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(3-Chloro-4-Methoxycarbonyl)Benzeneboronic Acid
Linshang Chemical
|
HS Code |
900156 |
| Name | (3-Chloro-4-Methoxycarbonyl)Benzeneboronic Acid |
| Chemical Formula | C9H10BClO4 |
| Molecular Weight | 228.44 |
| Appearance | Typically a solid (physical state depends on conditions) |
| Melting Point | Data may vary, needs specific determination |
| Solubility | Solubility characteristics vary by solvent, e.g., some solubility in polar organic solvents |
| Purity | Purity can range depending on production and purification, e.g., 95%+ in high - quality samples |
| Boiling Point | Requires experimental determination, decomposition may occur before boiling |
| Density | Specific density data needs experimental measurement |
| Stability | Should be stored properly, may be sensitive to air, moisture |
As an accredited (3-Chloro-4-Methoxycarbonyl)Benzeneboronic Acid factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100g of (3 - chloro - 4 - methoxycarbonyl)benzeneboronic Acid in sealed, labeled container. |
| Storage | (3 - Chloro - 4 - methoxycarbonyl)benzeneboronic acid should be stored in a cool, dry place away from heat and direct sunlight. Keep it in a tightly sealed container to prevent moisture absorption and contact with air, which could lead to degradation. Store separately from incompatible substances, like strong oxidizing agents or bases, to ensure its stability. |
| Shipping | (3 - chloro - 4 - methoxycarbonyl)benzeneboronic acid is shipped in well - sealed containers, following strict chemical shipping regulations. Special care is taken to prevent damage and ensure safe transport due to its chemical nature. |
Competitive (3-Chloro-4-Methoxycarbonyl)Benzeneboronic Acid prices that fit your budget—flexible terms and customized quotes for every order.
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Where to Buy (3-Chloro-4-Methoxycarbonyl)Benzeneboronic Acid 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 (3-Chloro-4-Methoxycarbonyl)Benzeneboronic Acid 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-chloro-4-methoxycarbonyl) phenylboronic acid?
(3-Ammonia-4-methylhydroxybenzyl) benzothiazolic acid has a wide range of main uses.
In the field of medicine, this compound has unique medicinal potential. Due to its structural properties, it may be helpful for the treatment of specific diseases. For example, it can be used as a lead compound for medical researchers to explore in depth, and the structure can be modified and optimized to develop highly effective drugs for specific diseases. Or it can play a role in anti-inflammation, reducing inflammation by regulating inflammation-related signaling pathways in the body, providing a new direction for the treatment of inflammatory diseases; or it has inhibitory effects on the growth and proliferation of certain tumor cells, which is expected to become an important basis for the development of anti-cancer drugs.
In the field of materials science, it also has unique value. Due to the special physical and chemical properties of the molecular structure, it can be used to prepare new functional materials. For example, by participating in the synthesis of optoelectronic device materials, with its unique response to light and electricity, the performance of optoelectronic devices can be improved, such as improving the photoelectric conversion efficiency of solar cells, or optimizing the luminescence performance of organic Light Emitting Diodes. In addition, in terms of sensor materials, (3-ammonia-4-methylhydroxybenzyl) benzothiazolic acid may selectively interact with specific substances, thereby constructing highly sensitive and highly selective chemical sensors for detecting environmental pollutants, biomarkers, etc., to assist environmental monitoring and biomedical diagnosis.
In the agricultural field, it may be used as a raw material for new pesticides or plant growth regulators. If used as a pesticide, it has special killing or inhibitory activity against certain crop pests or pathogens, and compared with traditional pesticides, it may have the advantages of low toxicity, high efficiency and environmental friendliness, which is conducive to the realization of green agricultural production; if used as a plant growth regulator, it can precisely regulate the growth and development process of plants, such as promoting seed germination, improving crop yield and quality, etc.
In the field of medicine, this compound has unique medicinal potential. Due to its structural properties, it may be helpful for the treatment of specific diseases. For example, it can be used as a lead compound for medical researchers to explore in depth, and the structure can be modified and optimized to develop highly effective drugs for specific diseases. Or it can play a role in anti-inflammation, reducing inflammation by regulating inflammation-related signaling pathways in the body, providing a new direction for the treatment of inflammatory diseases; or it has inhibitory effects on the growth and proliferation of certain tumor cells, which is expected to become an important basis for the development of anti-cancer drugs.
In the field of materials science, it also has unique value. Due to the special physical and chemical properties of the molecular structure, it can be used to prepare new functional materials. For example, by participating in the synthesis of optoelectronic device materials, with its unique response to light and electricity, the performance of optoelectronic devices can be improved, such as improving the photoelectric conversion efficiency of solar cells, or optimizing the luminescence performance of organic Light Emitting Diodes. In addition, in terms of sensor materials, (3-ammonia-4-methylhydroxybenzyl) benzothiazolic acid may selectively interact with specific substances, thereby constructing highly sensitive and highly selective chemical sensors for detecting environmental pollutants, biomarkers, etc., to assist environmental monitoring and biomedical diagnosis.
In the agricultural field, it may be used as a raw material for new pesticides or plant growth regulators. If used as a pesticide, it has special killing or inhibitory activity against certain crop pests or pathogens, and compared with traditional pesticides, it may have the advantages of low toxicity, high efficiency and environmental friendliness, which is conducive to the realization of green agricultural production; if used as a plant growth regulator, it can precisely regulate the growth and development process of plants, such as promoting seed germination, improving crop yield and quality, etc.
What are the synthesis methods of (3-chloro-4-methoxycarbonyl) phenylboronic acid?
The synthesis method of (3-ammonia-4-methoxyphenyl) thiophenecarboxylic acid has been known for a long time. There are many methods, each with its own advantages and disadvantages, and with the passage of time, new methods have emerged.
The synthesis method in the past, first, based on [starting material 1], has undergone several steps of reaction. First, the [starting material 1] and [reagent 1] are heated to a suitable temperature under specific conditions, such as in an organic solvent, and the [reaction type 1] reaction occurs to form the intermediate [intermediate 1]. This step requires attention to the control of the reaction time and temperature. If the time is too short or the temperature is not appropriate, the reaction can be incomplete. Then, the intermediate [intermediate 1] and [reagent 2] reacted again [reaction type 2] to obtain the target product (3-ammonia-4-methoxyphenyl) thiophenecarboxylic acid. Although this path is more classical, the steps are slightly complicated, and the cost of some reagents is quite high, which also requires certain reaction equipment.
Second, there are also those who start with [starting material 2]. Shilling [starting material 2] and [reagent 3] carry out [reaction type 3] reaction to generate the key intermediate [intermediate 2]. This intermediate [intermediate 2] is then treated with [specific reaction conditions 2], and then reacts with [reagent 4] to obtain (3-ammonia-4-methoxyphenyl) thiophenecarboxylic acid. This method is relatively simple compared to the former, but some reaction conditions are more harsh, which requires very high operation, and the improvement of product purity also needs fine regulation.
Today, science and technology are changing, and new synthesis methods are also emerging. If a new catalyst is used, the reaction can be achieved under mild conditions, which can not only save steps, but also improve the yield and purity of the product. Or with the help of green chemistry concept, choose more environmentally friendly solvents and reagents to make the synthesis process more in line with the needs of sustainable development. However, the new method also faces challenges, such as the high cost of new catalysts, and the stability of the supply of green reagents needs to be considered.
The synthesis method in the past, first, based on [starting material 1], has undergone several steps of reaction. First, the [starting material 1] and [reagent 1] are heated to a suitable temperature under specific conditions, such as in an organic solvent, and the [reaction type 1] reaction occurs to form the intermediate [intermediate 1]. This step requires attention to the control of the reaction time and temperature. If the time is too short or the temperature is not appropriate, the reaction can be incomplete. Then, the intermediate [intermediate 1] and [reagent 2] reacted again [reaction type 2] to obtain the target product (3-ammonia-4-methoxyphenyl) thiophenecarboxylic acid. Although this path is more classical, the steps are slightly complicated, and the cost of some reagents is quite high, which also requires certain reaction equipment.
Second, there are also those who start with [starting material 2]. Shilling [starting material 2] and [reagent 3] carry out [reaction type 3] reaction to generate the key intermediate [intermediate 2]. This intermediate [intermediate 2] is then treated with [specific reaction conditions 2], and then reacts with [reagent 4] to obtain (3-ammonia-4-methoxyphenyl) thiophenecarboxylic acid. This method is relatively simple compared to the former, but some reaction conditions are more harsh, which requires very high operation, and the improvement of product purity also needs fine regulation.
Today, science and technology are changing, and new synthesis methods are also emerging. If a new catalyst is used, the reaction can be achieved under mild conditions, which can not only save steps, but also improve the yield and purity of the product. Or with the help of green chemistry concept, choose more environmentally friendly solvents and reagents to make the synthesis process more in line with the needs of sustainable development. However, the new method also faces challenges, such as the high cost of new catalysts, and the stability of the supply of green reagents needs to be considered.
What are the physical properties of (3-chloro-4-methoxycarbonyl) phenylboronic acid?
(3-Ammonia-4-methylhydroxyphenyl) benzothiazolic acid, the physical properties of this substance are as follows:
Its appearance is often in a specific shape, or it is crystalline, and it has a certain regular geometric shape. The crystal surface is flat and shiny, like a carefully carved miniature object. Its color is either colorless and transparent, or it is a light color, just like the morning light through thin clouds, giving it a unique visual appearance.
Smell it, (3-ammonia-4-methylhydroxyphenyl) benzothiazolic acid may emit a slight smell, but its smell is not pungent and unpleasant, but like a faint breath hidden in the depths, which needs to be sniffed carefully to be detected, just like a wisp of fragrance in the depths of the forest.
As for solubility, in specific solvents, it shows unique solubility characteristics. In some polar solvents, such as alcohols, there is a certain solubility, just like ice and snow melt when warm, slowly fusing with the solvent to form a uniform system; in non-polar solvents, the solubility is very small, just like the incompatibility of oil and water, which are distinct from each other.
Its melting point is also one of the important physical properties. When the temperature gradually rises to a certain value, (3-ammonia-4-methylhydroxyphenyl) benzothiazolic acid will change from solid to liquid. This melting point temperature is like a key node in the transformation of its material morphology. It is precise and unique, and has become one of the important basis for identifying this substance.
In terms of density, it has a specific value, reflecting the tightness of its molecular arrangement. Just like the masonry of a building, the density of the arrangement is different, and the density is also different. This density characteristic has significance that cannot be ignored in many practical application scenarios.
Its appearance is often in a specific shape, or it is crystalline, and it has a certain regular geometric shape. The crystal surface is flat and shiny, like a carefully carved miniature object. Its color is either colorless and transparent, or it is a light color, just like the morning light through thin clouds, giving it a unique visual appearance.
Smell it, (3-ammonia-4-methylhydroxyphenyl) benzothiazolic acid may emit a slight smell, but its smell is not pungent and unpleasant, but like a faint breath hidden in the depths, which needs to be sniffed carefully to be detected, just like a wisp of fragrance in the depths of the forest.
As for solubility, in specific solvents, it shows unique solubility characteristics. In some polar solvents, such as alcohols, there is a certain solubility, just like ice and snow melt when warm, slowly fusing with the solvent to form a uniform system; in non-polar solvents, the solubility is very small, just like the incompatibility of oil and water, which are distinct from each other.
Its melting point is also one of the important physical properties. When the temperature gradually rises to a certain value, (3-ammonia-4-methylhydroxyphenyl) benzothiazolic acid will change from solid to liquid. This melting point temperature is like a key node in the transformation of its material morphology. It is precise and unique, and has become one of the important basis for identifying this substance.
In terms of density, it has a specific value, reflecting the tightness of its molecular arrangement. Just like the masonry of a building, the density of the arrangement is different, and the density is also different. This density characteristic has significance that cannot be ignored in many practical application scenarios.
Is (3-chloro-4-methoxycarbonyl) phenylboronic acid chemically stable?
The chemical properties of (3-mercapto-4-methoxyphenyl) thiazole carboxylic acid are still stable. In the structure of this compound, the thiazole ring has a certain rigidity, which can make the molecular configuration relatively stable. The methoxyphenyl part affects the electron cloud distribution of the thiazole ring due to the power supply effect of the methoxy group, but this effect is not enough to make the overall structure prone to variability. Although the thiol group has a certain reactivity, in the general environment, it is difficult to cause significant changes without the action of specific reagents.
Looking at its chemical environment, if it is at room temperature and pressure, and there are no strong oxidizing agents, strong reducing agents or special catalysts, this compound can maintain a stable state. The combination of its chemical bonds and the interaction between atoms endow the substance with a certain degree of chemical inertness.
Even in common organic solvents, (3-mercapto-4-methoxyphenyl) thiazole carboxylic acid is not easy to decompose or rearrange. The conjugate system between the thiazole ring and the phenyl group reduces the molecular energy and stabilizes the structure. Therefore, considering its structure and common chemical environment, the chemical properties of (3-mercapto-4-methoxyphenyl) thiazole carboxylic acid are relatively stable.
Looking at its chemical environment, if it is at room temperature and pressure, and there are no strong oxidizing agents, strong reducing agents or special catalysts, this compound can maintain a stable state. The combination of its chemical bonds and the interaction between atoms endow the substance with a certain degree of chemical inertness.
Even in common organic solvents, (3-mercapto-4-methoxyphenyl) thiazole carboxylic acid is not easy to decompose or rearrange. The conjugate system between the thiazole ring and the phenyl group reduces the molecular energy and stabilizes the structure. Therefore, considering its structure and common chemical environment, the chemical properties of (3-mercapto-4-methoxyphenyl) thiazole carboxylic acid are relatively stable.
What are the precautions for (3-chloro-4-methoxycarbonyl) phenylboronic acid in storage and transportation?
(3-Ammonia-4-methylhydroxyphenyl) benzenesulfonic acid needs to pay attention to many matters during storage and transportation.
When storing it, the first environment should be selected. It must be placed in a cool, dry and well-ventilated place, because if the substance is exposed to high temperature, humid environment, or chemical properties change due to excessive temperature, or moisture causes deliquescence, etc., it will damage its quality. And it should be kept away from fire and heat sources, because it has certain chemical activity, in case of open flame, hot topic or risk of combustion and explosion.
Furthermore, when storing, it should be stored separately from oxidizing agents, acids, bases, etc., and cannot be mixed. The ammonia, hydroxyl and other groups in the chemical structure of this substance make it chemically active, mix with the above substances, or cause violent chemical reactions, resulting in dangerous accidents.
As for transportation, the packaging must be tight. To ensure that the packaging container is not at risk of leakage, to prevent the substance from leaking during transportation, polluting the environment or endangering the safety of transportation personnel. During transportation, it is also necessary to avoid exposure to the sun, rain, and high temperature. The vehicle should run smoothly, and do not brake or turn sharply to avoid damage to the packaging.
Transportation vehicles also need to meet specific requirements and be equipped with corresponding fire equipment and leakage emergency treatment equipment. Once there is an emergency situation such as leakage during transportation, it can be dealt with immediately. Transport personnel should also receive professional training to familiarize themselves with the characteristics of the substance and emergency treatment methods, and operate cautiously during transportation to ensure safe transportation.
When storing it, the first environment should be selected. It must be placed in a cool, dry and well-ventilated place, because if the substance is exposed to high temperature, humid environment, or chemical properties change due to excessive temperature, or moisture causes deliquescence, etc., it will damage its quality. And it should be kept away from fire and heat sources, because it has certain chemical activity, in case of open flame, hot topic or risk of combustion and explosion.
Furthermore, when storing, it should be stored separately from oxidizing agents, acids, bases, etc., and cannot be mixed. The ammonia, hydroxyl and other groups in the chemical structure of this substance make it chemically active, mix with the above substances, or cause violent chemical reactions, resulting in dangerous accidents.
As for transportation, the packaging must be tight. To ensure that the packaging container is not at risk of leakage, to prevent the substance from leaking during transportation, polluting the environment or endangering the safety of transportation personnel. During transportation, it is also necessary to avoid exposure to the sun, rain, and high temperature. The vehicle should run smoothly, and do not brake or turn sharply to avoid damage to the packaging.
Transportation vehicles also need to meet specific requirements and be equipped with corresponding fire equipment and leakage emergency treatment equipment. Once there is an emergency situation such as leakage during transportation, it can be dealt with immediately. Transport personnel should also receive professional training to familiarize themselves with the characteristics of the substance and emergency treatment methods, and operate cautiously during transportation to ensure safe transportation.
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