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1,3-Dichloro-4-Fluorobenzene
Linshang Chemical
|
HS Code |
620814 |
| Chemical Formula | C6H3Cl2F |
| Molar Mass | 166.99 g/mol |
| Appearance | Colorless to light yellow liquid |
| Boiling Point | 174 - 176 °C |
| Density | 1.42 g/cm³ (approximate) |
| Solubility In Water | Insoluble |
| Solubility In Organic Solvents | Soluble in many organic solvents like ethanol, ether |
| Vapor Pressure | Low (data may vary with temperature) |
| Flash Point | 64 °C (approximate) |
As an accredited 1,3-Dichloro-4-Fluorobenzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 1,3 - Dichloro - 4 - fluorobenzene: Packed in 500 - gram bottles for chemical storage. |
| Storage | 1,3 - dichloro - 4 - fluorobenzene should be stored in a cool, well - ventilated storage area. Keep it away from heat, sparks, and open flames as it is potentially flammable. Store in tightly closed containers to prevent vapor leakage. Separate it from oxidizing agents and incompatible substances. Label the storage containers clearly for easy identification and safety. |
| Shipping | 1,3 - dichloro - 4 - fluorobenzene is shipped in accordance with strict hazardous chemical regulations. It is typically packaged in specialized containers to prevent leakage, and transported by carriers trained in handling such substances. |
Competitive 1,3-Dichloro-4-Fluorobenzene 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 1,3-Dichloro-4-Fluorobenzene in China?
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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 1,3-Dichloro-4-Fluorobenzene 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 1,3-dichloro-4-fluorobenzene?
The main uses of 1% 2C3 (suspected to be "carbon monoxide"), carbon dioxide, 4 (suspected to be unknown), and olefins are described in "Tiangong Kaiwu" as follows:
Carbon monoxide, although it did not have its exact name in ancient times, may be generated when coal is not fully burned in smelting and casting industries. For industrial use, it can be used as a reducing agent. In the iron smelting industry, carbon monoxide can capture oxygen in iron ore, causing iron to reduce and precipitate, which is a key step in iron smelting.
Carbon dioxide, although it is not named "carbon dioxide" in "Tiangong Kaiwu", may be involved in related phenomena in the book. Its uses are quite many, and it can be one of the raw materials in alkali making. And when making wine, the carbon dioxide produced by the fermentation process is related to the quality and flavor of the wine. In terms of fire extinguishing, although the ancients did not clearly state the principle of carbon dioxide extinguishing fire, when water, sand, etc. are extinguished, carbon dioxide may be generated to help extinguish fire.
For olefins, at the time of "Tiangong Kaiwu", there was no concept of "olefins". However, based on today's chemical knowledge, olefins are crucial in organic synthesis. Plastics can be made, and today's plastics are widely used. Although there were no plastics in ancient times, they were similar to organic synthesis ideas, or they can provide raw materials for fabric dyeing and fragrance production. Olefins can be polymerized to produce various polymer materials. Although this technology did not exist in ancient times, it will develop in the future. This is an important direction. And olefins can be used to prepare solvents. In the ancient lacquer art, printing and dyeing industries, if there is an appropriate solvent, the process effect can be improved.
Carbon monoxide, although it did not have its exact name in ancient times, may be generated when coal is not fully burned in smelting and casting industries. For industrial use, it can be used as a reducing agent. In the iron smelting industry, carbon monoxide can capture oxygen in iron ore, causing iron to reduce and precipitate, which is a key step in iron smelting.
Carbon dioxide, although it is not named "carbon dioxide" in "Tiangong Kaiwu", may be involved in related phenomena in the book. Its uses are quite many, and it can be one of the raw materials in alkali making. And when making wine, the carbon dioxide produced by the fermentation process is related to the quality and flavor of the wine. In terms of fire extinguishing, although the ancients did not clearly state the principle of carbon dioxide extinguishing fire, when water, sand, etc. are extinguished, carbon dioxide may be generated to help extinguish fire.
For olefins, at the time of "Tiangong Kaiwu", there was no concept of "olefins". However, based on today's chemical knowledge, olefins are crucial in organic synthesis. Plastics can be made, and today's plastics are widely used. Although there were no plastics in ancient times, they were similar to organic synthesis ideas, or they can provide raw materials for fabric dyeing and fragrance production. Olefins can be polymerized to produce various polymer materials. Although this technology did not exist in ancient times, it will develop in the future. This is an important direction. And olefins can be used to prepare solvents. In the ancient lacquer art, printing and dyeing industries, if there is an appropriate solvent, the process effect can be improved.
What are the physical properties of 1,3-dichloro-4-fluorobenzene
1% 2C3 + - + dioxy + - + 4 + - + alkynes are rational compounds.
For dioxy, the chemical formula is $O_2 $, and the density is slightly larger than that of air, slightly soluble in water. Its melting temperature is -218.4 ° C, boiling temperature is -183 ° C. Dioxy is fire-supporting, and plays an important role in combustion reaction, and it is also important for the respiration of the fuel.
4-alkynes are compounds containing carbon and carbon. Its physical rationality depends on the molecular weight. Generally speaking, alkynes are often low, and small molecules, such as acetylene, have an increase in molecular weight, and are liquid or even solid. Acetylene is soluble in water, easily soluble in soluble substances such as benzene, carbon tetrachloride, etc. Its boiling temperature is affected by the molecular force. The larger the molecular weight, the greater the molecular force, and the higher the melting temperature. And the density of ethylene is usually smaller than that of water.
Acetylene is a typical example of ethylene, and the color under the pressure is often slightly smelly, and the workmanship has a special odor due to its content. Its density is smaller than that of air, slightly soluble in water, and easily soluble in acetone and other soluble substances.
For example, dioxy has the characteristics of supporting combustion; alkyne aggregates differently according to molecular weight, and is soluble in water. It has specific solubility and density characteristics, and has its own important properties in the chemical field.
For dioxy, the chemical formula is $O_2 $, and the density is slightly larger than that of air, slightly soluble in water. Its melting temperature is -218.4 ° C, boiling temperature is -183 ° C. Dioxy is fire-supporting, and plays an important role in combustion reaction, and it is also important for the respiration of the fuel.
4-alkynes are compounds containing carbon and carbon. Its physical rationality depends on the molecular weight. Generally speaking, alkynes are often low, and small molecules, such as acetylene, have an increase in molecular weight, and are liquid or even solid. Acetylene is soluble in water, easily soluble in soluble substances such as benzene, carbon tetrachloride, etc. Its boiling temperature is affected by the molecular force. The larger the molecular weight, the greater the molecular force, and the higher the melting temperature. And the density of ethylene is usually smaller than that of water.
Acetylene is a typical example of ethylene, and the color under the pressure is often slightly smelly, and the workmanship has a special odor due to its content. Its density is smaller than that of air, slightly soluble in water, and easily soluble in acetone and other soluble substances.
For example, dioxy has the characteristics of supporting combustion; alkyne aggregates differently according to molecular weight, and is soluble in water. It has specific solubility and density characteristics, and has its own important properties in the chemical field.
What is the production method of 1,3-dichloro-4-fluorobenzene?
1. ** On the ancient method of "production method of 1,3-diol-4-allyl" **
- ** According to the ancient books, the basis of the ancient method **: To find the ancient method of production of 1,3-diol-4-allyl, although the ancient books rarely describe this thing directly, it can be deduced according to the chemical principles and the preparation wisdom of the ancients for similar substances. Ancient alchemy, pharmacology and early chemical practice are all the sources of exploring its methods. Alchemists have accumulated experience in the transformation of many substances in the process of gold and stone calcination and drug synthesis. For example, the reaction of various minerals during alchemy is recorded in "Baopuzi · Inner Chapter", which reveals the preliminary cognition of the ancient people on chemical changes, and can provide ideas for exploring the preparation of 1,3-diol-4-allyl.
- ** Raw material exploration, natural source **: According to the ancient method, the raw material should be taken from nature. 1,3-diol-4-allyl contains carbon, hydrogen, and oxygen elements. It can be speculated that the ancient people took vegetable oils, plants or minerals containing hydroxyl groups as starting materials. Vegetable oils such as tung oil and castor oil contain unsaturated bonds and hydroxyl groups, which can be converted after appropriate treatment. And in ancient times, it was customary to use herbs and trees to make medicines, and some herbs containing special functional groups may be used as key raw materials. For example, the "Compendium of Materia Medica" contains a variety of plant characteristics, which can be referred to for raw material selection.
- ** Process simulation, the path of the ancient method **: The ancients did not have modern precision instruments, and their processes were mostly based on observation and experience. Or first decompose and transform the raw materials by heating. For example, use retort and other utensils to control the heat, carry out distillation and fractionation. Heat vegetable oils, low boiling point ingredients come out first, and components containing target functional groups are distilled out at a specific temperature range. Or use fermentation methods, with the help of microorganisms, to transform the raw material components. Ancient wine brewing and vinegar brewing are all examples of fermentation, which can be deduced if suitable microorganisms are selected, or can catalyze the formation of 1,3-diol-4-allyl from raw materials. Then purified by water leaching, extraction, etc., such as wine, water and other solvents, the target product is separated from the complex mixture to achieve a relatively pure state.
- ** According to the ancient books, the basis of the ancient method **: To find the ancient method of production of 1,3-diol-4-allyl, although the ancient books rarely describe this thing directly, it can be deduced according to the chemical principles and the preparation wisdom of the ancients for similar substances. Ancient alchemy, pharmacology and early chemical practice are all the sources of exploring its methods. Alchemists have accumulated experience in the transformation of many substances in the process of gold and stone calcination and drug synthesis. For example, the reaction of various minerals during alchemy is recorded in "Baopuzi · Inner Chapter", which reveals the preliminary cognition of the ancient people on chemical changes, and can provide ideas for exploring the preparation of 1,3-diol-4-allyl.
- ** Raw material exploration, natural source **: According to the ancient method, the raw material should be taken from nature. 1,3-diol-4-allyl contains carbon, hydrogen, and oxygen elements. It can be speculated that the ancient people took vegetable oils, plants or minerals containing hydroxyl groups as starting materials. Vegetable oils such as tung oil and castor oil contain unsaturated bonds and hydroxyl groups, which can be converted after appropriate treatment. And in ancient times, it was customary to use herbs and trees to make medicines, and some herbs containing special functional groups may be used as key raw materials. For example, the "Compendium of Materia Medica" contains a variety of plant characteristics, which can be referred to for raw material selection.
- ** Process simulation, the path of the ancient method **: The ancients did not have modern precision instruments, and their processes were mostly based on observation and experience. Or first decompose and transform the raw materials by heating. For example, use retort and other utensils to control the heat, carry out distillation and fractionation. Heat vegetable oils, low boiling point ingredients come out first, and components containing target functional groups are distilled out at a specific temperature range. Or use fermentation methods, with the help of microorganisms, to transform the raw material components. Ancient wine brewing and vinegar brewing are all examples of fermentation, which can be deduced if suitable microorganisms are selected, or can catalyze the formation of 1,3-diol-4-allyl from raw materials. Then purified by water leaching, extraction, etc., such as wine, water and other solvents, the target product is separated from the complex mixture to achieve a relatively pure state.
What are the precautions for the use of 1,3-dichloro-4-fluorobenzene?
When using dioxetetraethyl lead, there are many key things to pay attention to.
First, this substance is very toxic. During operation, it must not be allowed to contact the skin, and it must be careful not to inhale its volatile gas. You must wear complete protective equipment, such as gas masks, protective gloves and protective clothing, to ensure your own safety.
Second, because of its volatility, it must be used in a well-ventilated place. If the ventilation is poor, its volatile gas will easily accumulate in the space, greatly increasing the risk of poisoning. It is necessary to be equipped with efficient ventilation equipment to discharge the volatile gas in time.
Third, the dosage should be strictly controlled during use. Use it accurately according to actual needs, avoid waste, and do not use it in excess. Because it is toxic, excessive use will not only cause harm to the user himself, but also cause serious pollution to the surrounding environment.
Fourth, after use, properly dispose of the remaining materials and use appliances. Do not discard the remaining lead at will, and should be treated harmlessly in accordance with relevant regulations. Used appliances should also be carefully cleaned to avoid residual poisons affecting subsequent use.
Fifth, caution should also be used when storing. It should be placed in a cool, dry and ventilated place, away from fire and heat sources, and stored separately from other chemicals to prevent chemical reactions and accidents.
The use of dioxetraethyl lead requires a rigorous and prudent attitude and strict follow of all precautions to ensure personal safety and environmental safety.
First, this substance is very toxic. During operation, it must not be allowed to contact the skin, and it must be careful not to inhale its volatile gas. You must wear complete protective equipment, such as gas masks, protective gloves and protective clothing, to ensure your own safety.
Second, because of its volatility, it must be used in a well-ventilated place. If the ventilation is poor, its volatile gas will easily accumulate in the space, greatly increasing the risk of poisoning. It is necessary to be equipped with efficient ventilation equipment to discharge the volatile gas in time.
Third, the dosage should be strictly controlled during use. Use it accurately according to actual needs, avoid waste, and do not use it in excess. Because it is toxic, excessive use will not only cause harm to the user himself, but also cause serious pollution to the surrounding environment.
Fourth, after use, properly dispose of the remaining materials and use appliances. Do not discard the remaining lead at will, and should be treated harmlessly in accordance with relevant regulations. Used appliances should also be carefully cleaned to avoid residual poisons affecting subsequent use.
Fifth, caution should also be used when storing. It should be placed in a cool, dry and ventilated place, away from fire and heat sources, and stored separately from other chemicals to prevent chemical reactions and accidents.
The use of dioxetraethyl lead requires a rigorous and prudent attitude and strict follow of all precautions to ensure personal safety and environmental safety.
What is the market outlook for 1,3-dichloro-4-fluorobenzene?
Looking at the market prospects of 1,3-carbon dioxide-4-ethylene today, it can be said that opportunities and challenges coexist.
Since the industrial boom in the world, the demand for 1,3-carbon dioxide-4-ethylene is growing. In chemical fields, it is an important raw material and can produce a variety of high-value products. For example, in the manufacture of plastic materials, based on it, flexible and strong plastic products can be made, which are used in packaging, construction and other industries. Due to the prosperity of the plastic industry, the demand for it has also increased. In addition, in the manufacture of medical materials, through exquisite craftsmanship, it can be used to make medical products suitable for the human body. The medical industry is booming every day. The demand in this regard should not be underestimated.
Moreover, with the advance of science and technology, new uses are opened up. Researchers explore its potential in the fields of new energy, electronic materials, etc. If the battery separator material, with its characteristics, or the ability to enhance the battery, the new energy industry is booming, which will lead to new demand for 1,3-carbon dioxide-4-ethylene.
However, its market also has challenges. First, the production process is not perfect, some steps are complicated and costly, resulting in low efficiency and high price. In the market competition, the high price hinders its wide use. Second, environmental protection regulations are becoming stricter. If the process of producing this substance or the discharge of pollutants is not followed, it will be punished, which is not conducive to the long-term development of the enterprise. Third, there are also competing products in the market, and other materials or new substances are used instead, or they are superior in price and performance, and their market share is divided.
Although the market prospect of 1,3-carbon dioxide-4-ethylene is bright, if you want to dominate the market, enterprises must strive to develop new products, reduce costs and improve efficiency; pay attention to environmental protection, and comply with regulations; and observe the changes in the market, and should be selected by competing products, so as to stabilize in the market tide.
Since the industrial boom in the world, the demand for 1,3-carbon dioxide-4-ethylene is growing. In chemical fields, it is an important raw material and can produce a variety of high-value products. For example, in the manufacture of plastic materials, based on it, flexible and strong plastic products can be made, which are used in packaging, construction and other industries. Due to the prosperity of the plastic industry, the demand for it has also increased. In addition, in the manufacture of medical materials, through exquisite craftsmanship, it can be used to make medical products suitable for the human body. The medical industry is booming every day. The demand in this regard should not be underestimated.
Moreover, with the advance of science and technology, new uses are opened up. Researchers explore its potential in the fields of new energy, electronic materials, etc. If the battery separator material, with its characteristics, or the ability to enhance the battery, the new energy industry is booming, which will lead to new demand for 1,3-carbon dioxide-4-ethylene.
However, its market also has challenges. First, the production process is not perfect, some steps are complicated and costly, resulting in low efficiency and high price. In the market competition, the high price hinders its wide use. Second, environmental protection regulations are becoming stricter. If the process of producing this substance or the discharge of pollutants is not followed, it will be punished, which is not conducive to the long-term development of the enterprise. Third, there are also competing products in the market, and other materials or new substances are used instead, or they are superior in price and performance, and their market share is divided.
Although the market prospect of 1,3-carbon dioxide-4-ethylene is bright, if you want to dominate the market, enterprises must strive to develop new products, reduce costs and improve efficiency; pay attention to environmental protection, and comply with regulations; and observe the changes in the market, and should be selected by competing products, so as to stabilize in the market tide.
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