Linshang Chemical
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3,4-Dichloro-Benzeneethanamine
Linshang Chemical
|
HS Code |
545175 |
| Chemical Formula | C8H7Cl2N |
| Molecular Weight | 188.05 |
| Appearance | Solid |
| Odor | Typical organic chemical odor |
| Solubility In Water | Low solubility |
| Solubility In Organic Solvents | Soluble in many organic solvents |
| Toxicity | Toxic, may cause harm to health |
| Hazard Class | Irritant, potentially harmful |
As an accredited 3,4-Dichloro-Benzeneethanamine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100 - gram pack of 3,4 - dichloro - benzeneethanamine in sealed chemical - grade container. |
| Storage | 3,4 - dichloro - benzeneethanamine should be stored in a cool, dry, well - ventilated area. Keep it away from heat sources, open flames, and oxidizing agents. Store in a tightly - sealed container to prevent leakage and exposure to air and moisture. Label the storage container clearly with the chemical's name, properties, and safety warnings. |
| Shipping | 3,4 - dichloro - benzeneethanamine is likely shipped in specialized, leak - proof containers. It must adhere to strict hazardous chemical regulations, with proper labeling and handling to ensure safe transportation and prevent environmental and safety risks. |
Competitive 3,4-Dichloro-Benzeneethanamine 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 3,4-Dichloro-Benzeneethanamine in China?
As a trusted 3,4-Dichloro-Benzeneethanamine 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 3,4-Dichloro-Benzeneethanamine 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 3,4-dichlorophenethylamine?
Dioxy isobutyl ether, which is an organic compound, has a wide range of main uses.
In the industrial field, it is often used as a solvent. Because of its good solubility, it can effectively dissolve many organic substances, such as resins, paints, coatings, etc. With this characteristic, in the production of paints, it can help the resin and pigment to disperse evenly, thereby improving the quality and coating performance of the paint; in the manufacture of paints, it can adjust the viscosity and drying speed of the paint, making the paint easier to apply and forming a flat and smooth paint film.
In the organic synthesis reaction, dioxy isobutyl ether is also an important reaction medium. Its stable chemical properties can provide a suitable environment for the reaction and contribute to the smooth progress of the reaction. Some organic synthesis reactions that require strict reaction conditions can achieve higher reaction yields and selectivity when dioxy isobutyl ether is used as a medium.
In addition, in some specific medical fields, it may be used in the synthesis and purification process of drugs. Its solubility can help separate and extract active ingredients, and play a certain role in drug development and production.
However, it should be noted that dioxy isobutyl ether is an organic compound, which is volatile and flammable. When using, be sure to follow safety operating procedures to ensure that it is operated in a well-ventilated environment, away from open flames and high temperatures, to avoid safety accidents such as fires and explosions.
In the industrial field, it is often used as a solvent. Because of its good solubility, it can effectively dissolve many organic substances, such as resins, paints, coatings, etc. With this characteristic, in the production of paints, it can help the resin and pigment to disperse evenly, thereby improving the quality and coating performance of the paint; in the manufacture of paints, it can adjust the viscosity and drying speed of the paint, making the paint easier to apply and forming a flat and smooth paint film.
In the organic synthesis reaction, dioxy isobutyl ether is also an important reaction medium. Its stable chemical properties can provide a suitable environment for the reaction and contribute to the smooth progress of the reaction. Some organic synthesis reactions that require strict reaction conditions can achieve higher reaction yields and selectivity when dioxy isobutyl ether is used as a medium.
In addition, in some specific medical fields, it may be used in the synthesis and purification process of drugs. Its solubility can help separate and extract active ingredients, and play a certain role in drug development and production.
However, it should be noted that dioxy isobutyl ether is an organic compound, which is volatile and flammable. When using, be sure to follow safety operating procedures to ensure that it is operated in a well-ventilated environment, away from open flames and high temperatures, to avoid safety accidents such as fires and explosions.
What are the physical properties of 3,4-dichlorophenethylamine?
Dioxane ring is an important organic compound with unique physical properties and is widely used in chemical, pharmaceutical and other fields. Its physical properties are as follows:
- ** Appearance and odor **: Under normal conditions, dioxane ring is a colorless and transparent liquid with a weak odor and ether-like smell. This property makes it suitable for many application scenarios that require strict odor requirements, such as some chemical reactions that require an odorless environment, or the production of medicines and fragrances with strict restrictions on product odor.
- ** Boiling point and melting point **: The boiling point is about 74-76 ° C, and the melting point is about -95 ° C. The relatively low boiling point makes dioxane ring easy to vaporize under moderate heating conditions, which is conducive to separation and purification by distillation. In chemical production, dioxane ring can be separated from the mixed liquid by distillation by controlling the temperature. The low melting point indicates that it can maintain a stable liquid state at room temperature, which is convenient for storage and transportation.
- ** Solubility **: Dioxane ring can be miscible with water in any ratio, and can be miscible with common organic solvents such as ethanol and ether. Good solubility makes it an excellent solvent. In the field of organic synthesis, it is often used to dissolve various organic compounds and help chemical reactions proceed smoothly. For example, when preparing specific pharmaceutical intermediates, dioxane ring can be used as a solvent to promote full contact of the reactants and speed up the reaction rate.
- ** Density **: The density is about 1.06 g/cm ³, which is slightly higher than that of water. This density characteristic is significant when it comes to the operation of mixed systems involving dioxane rings with water or other liquids of different densities. For example, during the extraction process, the layered separation of dioxane rings from other liquids can be achieved depending on the density difference.
- ** Stability **: Dioxane rings are chemically relatively stable, but under certain conditions, in case of high temperature, open flame or strong oxidizing agent, it may still cause danger. At high temperature, it may decompose to produce harmful gases, which are flammable in case of open flame, and may react violently in contact with strong oxidizing agents. Therefore, when storing and using dioxane rings, it is necessary to strictly follow safety procedures and keep away from fire sources, heat sources and strong oxidizing agents.
- ** Appearance and odor **: Under normal conditions, dioxane ring is a colorless and transparent liquid with a weak odor and ether-like smell. This property makes it suitable for many application scenarios that require strict odor requirements, such as some chemical reactions that require an odorless environment, or the production of medicines and fragrances with strict restrictions on product odor.
- ** Boiling point and melting point **: The boiling point is about 74-76 ° C, and the melting point is about -95 ° C. The relatively low boiling point makes dioxane ring easy to vaporize under moderate heating conditions, which is conducive to separation and purification by distillation. In chemical production, dioxane ring can be separated from the mixed liquid by distillation by controlling the temperature. The low melting point indicates that it can maintain a stable liquid state at room temperature, which is convenient for storage and transportation.
- ** Solubility **: Dioxane ring can be miscible with water in any ratio, and can be miscible with common organic solvents such as ethanol and ether. Good solubility makes it an excellent solvent. In the field of organic synthesis, it is often used to dissolve various organic compounds and help chemical reactions proceed smoothly. For example, when preparing specific pharmaceutical intermediates, dioxane ring can be used as a solvent to promote full contact of the reactants and speed up the reaction rate.
- ** Density **: The density is about 1.06 g/cm ³, which is slightly higher than that of water. This density characteristic is significant when it comes to the operation of mixed systems involving dioxane rings with water or other liquids of different densities. For example, during the extraction process, the layered separation of dioxane rings from other liquids can be achieved depending on the density difference.
- ** Stability **: Dioxane rings are chemically relatively stable, but under certain conditions, in case of high temperature, open flame or strong oxidizing agent, it may still cause danger. At high temperature, it may decompose to produce harmful gases, which are flammable in case of open flame, and may react violently in contact with strong oxidizing agents. Therefore, when storing and using dioxane rings, it is necessary to strictly follow safety procedures and keep away from fire sources, heat sources and strong oxidizing agents.
Is the chemical property of 3,4-dichlorophenethylamine stable?
As a new type of energetic material, the chemical properties of 3% 2C4-dioxofurazan oxide (DNTF for short) have a certain stability.
From the perspective of molecular structure, DNTF molecules are connected by specific chemical bonds. The furazan ring and the dioxofurazan structure in its molecule endow it with unique chemical stability. The furazan ring has a certain aromaticity. This aromatic structure makes the electron cloud distribution inside the molecule relatively uniform, which enhances the stability of the molecule. At the same time, the chemical bonds formed between the oxygen atoms in the dioxofurazan structure and the surrounding atoms also play an important role in the overall stability.
In common chemical environments, DNTF can maintain a relatively stable state at room temperature and pressure. It is not prone to rapid chemical reactions with common substances such as oxygen and water in the air. This is due to the strength of its chemical bonds and the characteristics of its molecular configuration.
However, like many energetic materials, the stability of DNTF is challenged when it is exposed to extreme conditions, such as high temperature, high pressure or strong mechanical shock. High temperatures may cause chemical bonds within molecules to gain enough energy to break, triggering chemical reactions; high pressure may change the distance and interaction between molecules, and may also cause changes in chemical bonds. However, under normal storage and general use conditions, 3% 2C4-dioxofurazyl oxide can maintain chemical stability, thus providing basic conditions for its application in related fields, such as military ammunition and space propellant.
From the perspective of molecular structure, DNTF molecules are connected by specific chemical bonds. The furazan ring and the dioxofurazan structure in its molecule endow it with unique chemical stability. The furazan ring has a certain aromaticity. This aromatic structure makes the electron cloud distribution inside the molecule relatively uniform, which enhances the stability of the molecule. At the same time, the chemical bonds formed between the oxygen atoms in the dioxofurazan structure and the surrounding atoms also play an important role in the overall stability.
In common chemical environments, DNTF can maintain a relatively stable state at room temperature and pressure. It is not prone to rapid chemical reactions with common substances such as oxygen and water in the air. This is due to the strength of its chemical bonds and the characteristics of its molecular configuration.
However, like many energetic materials, the stability of DNTF is challenged when it is exposed to extreme conditions, such as high temperature, high pressure or strong mechanical shock. High temperatures may cause chemical bonds within molecules to gain enough energy to break, triggering chemical reactions; high pressure may change the distance and interaction between molecules, and may also cause changes in chemical bonds. However, under normal storage and general use conditions, 3% 2C4-dioxofurazyl oxide can maintain chemical stability, thus providing basic conditions for its application in related fields, such as military ammunition and space propellant.
What are the preparation methods of 3,4-dichlorophenethylamine?
There are various methods for the preparation of glutaric anhydride. One is based on glutaric acid and obtained by dehydration. Glutaric acid is dehydrated by heating in the presence of a suitable catalyst, such as acetic anhydride or acetyl chloride, and the anhydride is formed. The reason for the reaction is that the carboxyl groups in the glutaric acid molecule interact to remove a molecule of water to form a cyclic anhydride structure.
There are also those who use glutaric acid esters as the starting materials. Glutaric acid esters are hydrolyzed and cyclized under the action of an alkaline catalyst. First hydrolyzed to glutaric acid, and then dehydrated and cyclized under the catalysis of a base, dioxyglutaric acid anhydride can also be obtained. In this process, alkali can promote the ionization and reaction activity of carboxyl groups, making dehydration and cyclization easier.
Furthermore, glutaric acid derivatives containing specific substituents can also be used as raw materials for the preparation of dioxyglutaric anhydride through appropriate functional group conversion and cyclization reactions. For example, some glutaric acid derivatives with easily leaving groups can form an acid anhydride structure through nucleophilic substitution in molecules under specific reaction conditions.
The preparation conditions are quite critical. Temperature control needs to be appropriate, too high or side reactions will occur, and too low will slow down the reaction rate. The type and dosage of catalyst also affect the reaction process and yield. The purity of the reaction system and the choice of solvent all affect the preparation effect of dioglutaric anhydride. The solvent needs to be compatible with the reactants and products without interfering with the progress of the main reaction.
In summary, the methods for preparing dioglutaric anhydride vary depending on the raw materials and reaction conditions. To obtain high-purity and high-yield products, the advantages and disadvantages of each method should be carefully studied, and the reaction conditions should be carefully selected and optimized.
There are also those who use glutaric acid esters as the starting materials. Glutaric acid esters are hydrolyzed and cyclized under the action of an alkaline catalyst. First hydrolyzed to glutaric acid, and then dehydrated and cyclized under the catalysis of a base, dioxyglutaric acid anhydride can also be obtained. In this process, alkali can promote the ionization and reaction activity of carboxyl groups, making dehydration and cyclization easier.
Furthermore, glutaric acid derivatives containing specific substituents can also be used as raw materials for the preparation of dioxyglutaric anhydride through appropriate functional group conversion and cyclization reactions. For example, some glutaric acid derivatives with easily leaving groups can form an acid anhydride structure through nucleophilic substitution in molecules under specific reaction conditions.
The preparation conditions are quite critical. Temperature control needs to be appropriate, too high or side reactions will occur, and too low will slow down the reaction rate. The type and dosage of catalyst also affect the reaction process and yield. The purity of the reaction system and the choice of solvent all affect the preparation effect of dioglutaric anhydride. The solvent needs to be compatible with the reactants and products without interfering with the progress of the main reaction.
In summary, the methods for preparing dioglutaric anhydride vary depending on the raw materials and reaction conditions. To obtain high-purity and high-yield products, the advantages and disadvantages of each method should be carefully studied, and the reaction conditions should be carefully selected and optimized.
What are the precautions for 3,4-dichlorophenethylamine during storage and transportation?
3% 2C4 -Dioxofurazanyl oxide, this product is highly toxic and unstable, highly explosive, and needs to be extremely cautious during storage and transportation. A little carelessness may cause serious accidents.
In terms of storage, the first choice of environment. It should be placed in a cool, dry and well-ventilated place, away from fire and heat sources. Because it is extremely sensitive to temperature and humidity, excessive temperature or humidity will cause it to decompose or even explode. The temperature of the warehouse should be strictly controlled within a specific range, and the humidity should also be precisely controlled. At the same time, it should be stored separately from oxidants, reducing agents, acids, bases and other substances, and must not be mixed to prevent violent chemical reactions. Furthermore, the storage area must be equipped with complete leakage emergency treatment equipment and suitable containment materials, so that it can respond quickly in the event of an emergency.
When transporting, it is necessary to ensure that the packaging is complete and safely loaded. Packaging materials need to have good compression resistance, shock resistance and leakage resistance, which can effectively resist bumps and collisions during transportation. The transportation process should be far away from densely populated areas and traffic arteries, and choose a safe and convenient route. Transportation vehicles need to be equipped with corresponding varieties and quantities of fire fighting equipment and leakage emergency treatment equipment. Escort personnel must be professionally trained, familiar with the dangerous characteristics of the transported goods and emergency treatment methods. During transportation, they should pay close attention to the status of the goods. If any abnormalities are found, effective measures should be taken immediately.
In short, for high-risk substances such as 3% 2C4-dioxofurazyl oxide, every detail in the storage and transportation process is related to safety, and there is no room for sloppiness.
In terms of storage, the first choice of environment. It should be placed in a cool, dry and well-ventilated place, away from fire and heat sources. Because it is extremely sensitive to temperature and humidity, excessive temperature or humidity will cause it to decompose or even explode. The temperature of the warehouse should be strictly controlled within a specific range, and the humidity should also be precisely controlled. At the same time, it should be stored separately from oxidants, reducing agents, acids, bases and other substances, and must not be mixed to prevent violent chemical reactions. Furthermore, the storage area must be equipped with complete leakage emergency treatment equipment and suitable containment materials, so that it can respond quickly in the event of an emergency.
When transporting, it is necessary to ensure that the packaging is complete and safely loaded. Packaging materials need to have good compression resistance, shock resistance and leakage resistance, which can effectively resist bumps and collisions during transportation. The transportation process should be far away from densely populated areas and traffic arteries, and choose a safe and convenient route. Transportation vehicles need to be equipped with corresponding varieties and quantities of fire fighting equipment and leakage emergency treatment equipment. Escort personnel must be professionally trained, familiar with the dangerous characteristics of the transported goods and emergency treatment methods. During transportation, they should pay close attention to the status of the goods. If any abnormalities are found, effective measures should be taken immediately.
In short, for high-risk substances such as 3% 2C4-dioxofurazyl oxide, every detail in the storage and transportation process is related to safety, and there is no room for sloppiness.
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