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Benzenepropanoic Acid, 2-Chloro-
Linshang Chemical
|
HS Code |
365574 |
| Iupac Name | 2-chlorobenzenepropanoic acid |
| Molecular Formula | C9H9ClO2 |
| Molar Mass | 184.62 g/mol |
| Appearance | Solid (usually) |
| Melting Point | Data needed |
| Boiling Point | Data needed |
| Density | Data needed |
| Solubility In Water | Low solubility (organic acid, hydrophobic benzene ring) |
| Solubility In Organic Solvents | Soluble in common organic solvents like ethanol, ether |
| Acidity Pka | Data needed |
| Hazard Class | Irritant (may cause skin, eye, and respiratory irritation) |
As an accredited Benzenepropanoic Acid, 2-Chloro- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 1 kg of 2 - chloro - benzenepropanoic acid packaged in a sealed plastic drum. |
| Storage | **Storage of 2 - Chloro - benzenepropanoic Acid**: Store this chemical in a cool, dry, well - ventilated area, away from sources of heat, ignition, and direct sunlight. It should be kept in a tightly sealed container made of corrosion - resistant materials, as it may be reactive. Segregate it from incompatible substances like strong oxidizing agents, bases, and reducing agents to prevent chemical reactions. |
| Shipping | Benzenepropanoic acid, 2 - chloro - should be shipped in tightly sealed, corrosion - resistant containers. Label clearly as a chemical. Follow all relevant safety regulations during transportation to prevent spills and ensure safety. |
Competitive Benzenepropanoic Acid, 2-Chloro- 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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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 Benzenepropanoic Acid, 2-Chloro- 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 physical properties of 2-chlorophenylpropionic acid?
Mercury bromide red, or red potion, is a commonly used disinfectant and antiseptic in the past. Its physical properties are as follows:
Looking at its properties, it is mostly small pieces or particles with green or blue-green auburn at room temperature, odorless and hygroscopic. When dissolved in water, it can slowly dissolve. The aqueous solution is bright cherry red, clear and transparent, has no precipitation impurities, and is often fluorescent; while it is extremely difficult to dissolve in ethanol or chloroform.
When it comes to melting point, mercury bromide red has no exact melting point and will decompose and deteriorate at higher temperatures.
Smell its smell, this thing itself has no obvious smell, so it will not cause discomfort due to pungent smell when using.
Considering the density, due to the application of mercury bromide red in the form of aqueous solution, the density of the aqueous solution is slightly greater than that of water, about 1.02-1.05g/cm ³, which results in a slight increase in the density of the solution due to the dissolution of the solute.
Looking at its volatility, mercury bromide red has extremely low volatility, is stable in the air under normal conditions, and is not easy to evaporate and dissipate, so it can be stored and maintained for a long time.
In summary, the physical properties of mercury bromide red give it certain advantages in disinfection and anti-corrosion applications. The color of the aqueous solution is conducive to observing the application range, and it is stable and non-volatile, making it easy to store and use.
Looking at its properties, it is mostly small pieces or particles with green or blue-green auburn at room temperature, odorless and hygroscopic. When dissolved in water, it can slowly dissolve. The aqueous solution is bright cherry red, clear and transparent, has no precipitation impurities, and is often fluorescent; while it is extremely difficult to dissolve in ethanol or chloroform.
When it comes to melting point, mercury bromide red has no exact melting point and will decompose and deteriorate at higher temperatures.
Smell its smell, this thing itself has no obvious smell, so it will not cause discomfort due to pungent smell when using.
Considering the density, due to the application of mercury bromide red in the form of aqueous solution, the density of the aqueous solution is slightly greater than that of water, about 1.02-1.05g/cm ³, which results in a slight increase in the density of the solution due to the dissolution of the solute.
Looking at its volatility, mercury bromide red has extremely low volatility, is stable in the air under normal conditions, and is not easy to evaporate and dissipate, so it can be stored and maintained for a long time.
In summary, the physical properties of mercury bromide red give it certain advantages in disinfection and anti-corrosion applications. The color of the aqueous solution is conducive to observing the application range, and it is stable and non-volatile, making it easy to store and use.
What are the chemical properties of 2-chlorophenylpropionic acid?
Silver halide is an important class of compounds with unique chemical properties, which are described in detail here.
Silver halide is photosensitive. Under light, silver halide will decompose. Take silver chloride as an example. When illuminated, silver chloride decomposes into silver elements and chlorine gas, and the chemical equation is\ (2AgCl\ xlongequal {light} 2Ag + Cl_ {2}\ uparrow\). This photosensitivity is of great significance in the field of photography. In the past, film was coated with silver halide particles. When light irradiated the film, the silver halide decomposed, forming a latent image on the film, and the image could be displayed through development, fixing and other steps.
The solubility of silver halide is also characteristic. In common silver halide, silver fluoride is soluble in water, while silver chloride, silver bromide, and silver iodide are all insoluble in water, and the solubility decreases in sequence according to the order of silver chloride, silver bromide, and silver iodide. This property is often used in chemical analysis, such as the use of chloride ions and silver ions to react to form a white precipitate of silver chloride to check whether there is chloride ions in the solution; Similarly, bromine ions and iodine ions react with silver ions to form a light yellow silver bromide precipitate and a yellow silver iodide precipitate, which can be used to test the corresponding ions.
Silver halide is also oxidizing. Under certain conditions, silver halide can react with a reducing agent and be reduced to silver elemental substance. For example, zinc and other active metals can be replaced with silver halide to replace the silver in the silver halide,\ (Zn + 2AgBr = ZnBr_ {2} + 2Ag\), which shows the properties of silver halide as an oxidizing agent.
Furthermore, the stability of silver halide varies with different halogen ions. Silver fluoride is relatively stable, while silver iodide is less stable. When storing and using silver halide-related substances, its stability factors should be considered to prevent its decomposition and other reactions from affecting the use. These chemical properties of silver halide make it play an important role in many fields, such as photography, chemical analysis, material preparation, etc.
Silver halide is photosensitive. Under light, silver halide will decompose. Take silver chloride as an example. When illuminated, silver chloride decomposes into silver elements and chlorine gas, and the chemical equation is\ (2AgCl\ xlongequal {light} 2Ag + Cl_ {2}\ uparrow\). This photosensitivity is of great significance in the field of photography. In the past, film was coated with silver halide particles. When light irradiated the film, the silver halide decomposed, forming a latent image on the film, and the image could be displayed through development, fixing and other steps.
The solubility of silver halide is also characteristic. In common silver halide, silver fluoride is soluble in water, while silver chloride, silver bromide, and silver iodide are all insoluble in water, and the solubility decreases in sequence according to the order of silver chloride, silver bromide, and silver iodide. This property is often used in chemical analysis, such as the use of chloride ions and silver ions to react to form a white precipitate of silver chloride to check whether there is chloride ions in the solution; Similarly, bromine ions and iodine ions react with silver ions to form a light yellow silver bromide precipitate and a yellow silver iodide precipitate, which can be used to test the corresponding ions.
Silver halide is also oxidizing. Under certain conditions, silver halide can react with a reducing agent and be reduced to silver elemental substance. For example, zinc and other active metals can be replaced with silver halide to replace the silver in the silver halide,\ (Zn + 2AgBr = ZnBr_ {2} + 2Ag\), which shows the properties of silver halide as an oxidizing agent.
Furthermore, the stability of silver halide varies with different halogen ions. Silver fluoride is relatively stable, while silver iodide is less stable. When storing and using silver halide-related substances, its stability factors should be considered to prevent its decomposition and other reactions from affecting the use. These chemical properties of silver halide make it play an important role in many fields, such as photography, chemical analysis, material preparation, etc.
What are the main uses of 2-chlorophenylpropionic acid?
The use of reckless acetic acid is quite wide, and it is involved in all kinds of matters.
First, in the field of medical Tao, reckless acetic acid can be used as a medicine. If it is strong in nature, it can be used to induce the power of medicine to reach the disease, so as to cure the disease. In the past, when a doctor encountered a disease, he used reckless acetic acid skillfully, and led the group of medicines to attack the disease, and the patient was cured.
Second, in the art of alchemy, reckless acetic acid is also an important thing. During alchemy, reckless acetic acid can help the tone of the heat and make the nature of the medicinal pill purer. The ancient alchemists all knew the wonders of reckless acetic acid. They used magic according to their characteristics, refined the elixir, and took it to prolong life.
Third, in the manufacture of utensils, reckless acetic acid also has its merits. For example, when a sword is forged, it is quenched with reckless acetic acid, which can make the blade more powerful and indestructible. With the help of reckless acetic acid, craftsmen have created countless excellent weapons for marching and defending the country.
Fourth, in the matter of farmers, reckless acetic acid can also help. Sprinkle it on the field, it can drive away pests and protect the growth of the seedlings. Farmers know its ability, and use it to protect the fields and ensure the abundance of the five grains.
From this perspective, although reckless acetic acid is strong in nature, it can be used well in many fields such as medicine, Dan, utensils, agriculture, etc., and can be used for the world and benefit people.
First, in the field of medical Tao, reckless acetic acid can be used as a medicine. If it is strong in nature, it can be used to induce the power of medicine to reach the disease, so as to cure the disease. In the past, when a doctor encountered a disease, he used reckless acetic acid skillfully, and led the group of medicines to attack the disease, and the patient was cured.
Second, in the art of alchemy, reckless acetic acid is also an important thing. During alchemy, reckless acetic acid can help the tone of the heat and make the nature of the medicinal pill purer. The ancient alchemists all knew the wonders of reckless acetic acid. They used magic according to their characteristics, refined the elixir, and took it to prolong life.
Third, in the manufacture of utensils, reckless acetic acid also has its merits. For example, when a sword is forged, it is quenched with reckless acetic acid, which can make the blade more powerful and indestructible. With the help of reckless acetic acid, craftsmen have created countless excellent weapons for marching and defending the country.
Fourth, in the matter of farmers, reckless acetic acid can also help. Sprinkle it on the field, it can drive away pests and protect the growth of the seedlings. Farmers know its ability, and use it to protect the fields and ensure the abundance of the five grains.
From this perspective, although reckless acetic acid is strong in nature, it can be used well in many fields such as medicine, Dan, utensils, agriculture, etc., and can be used for the world and benefit people.
What are the synthesis methods of 2-chlorophenylpropionic acid?
Mercury bromored acid, also known as red mercury, has been prepared in many ways throughout the ages, and the following is the detailed description of Jun.
First, the condensation reaction between phthalic anhydride and resorcinol can be carried out under the catalysis of sulfuric acid. This process is like a craftsman's careful carving. First, phthalic anhydride and resorcinol are placed in a reaction kettle in a certain proportion, and sulfuric acid is slowly added as the reaction medium, which seems to lay a gorgeous stage for this chemical dance. At a suitable temperature, the two are cleverly combined to generate 4,5,6,7-tetrahydroxy fluorescent red. This step requires strict control of the temperature and the ratio of the reactants. If there is a slight difference, it will be like music out of tune and affect the quality of the product.
Subsequently, 4,5,6,7-tetrahydroxy fluorescent red reacts with mercury salts. Mercury salts are like magic brushes, adding a key stroke to the product. Under the right reaction conditions, after careful operation, mercury bromored acid is finally formed. During this reaction process, the type, dosage and reaction environment of mercury salts have a profound impact on the product, and it needs to be as careful as a lamp bearer.
Second, there is another way to prepare it. First, resorcinol is used as the starting material, and a specific group is introduced through a series of delicate chemical reactions. This process is like building an exquisite castle, step by step. First, resorcinol reacts with specific reagents to generate intermediate products, which is like the cornerstone of building a castle. Then through multi-step transformation, the molecular framework is gradually constructed.
After that, it reacts ingeniously with reagents containing mercury and bromine, so that mercury and bromine are precisely embedded in the molecular structure, and finally mercury bromocarboxylic acid is obtained. This path requires chemists, such as generals in command of thousands of troops, to know the rhythm and conditions of each step of the reaction well before it can be successfully prepared.
Furthermore, there is a synthesis strategy starting from other related compounds. Starting from some compounds with similar structures, after ingenious chemical modification, it gradually transitions to the structure of mercury bromocarboxylic acid. This strategy is like a masterful danqing, based on existing paintings, carefully modify the brushstrokes, and finally paint the one you like. Through precise selection of starting compounds, rational design of reaction routes, and the use of various chemical reactions, such as substitution, addition, oxidation and reduction, the molecular structure is ingeniously carved, and finally the synthesis of mercury bromored acid is achieved.
This is the method of mercury bromored acid synthesis, each of which gathers the wisdom and hard work of chemists, and shines uniquely in the hall of chemistry.
First, the condensation reaction between phthalic anhydride and resorcinol can be carried out under the catalysis of sulfuric acid. This process is like a craftsman's careful carving. First, phthalic anhydride and resorcinol are placed in a reaction kettle in a certain proportion, and sulfuric acid is slowly added as the reaction medium, which seems to lay a gorgeous stage for this chemical dance. At a suitable temperature, the two are cleverly combined to generate 4,5,6,7-tetrahydroxy fluorescent red. This step requires strict control of the temperature and the ratio of the reactants. If there is a slight difference, it will be like music out of tune and affect the quality of the product.
Subsequently, 4,5,6,7-tetrahydroxy fluorescent red reacts with mercury salts. Mercury salts are like magic brushes, adding a key stroke to the product. Under the right reaction conditions, after careful operation, mercury bromored acid is finally formed. During this reaction process, the type, dosage and reaction environment of mercury salts have a profound impact on the product, and it needs to be as careful as a lamp bearer.
Second, there is another way to prepare it. First, resorcinol is used as the starting material, and a specific group is introduced through a series of delicate chemical reactions. This process is like building an exquisite castle, step by step. First, resorcinol reacts with specific reagents to generate intermediate products, which is like the cornerstone of building a castle. Then through multi-step transformation, the molecular framework is gradually constructed.
After that, it reacts ingeniously with reagents containing mercury and bromine, so that mercury and bromine are precisely embedded in the molecular structure, and finally mercury bromocarboxylic acid is obtained. This path requires chemists, such as generals in command of thousands of troops, to know the rhythm and conditions of each step of the reaction well before it can be successfully prepared.
Furthermore, there is a synthesis strategy starting from other related compounds. Starting from some compounds with similar structures, after ingenious chemical modification, it gradually transitions to the structure of mercury bromocarboxylic acid. This strategy is like a masterful danqing, based on existing paintings, carefully modify the brushstrokes, and finally paint the one you like. Through precise selection of starting compounds, rational design of reaction routes, and the use of various chemical reactions, such as substitution, addition, oxidation and reduction, the molecular structure is ingeniously carved, and finally the synthesis of mercury bromored acid is achieved.
This is the method of mercury bromored acid synthesis, each of which gathers the wisdom and hard work of chemists, and shines uniquely in the hall of chemistry.
What are the precautions for storing and transporting chlorophenylpropionic acid?
Mercury bromide red solution, that is, red potion, needs to pay attention to many key matters during storage and transportation.
When storing it, choose the first environment. When placed in a cool and dry place, away from fire and heat sources. Because mercury bromide red is easy to decompose when heated, its efficacy is reduced, and if it is near a fire source, it will increase the fire hazard. The temperature of the warehouse should be controlled between 15 ° C and 30 ° C, and the humidity should be 45% to 75%, so as to ensure the stability of its chemical properties.
Furthermore, it should be strictly avoided to co-store with acids and alkalis. Mercury bromide red will separate out mercury ions in case of acid, enhancing toxicity; in case of alkali, its structure will be changed, and its efficacy will be lost. And it must be placed separately from the oxidizing agent to prevent oxidation reaction and damage its quality.
Storage containers should not be ignored, and sealed containers made of glass or plastic should be selected. Glass containers are chemically stable and do not react with mercury bromide red; plastic containers are light and not fragile. But they must be well sealed to prevent drug volatilization or moisture.
When transporting, ensure that the packaging is tight and stable. Use thick cartons or wooden boxes with built-in cushioning materials such as foam, sponge, etc., to prevent the container from being damaged due to collision. Transportation vehicles should be clean and odor-free to avoid other chemicals from being mixed with them and prevent mutual contamination.
In addition, transporters should also be familiar with the characteristics of mercury bromide red and emergency treatment methods. If there is a leak during transportation, the crowd should be evacuated immediately, the scene should be isolated, and protective equipment should be worn to avoid direct contact with the human body. The residue should be disposed of according to regulations and should not be discarded at will to avoid polluting the environment.
When storing it, choose the first environment. When placed in a cool and dry place, away from fire and heat sources. Because mercury bromide red is easy to decompose when heated, its efficacy is reduced, and if it is near a fire source, it will increase the fire hazard. The temperature of the warehouse should be controlled between 15 ° C and 30 ° C, and the humidity should be 45% to 75%, so as to ensure the stability of its chemical properties.
Furthermore, it should be strictly avoided to co-store with acids and alkalis. Mercury bromide red will separate out mercury ions in case of acid, enhancing toxicity; in case of alkali, its structure will be changed, and its efficacy will be lost. And it must be placed separately from the oxidizing agent to prevent oxidation reaction and damage its quality.
Storage containers should not be ignored, and sealed containers made of glass or plastic should be selected. Glass containers are chemically stable and do not react with mercury bromide red; plastic containers are light and not fragile. But they must be well sealed to prevent drug volatilization or moisture.
When transporting, ensure that the packaging is tight and stable. Use thick cartons or wooden boxes with built-in cushioning materials such as foam, sponge, etc., to prevent the container from being damaged due to collision. Transportation vehicles should be clean and odor-free to avoid other chemicals from being mixed with them and prevent mutual contamination.
In addition, transporters should also be familiar with the characteristics of mercury bromide red and emergency treatment methods. If there is a leak during transportation, the crowd should be evacuated immediately, the scene should be isolated, and protective equipment should be worn to avoid direct contact with the human body. The residue should be disposed of according to regulations and should not be discarded at will to avoid polluting the environment.
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