Linshang Chemical
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2,4-Dichloro-1,3,5-Trifluorobenzene
Linshang Chemical
|
HS Code |
150454 |
| Chemical Formula | C6HCl2F3 |
| Molecular Weight | 198.97 |
| Appearance | Colorless to light yellow liquid |
| Boiling Point | 127 - 129 °C |
| Density | 1.53 g/cm³ (approximate) |
| Solubility In Water | Insoluble |
| Solubility In Organic Solvents | Soluble in common organic solvents like ethanol, ether |
As an accredited 2,4-Dichloro-1,3,5-Trifluorobenzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 500 - gram bottle packaging for 2,4 - dichloro - 1,3,5 - trifluorobenzene chemical. |
| Storage | 2,4 - Dichloro - 1,3,5 - trifluorobenzene 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. Store it separately from oxidizing agents, reducing agents, and incompatible substances to avoid chemical reactions. Follow proper safety regulations for hazardous chemicals during storage. |
| Shipping | 2,4 - dichloro - 1,3,5 - trifluorobenzene is shipped in tightly sealed, corrosion - resistant containers. Shipment follows strict hazardous chemical regulations, ensuring proper handling, storage, and transportation to prevent leaks and risks. |
Competitive 2,4-Dichloro-1,3,5-Trifluorobenzene 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 2,4-Dichloro-1,3,5-Trifluorobenzene in China?
As a trusted 2,4-Dichloro-1,3,5-Trifluorobenzene 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 2,4-Dichloro-1,3,5-Trifluorobenzene 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 2,4-dichloro-1,3,5-trifluorobenzene?
2% 2C4-dioxy-1% 2C3% 2C5-triazinobenzene is an important organic compound. It has a wide range of main uses and is of key value in many fields.
In the field of chemical synthesis, it is often used as a key intermediate. Through a series of chemical reactions, many compounds with special properties can be derived. For example, when preparing some high-performance polymers, it can be used as a key structural unit to build the polymer skeleton, endowing the polymer with properties such as excellent thermal stability and chemical stability, making it useful in high-end fields such as aerospace and electronics.
also plays an important role in materials science. By compounding with other materials, the properties of materials can be significantly improved. For example, introducing it into polymer materials can improve the flame retardancy of the material, making the material less likely to burn when exposed to fire sources, thus providing effective protection for fire safety. At the same time, it can also enhance the mechanical properties of the material, such as improving the strength and toughness of the material, and broadening the application range of the material.
In the field of medicine, it also shows potential uses. Due to its special chemical structure, it may have a certain biological activity, which may be used to develop new drugs. Scientists can design and optimize drug molecules according to their structural characteristics, hoping to develop highly effective therapeutic drugs for specific diseases.
In summary, 2% 2C4-dioxy-1% 2C3% 2C5-triazinobenzene has broad application prospects in many fields such as chemical industry, materials, and medicine due to its diverse chemical properties and unique structure, and plays an important role in promoting technological development and innovation in various fields.
In the field of chemical synthesis, it is often used as a key intermediate. Through a series of chemical reactions, many compounds with special properties can be derived. For example, when preparing some high-performance polymers, it can be used as a key structural unit to build the polymer skeleton, endowing the polymer with properties such as excellent thermal stability and chemical stability, making it useful in high-end fields such as aerospace and electronics.
also plays an important role in materials science. By compounding with other materials, the properties of materials can be significantly improved. For example, introducing it into polymer materials can improve the flame retardancy of the material, making the material less likely to burn when exposed to fire sources, thus providing effective protection for fire safety. At the same time, it can also enhance the mechanical properties of the material, such as improving the strength and toughness of the material, and broadening the application range of the material.
In the field of medicine, it also shows potential uses. Due to its special chemical structure, it may have a certain biological activity, which may be used to develop new drugs. Scientists can design and optimize drug molecules according to their structural characteristics, hoping to develop highly effective therapeutic drugs for specific diseases.
In summary, 2% 2C4-dioxy-1% 2C3% 2C5-triazinobenzene has broad application prospects in many fields such as chemical industry, materials, and medicine due to its diverse chemical properties and unique structure, and plays an important role in promoting technological development and innovation in various fields.
What are the physical properties of 2,4-dichloro-1,3,5-trifluorobenzene?
2% 2C4-dihydro-1% 2C3% 2C5-triazine benzene is an organic compound, which has unique physical properties.
Looking at its physical state, under room temperature and pressure, 2% 2C4-dihydro-1% 2C3% 2C5-triazine benzene is mostly solid, with a solid texture, like a rock. Its color is often white, just like the first snow in winter, pure and white, without noise.
When it comes to melting and boiling points, due to the unique intermolecular force, its melting point is quite high, and it requires a considerable amount of heat to make it from solid to liquid, just like iron needs to be tempered and roasted before it can be molten. The boiling point is also not low, indicating that the substance requires more energy to convert to a gaseous state in the liquid state.
In terms of solubility, 2% 2C4-dihydro-1% 2C3% 2C5-triazinobenzene can show a certain solubility in common organic solvents such as ethanol and ether, as if it is integrated into it, quietly concealing its body. However, in water, its solubility is poor, and it seems to be incompatible with water, and it goes its own way.
Above the density, 2% 2C4-dihydro-1% 2C3% 2C5-triazinobenzene has a slightly higher density than water. If it is placed in water, it will sink into the sea like a stone and slowly sink.
Furthermore, 2% 2C4-dihydro-1% 2C3% 2C5-triazinbenzene has certain stability. Under normal conditions, it is not easy to react with many substances, just like a stable person, and is not easily moved by the outside world. However, under specific conditions, such as high temperature, strong acid and alkali environment, its molecular structure may be affected, which in turn triggers chemical reactions and exhibits different chemical activities.
In short, 2% 2C4-dihydro-1% 2C3% 2C5-triazinbenzene has unique physical properties, laying the foundation for its application in chemical industry, materials and other fields, just like a cornerstone, with many carrying possibilities.
Looking at its physical state, under room temperature and pressure, 2% 2C4-dihydro-1% 2C3% 2C5-triazine benzene is mostly solid, with a solid texture, like a rock. Its color is often white, just like the first snow in winter, pure and white, without noise.
When it comes to melting and boiling points, due to the unique intermolecular force, its melting point is quite high, and it requires a considerable amount of heat to make it from solid to liquid, just like iron needs to be tempered and roasted before it can be molten. The boiling point is also not low, indicating that the substance requires more energy to convert to a gaseous state in the liquid state.
In terms of solubility, 2% 2C4-dihydro-1% 2C3% 2C5-triazinobenzene can show a certain solubility in common organic solvents such as ethanol and ether, as if it is integrated into it, quietly concealing its body. However, in water, its solubility is poor, and it seems to be incompatible with water, and it goes its own way.
Above the density, 2% 2C4-dihydro-1% 2C3% 2C5-triazinobenzene has a slightly higher density than water. If it is placed in water, it will sink into the sea like a stone and slowly sink.
Furthermore, 2% 2C4-dihydro-1% 2C3% 2C5-triazinbenzene has certain stability. Under normal conditions, it is not easy to react with many substances, just like a stable person, and is not easily moved by the outside world. However, under specific conditions, such as high temperature, strong acid and alkali environment, its molecular structure may be affected, which in turn triggers chemical reactions and exhibits different chemical activities.
In short, 2% 2C4-dihydro-1% 2C3% 2C5-triazinbenzene has unique physical properties, laying the foundation for its application in chemical industry, materials and other fields, just like a cornerstone, with many carrying possibilities.
What are the synthesis methods of 2,4-dichloro-1,3,5-trifluorobenzene?
2% 2C4-difluoro-1% 2C3% 2C5-trichlorobenzene is also an organic compound. There are many ways to synthesize it, try to describe it in detail for you.
One method uses benzene as the starting material. First, benzene is reacted with chlorine under specific conditions, such as at an appropriate temperature, with iron or ferric chloride as the catalyst, chlorobenzene can be obtained. Chlorobenzene is further reacted with chlorine. By regulating the reaction conditions, such as temperature, chlorine dosage and reaction time, chlorination can occur at different positions on the benzene ring to form a polychlorobenzene isomer mixture. Subsequently, the resulting mixture is separated to obtain 1% 2C3% 2C5-trichlorobenzene. Then 1% 2C3% 2C5-trichlorobenzene is fluorinated with fluorinating reagents, such as potassium fluoride, in the presence of suitable solvents and catalysts, and finally 2% 2C4-difluoro-1% 2C3% 2C5-trichlorobenzene is obtained. In this process, the conditions of fluorination reaction are quite critical, and it is necessary to strictly control the temperature, pressure and reaction time to ensure the selectivity and yield of fluorination.
Another method can be started from other chlorine-containing and fluorine-containing compounds. For example, using chlorofluorobenzene derivatives containing appropriate substituents as raw materials, through a series of substitution reactions. First, the desired chlorine atoms or fluorine atoms are introduced by nucleophilic substitution reaction, and the molecular structure is gradually modified. The molecular structure of 2% 2C4-difluoro-1% 2C3% 2C5-trichlorobenzene was finally constructed through multi-step reaction, fine adjustment of the position and type of substituents. This method requires in-depth understanding of the mechanism of each step of the reaction and precise control of the reaction conditions in order to achieve efficient synthesis of the target product.
Furthermore, some special organic synthesis strategies can also be used, such as the coupling reaction catalyzed by transition metals. Select suitable halogenated aromatics and fluorine-containing reagents, and the coupling reaction occurs under the catalysis of transition metal catalysts such as palladium and nickel. Such reaction conditions are relatively mild and highly selective, but the selection of catalysts and the optimization of the reaction system are very high. The synthesis of 2% 2C4-difluoro-1% 2C3% 2C5-trichlorobenzene can be achieved by ingeniously designing the reaction route and rationally matching the reactants and catalysts.
One method uses benzene as the starting material. First, benzene is reacted with chlorine under specific conditions, such as at an appropriate temperature, with iron or ferric chloride as the catalyst, chlorobenzene can be obtained. Chlorobenzene is further reacted with chlorine. By regulating the reaction conditions, such as temperature, chlorine dosage and reaction time, chlorination can occur at different positions on the benzene ring to form a polychlorobenzene isomer mixture. Subsequently, the resulting mixture is separated to obtain 1% 2C3% 2C5-trichlorobenzene. Then 1% 2C3% 2C5-trichlorobenzene is fluorinated with fluorinating reagents, such as potassium fluoride, in the presence of suitable solvents and catalysts, and finally 2% 2C4-difluoro-1% 2C3% 2C5-trichlorobenzene is obtained. In this process, the conditions of fluorination reaction are quite critical, and it is necessary to strictly control the temperature, pressure and reaction time to ensure the selectivity and yield of fluorination.
Another method can be started from other chlorine-containing and fluorine-containing compounds. For example, using chlorofluorobenzene derivatives containing appropriate substituents as raw materials, through a series of substitution reactions. First, the desired chlorine atoms or fluorine atoms are introduced by nucleophilic substitution reaction, and the molecular structure is gradually modified. The molecular structure of 2% 2C4-difluoro-1% 2C3% 2C5-trichlorobenzene was finally constructed through multi-step reaction, fine adjustment of the position and type of substituents. This method requires in-depth understanding of the mechanism of each step of the reaction and precise control of the reaction conditions in order to achieve efficient synthesis of the target product.
Furthermore, some special organic synthesis strategies can also be used, such as the coupling reaction catalyzed by transition metals. Select suitable halogenated aromatics and fluorine-containing reagents, and the coupling reaction occurs under the catalysis of transition metal catalysts such as palladium and nickel. Such reaction conditions are relatively mild and highly selective, but the selection of catalysts and the optimization of the reaction system are very high. The synthesis of 2% 2C4-difluoro-1% 2C3% 2C5-trichlorobenzene can be achieved by ingeniously designing the reaction route and rationally matching the reactants and catalysts.
What are the precautions for storing and transporting 2,4-dichloro-1,3,5-trifluorobenzene?
2% 2C4-difluoro-1% 2C3% 2C5-trichlorobenzene is a special chemical substance. When storing and transporting, many precautions need to be paid attention to.
First of all, store in a cool, dry and well-ventilated place. This is because the substance may be sensitive to temperature and humidity, high temperature and humid environment, which can easily cause its properties to change, and even cause chemical reactions. And it needs to be kept away from fire and heat sources to prevent it from being dangerous due to heat. Because it may be flammable and explosive, if it is not careful, it will cause disaster.
Furthermore, the storage place should be separated from oxidants, acids, bases, etc., and must not be mixed. If such substances come into contact with it, or cause violent chemical reactions, endangering safety. The storage area needs to be equipped with suitable materials to contain the leakage, in case of leakage, and can be dealt with in time to prevent its spread from causing greater harm.
As for transportation, make sure that the packaging is complete and sealed before transportation. If the packaging is damaged and the substance leaks, it will not only pollute the environment, but also endanger the safety of the transporting personnel and the surrounding area. During transportation, make sure that the container does not tip, fall or damage. The transportation vehicle should also be equipped with the corresponding variety and quantity of fire fighting equipment and leakage emergency treatment equipment. And when transportation, it should be driven according to the specified route, and do not stop in densely populated areas and residential areas to avoid major casualties in the event of an accident. Escort personnel are also required to be familiar with the nature of the substance and emergency treatment methods, and to ensure the safety of transportation during transportation.
First of all, store in a cool, dry and well-ventilated place. This is because the substance may be sensitive to temperature and humidity, high temperature and humid environment, which can easily cause its properties to change, and even cause chemical reactions. And it needs to be kept away from fire and heat sources to prevent it from being dangerous due to heat. Because it may be flammable and explosive, if it is not careful, it will cause disaster.
Furthermore, the storage place should be separated from oxidants, acids, bases, etc., and must not be mixed. If such substances come into contact with it, or cause violent chemical reactions, endangering safety. The storage area needs to be equipped with suitable materials to contain the leakage, in case of leakage, and can be dealt with in time to prevent its spread from causing greater harm.
As for transportation, make sure that the packaging is complete and sealed before transportation. If the packaging is damaged and the substance leaks, it will not only pollute the environment, but also endanger the safety of the transporting personnel and the surrounding area. During transportation, make sure that the container does not tip, fall or damage. The transportation vehicle should also be equipped with the corresponding variety and quantity of fire fighting equipment and leakage emergency treatment equipment. And when transportation, it should be driven according to the specified route, and do not stop in densely populated areas and residential areas to avoid major casualties in the event of an accident. Escort personnel are also required to be familiar with the nature of the substance and emergency treatment methods, and to ensure the safety of transportation during transportation.
What are the effects of 2,4-dichloro-1,3,5-trifluorobenzene on the environment and human health?
2% 2C4-dichloro-1% 2C3% 2C5-triazinobenzene, this substance has the following effects on the environment and human health:
In terms of the environment, it has a certain persistence in the environment. Due to its relatively stable chemical structure, it is not easy to decompose rapidly under natural conditions, and it is easy to remain in environmental media such as soil and water bodies. In soil, it may affect the structure and function of soil microbial communities, and interfere with the material cycle and energy flow of soil ecosystems. For example, inhibit the activity of certain microorganisms involved in the decomposition of soil organic matter, hindering the process of soil fertility recovery and nutrient transformation. In water bodies, it can cause harm to aquatic organisms. It can damage the cell membrane structure of aquatic organisms and interfere with their physiological metabolism, such as affecting the respiration, feeding and reproduction of fish, reducing aquatic biodiversity and disrupting water ecological balance.
As far as human health is concerned, it has potential toxicity. Inhalation through the respiratory tract can irritate the mucosa of the respiratory tract, causing symptoms such as cough, asthma, and breathing difficulties. Long-term exposure may also damage lung tissue and increase the risk of respiratory diseases. If it is exposed through the skin, it may cause skin allergies, redness, swelling, itching, etc. In severe cases, it may even penetrate the skin into the blood circulation and damage other organs of the body. Oral ingestion can damage the digestive system, cause symptoms such as nausea, vomiting, and abdominal pain. It may also cause damage to important organs such as the liver and kidneys, affecting their normal metabolism and detoxification functions. Long-term or large-scale exposure to this substance may even pose a potential carcinogenic risk, interfering with the normal growth and differentiation of human cells, and causing cells to become cancerous.
The ancients said: "The nature of things has advantages and disadvantages." Although this chemical has its uses in some industrial fields, the harm to the environment and personal health should not be underestimated. People should use it cautiously, and must not leave it to future generations because of its temporary convenience. Scientific methods must be used to control its harm, to ensure the safety of the environment and the health of the human body.
In terms of the environment, it has a certain persistence in the environment. Due to its relatively stable chemical structure, it is not easy to decompose rapidly under natural conditions, and it is easy to remain in environmental media such as soil and water bodies. In soil, it may affect the structure and function of soil microbial communities, and interfere with the material cycle and energy flow of soil ecosystems. For example, inhibit the activity of certain microorganisms involved in the decomposition of soil organic matter, hindering the process of soil fertility recovery and nutrient transformation. In water bodies, it can cause harm to aquatic organisms. It can damage the cell membrane structure of aquatic organisms and interfere with their physiological metabolism, such as affecting the respiration, feeding and reproduction of fish, reducing aquatic biodiversity and disrupting water ecological balance.
As far as human health is concerned, it has potential toxicity. Inhalation through the respiratory tract can irritate the mucosa of the respiratory tract, causing symptoms such as cough, asthma, and breathing difficulties. Long-term exposure may also damage lung tissue and increase the risk of respiratory diseases. If it is exposed through the skin, it may cause skin allergies, redness, swelling, itching, etc. In severe cases, it may even penetrate the skin into the blood circulation and damage other organs of the body. Oral ingestion can damage the digestive system, cause symptoms such as nausea, vomiting, and abdominal pain. It may also cause damage to important organs such as the liver and kidneys, affecting their normal metabolism and detoxification functions. Long-term or large-scale exposure to this substance may even pose a potential carcinogenic risk, interfering with the normal growth and differentiation of human cells, and causing cells to become cancerous.
The ancients said: "The nature of things has advantages and disadvantages." Although this chemical has its uses in some industrial fields, the harm to the environment and personal health should not be underestimated. People should use it cautiously, and must not leave it to future generations because of its temporary convenience. Scientific methods must be used to control its harm, to ensure the safety of the environment and the health of the human body.
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