Linshang Chemical
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Benzeneethanamine, 4-Chloro-, Hydrochloride
Linshang Chemical
|
HS Code |
503826 |
| Chemical Name | Benzeneethanamine, 4 - Chloro -, Hydrochloride |
| Molecular Formula | C8H11ClN.ClH |
| Molar Mass | 192.09 g/mol |
| Appearance | White to off - white powder |
| Solubility | Soluble in water, methanol |
| Melting Point | 190 - 194 °C |
| Odor | Odorless |
| Purity | Typically high purity in pharmaceutical - grade products |
As an accredited Benzeneethanamine, 4-Chloro-, Hydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100 - gram pack of 4 - chloro - benzeneethanamine hydrochloride in sealed container. |
| Storage | Store “Benzeneethanamine, 4 - chloro -, Hydrochloride” in a cool, dry place away from heat and ignition sources. Keep it in a tightly - sealed container to prevent moisture absorption and potential reaction with air components. Store it separately from oxidizing agents and incompatible substances to avoid chemical reactions that could pose safety risks. |
| Shipping | Benzeneethanamine, 4 - chloro -, Hydrochloride is shipped in accordance with strict chemical transport regulations. It's carefully packaged to prevent leakage, transported in vehicles suitable for hazardous chemicals, ensuring safety during transit. |
Competitive Benzeneethanamine, 4-Chloro-, Hydrochloride 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
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What are the physical properties of 4-chlorophenethylamine hydrochloride?
The physical appearance of mercury bromide is clear red, and it is crystalline or powdery. It is slightly soluble in water, but it is also soluble in ethanol. It has the ability of anti-corrosion and disinfection, and was mostly used on small skin in the past.
Mercury bromide is often red, and its crystalline shape is complete, with a certain shape, and can be reflected by the crystal surface under light. And the powder, such as. Its solubility, water, can be dissolved, but the solubility is limited, and the water liquid is light red, with a certain degree of transparency. As for ethanol, due to its molecular properties, mercury bromomercurate is soluble in it, and it sinks more at the bottom in ethanol, without melting.
Its density is large, and it feels heavy in the hand. When it is affected, it will not be damaged, or it will decompose, resulting in a tasty product. And mercury bromomercurate has certain toxicity. Special attention should be paid to it when used. It should not be used to prevent damage to the body. Therefore, this substance has its uses in the past, but due to its toxicity and other characteristics, it has been used with caution today.
Mercury bromide is often red, and its crystalline shape is complete, with a certain shape, and can be reflected by the crystal surface under light. And the powder, such as. Its solubility, water, can be dissolved, but the solubility is limited, and the water liquid is light red, with a certain degree of transparency. As for ethanol, due to its molecular properties, mercury bromomercurate is soluble in it, and it sinks more at the bottom in ethanol, without melting.
Its density is large, and it feels heavy in the hand. When it is affected, it will not be damaged, or it will decompose, resulting in a tasty product. And mercury bromomercurate has certain toxicity. Special attention should be paid to it when used. It should not be used to prevent damage to the body. Therefore, this substance has its uses in the past, but due to its toxicity and other characteristics, it has been used with caution today.
What are the chemical properties of 4-chlorophenethylamine hydrochloride?
Haloboroacetic anhydride is a chemical substance with various chemical properties.
Haloboroacetic anhydride is active and often used as an electrophilic agent in chemical reactions. It can react with many substances containing electron pairs. If it meets alcohols, it will form halogenated hydrocarbons and borate esters. It has a wide range of uses in the field of organic synthesis and can assist in the formation of carbon-boron bonds. This bond has special chemical activity and can be used for subsequent transformation.
Acetic anhydride, also known as acetic anhydride, has a pungent smell. It has the ability to acylate and can transfer acyl groups to compounds such as alcohols and amines. When reacted with alcohols, esters and acetic acid are formed. This reaction is often used in the preparation of esters. And in organic synthesis, it is an important acetylation reagent, which can acetylate phenols, amines and other compounds to change the physical and chemical properties of the compounds.
Cyanoic anhydride is unstable in nature. It decomposes easily in contact with water to form cyanic acid and other products. Cyanoic anhydride is occasionally used in organic synthesis and can participate in the construction of specific nitrogen-containing compounds. However, due to its instability, it needs to be used with extreme caution and the operating conditions are quite harsh.
Although these substances have their own characteristics, they all have their unique uses in the field of chemistry. They are either raw materials for synthesis or reagents for reaction. They all play an important role in promoting the progress of chemical science and the development of organic synthesis.
Haloboroacetic anhydride is active and often used as an electrophilic agent in chemical reactions. It can react with many substances containing electron pairs. If it meets alcohols, it will form halogenated hydrocarbons and borate esters. It has a wide range of uses in the field of organic synthesis and can assist in the formation of carbon-boron bonds. This bond has special chemical activity and can be used for subsequent transformation.
Acetic anhydride, also known as acetic anhydride, has a pungent smell. It has the ability to acylate and can transfer acyl groups to compounds such as alcohols and amines. When reacted with alcohols, esters and acetic acid are formed. This reaction is often used in the preparation of esters. And in organic synthesis, it is an important acetylation reagent, which can acetylate phenols, amines and other compounds to change the physical and chemical properties of the compounds.
Cyanoic anhydride is unstable in nature. It decomposes easily in contact with water to form cyanic acid and other products. Cyanoic anhydride is occasionally used in organic synthesis and can participate in the construction of specific nitrogen-containing compounds. However, due to its instability, it needs to be used with extreme caution and the operating conditions are quite harsh.
Although these substances have their own characteristics, they all have their unique uses in the field of chemistry. They are either raw materials for synthesis or reagents for reaction. They all play an important role in promoting the progress of chemical science and the development of organic synthesis.
In which fields is 4-chlorophenethylamine hydrochloride used?
"Tiangong Kaiwu" does not mention which fields potassium ferrocyanate is used in. In today's world, the two are widely used.
Potassium cyanoferrite, also known as potassium yellow blood salt, is often used as a steel carburizing agent in the field of metallurgy, which can help form a hard and wear-resistant carburizing layer on the surface of steel, making the instrument durable. For chemical analysis, it is a commonly used reagent, which can accurately detect certain metal ions. If it encounters iron ions, a specific blue precipitate is formed. With this characteristic, the presence or absence of iron ions can be distinguished. It is also useful for preventing caking in table salt. Adding a small amount can effectively prevent salt from caking, making table salt loose and easy to obtain, and convenient for people's livelihood.
Potassium ferric cyanide, also known as red blood salt potassium, is an important developer in the photography industry in the past. It can reduce the photosensitive silver halide to metallic silver, thus showing the image and making great contributions to the memory of the past. In the printing and dyeing industry, it can be used as a mordant, and the dye can be firmly attached to the fabric, so that the color of printing and dyeing is bright and lasting, and it will not fade for a long time. In the preparation of other iron compounds, it is also a key raw material. Through specific chemical reactions, a variety of iron compounds with special properties can be derived to meet the diverse needs of various fields.
Potassium cyanoferrite, also known as potassium yellow blood salt, is often used as a steel carburizing agent in the field of metallurgy, which can help form a hard and wear-resistant carburizing layer on the surface of steel, making the instrument durable. For chemical analysis, it is a commonly used reagent, which can accurately detect certain metal ions. If it encounters iron ions, a specific blue precipitate is formed. With this characteristic, the presence or absence of iron ions can be distinguished. It is also useful for preventing caking in table salt. Adding a small amount can effectively prevent salt from caking, making table salt loose and easy to obtain, and convenient for people's livelihood.
Potassium ferric cyanide, also known as red blood salt potassium, is an important developer in the photography industry in the past. It can reduce the photosensitive silver halide to metallic silver, thus showing the image and making great contributions to the memory of the past. In the printing and dyeing industry, it can be used as a mordant, and the dye can be firmly attached to the fabric, so that the color of printing and dyeing is bright and lasting, and it will not fade for a long time. In the preparation of other iron compounds, it is also a key raw material. Through specific chemical reactions, a variety of iron compounds with special properties can be derived to meet the diverse needs of various fields.
What is the preparation method of 4-chlorophenethylamine hydrochloride?
To make borofluoric acid, the method is as follows:
Prepare equipment, take acid-resistant glass kettle or porcelain kettle, with condensing pipes, receiving devices, and all connections must be closed to prevent gas from escaping.
Prepare raw materials, borax and hydrofluoric acid are necessary. Borax, mostly obtained from salt lake deposition or boron ore refining, its mild nature, is the key material for the production of borofluoric acid. Hydrofluoric acid is a highly corrosive acid, often obtained by co-thermal distillation of fluorite and concentrated sulfuric acid, and should be used with extreme caution. When
is prepared, slowly put borax into an appropriate amount of hydrofluoric acid, heat it at low temperature in the kettle, and do not overheat to prevent overreaction. The reason for the reaction is that borax encounters hydrofluoric acid, and boron in borax combines with fluorine in hydrofluoric acid to produce borofluoric acid. Between the reactions, it can be seen that there are bubbles rising in the kettle, which is the gas produced by the reaction.
After the reaction is completed, the steam is cooled and liquefied in a condensing tube, and flows into the receiving vessel. The resulting liquid is borofluoric acid. However, this product or containing impurities can be purified by distillation, filtration, etc., to obtain pure borofluoric acid.
The entire preparation process, due to the strong corrosiveness of hydrofluoric acid, must be operated in a well-ventilated place, and the manufacturer needs protective equipment, such as acid-resistant gloves, protective masks, etc., to prevent injury to themselves.
Prepare equipment, take acid-resistant glass kettle or porcelain kettle, with condensing pipes, receiving devices, and all connections must be closed to prevent gas from escaping.
Prepare raw materials, borax and hydrofluoric acid are necessary. Borax, mostly obtained from salt lake deposition or boron ore refining, its mild nature, is the key material for the production of borofluoric acid. Hydrofluoric acid is a highly corrosive acid, often obtained by co-thermal distillation of fluorite and concentrated sulfuric acid, and should be used with extreme caution. When
is prepared, slowly put borax into an appropriate amount of hydrofluoric acid, heat it at low temperature in the kettle, and do not overheat to prevent overreaction. The reason for the reaction is that borax encounters hydrofluoric acid, and boron in borax combines with fluorine in hydrofluoric acid to produce borofluoric acid. Between the reactions, it can be seen that there are bubbles rising in the kettle, which is the gas produced by the reaction.
After the reaction is completed, the steam is cooled and liquefied in a condensing tube, and flows into the receiving vessel. The resulting liquid is borofluoric acid. However, this product or containing impurities can be purified by distillation, filtration, etc., to obtain pure borofluoric acid.
The entire preparation process, due to the strong corrosiveness of hydrofluoric acid, must be operated in a well-ventilated place, and the manufacturer needs protective equipment, such as acid-resistant gloves, protective masks, etc., to prevent injury to themselves.
What are the storage conditions for 4-chlorophenethylamine hydrochloride?
The storage conditions of guanidine isothiocyanate in halogen sand are very important in terms of its quality and utility.
Guanidine isothiocyanate in halogen sand is active and easy to react with surrounding substances. It should be stored in a cool place. Due to high temperature, it can cause changes in its molecular structure and accelerate decomposition and deterioration. For example, in summer, if placed in a high temperature environment, its active ingredients may be rapidly depleted.
It is also necessary in a dry place. This substance is easily soluble in water and prone to reactions such as hydrolysis, and a humid environment will greatly reduce its stability. If it is placed in a place with water vapor, its properties can be changed in a few days, and its effectiveness is not as good as before.
Furthermore, it is necessary to avoid direct light. Light has energy, which can trigger the photochemical reaction of guanidine isothiocyanate in halogen sand, causing its composition to change. If it is exposed to sunlight or exposed to strong light for a long time, its quality will be seriously affected.
In addition, the storage place should be well ventilated. Good ventilation can avoid excessive local concentrations, reduce the risk of overreaction with some components in the air, and can timely disperse undesirable gases generated by possible weak reactions to maintain the stability of its storage environment.
In the selection of containers, it is appropriate to use materials that are corrosion-resistant and have good sealing properties. Guanidine isothiocyanate in halogen sand is corrosive to a certain extent, and ordinary materials are easily eroded, causing it to leak or react with container components. Good sealing can prevent outside water vapor, oxygen and other intrusion, to ensure its purity and stability. In this way, it is necessary to properly store the brine sand guanidine isothiocyanate, so that it can play its due effect in application.
Guanidine isothiocyanate in halogen sand is active and easy to react with surrounding substances. It should be stored in a cool place. Due to high temperature, it can cause changes in its molecular structure and accelerate decomposition and deterioration. For example, in summer, if placed in a high temperature environment, its active ingredients may be rapidly depleted.
It is also necessary in a dry place. This substance is easily soluble in water and prone to reactions such as hydrolysis, and a humid environment will greatly reduce its stability. If it is placed in a place with water vapor, its properties can be changed in a few days, and its effectiveness is not as good as before.
Furthermore, it is necessary to avoid direct light. Light has energy, which can trigger the photochemical reaction of guanidine isothiocyanate in halogen sand, causing its composition to change. If it is exposed to sunlight or exposed to strong light for a long time, its quality will be seriously affected.
In addition, the storage place should be well ventilated. Good ventilation can avoid excessive local concentrations, reduce the risk of overreaction with some components in the air, and can timely disperse undesirable gases generated by possible weak reactions to maintain the stability of its storage environment.
In the selection of containers, it is appropriate to use materials that are corrosion-resistant and have good sealing properties. Guanidine isothiocyanate in halogen sand is corrosive to a certain extent, and ordinary materials are easily eroded, causing it to leak or react with container components. Good sealing can prevent outside water vapor, oxygen and other intrusion, to ensure its purity and stability. In this way, it is necessary to properly store the brine sand guanidine isothiocyanate, so that it can play its due effect in application.
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