changes soil physicochemical properties, hinders the uptake and growth of plant roots on nutrients, and affects the balance of terrestrial ecosystems.
It is related to human health, and its latent risk should not be underestimated. If it enters the human body through respiration, skin contact or accidental ingestion, it may pose a hidden danger. Contact with the skin, or cause allergic reactions, making the skin itchy, red and swollen. Inhalation through the respiratory tract, or irritation of respiratory mucosa, causing cough, asthma and other diseases. Long-term exposure and intake exceeding a certain threshold, because of its complex chemical structure, or interfere with the normal physiological metabolism of the human body, affect the endocrine system, or even have a potential risk of carcinogenesis. Cover because of some chemical groups or the interaction with biological macromolecules in human cells, resulting in abnormal cell proliferation, differentiation, and disease.
Therefore, the production, use and emission of 2% 2C6-bis (triethylamino) fluorone should be treated with caution, and control and monitoring should be strengthened to protect the environment and human health.
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