Linshang Chemical
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Benzeneacetic Acid, 2,4-Dichloro-
Linshang Chemical
|
HS Code |
459971 |
| Name | 2,4-Dichloro benzeneacetic acid |
| Chemical Formula | C8H6Cl2O2 |
| Molar Mass | 205.04 g/mol |
| Appearance | White to off - white solid |
| Melting Point | 137 - 140 °C |
| Solubility In Water | Slightly soluble in water |
| Solubility In Organic Solvents | Soluble in many organic solvents like ethanol, acetone |
| Pka | Approximately 2.9 |
| Odor | Odorless or very faint odor |
As an accredited Benzeneacetic Acid, 2,4-Dichloro- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 1 kg of 2,4 - dichlorobenzeneacetic acid packaged in a sealed plastic container. |
| Storage | **Storage of 2,4 - Dichlorobenzeneacetic Acid** Store 2,4 - dichlorobenzeneacetic acid in a cool, dry, well - ventilated area. Keep it away from heat sources, open flames, and oxidizing agents. Use a tightly - sealed container made of a suitable material like glass or high - density polyethylene to prevent leakage and contamination. Avoid storing near incompatible substances to ensure safety. |
| Shipping | Benzeneacetic Acid, 2,4 - dichloro - should be shipped in accordance with strict chemical regulations. It must be in well - sealed, corrosion - resistant containers, transported by carriers approved for hazardous chemicals, ensuring proper handling to prevent spills and environmental exposure. |
Competitive Benzeneacetic Acid, 2,4-Dichloro- 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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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 Benzeneacetic Acid, 2,4-Dichloro- supplier, we deliver high-quality products across diverse grades to meet evolving needs, empowering global customers with safe, efficient, and compliant chemical solutions.
What is the main use of phenylacetic acid, 2,4-dichloro-?
Borax, sodium dihydrate-tetrahydroborate, has a wide range of main uses and is important in various fields.
In the field of medicine, borax has the ability to disinfect and prevent corrosion. Throughout the ages, doctors have often used it to make a mouthwash to clear the filth of the mouth and prevent the birth of oral diseases, such as swollen gums and sores on the tongue. Gargle it with borax preparations to relieve its discomfort. When used externally, it can also help heal sores, because it can kill all kinds of poisonous evils, refresh the affected area, and promote new muscle growth.
In industry, borax is an important raw material. In the glass manufacturing industry, the addition of borax can greatly increase the heat resistance of glass, so that glass products can withstand large temperature changes without cracking. Common heat-resistant glassware relies on borax. In the ceramic industry, borax can be used as a component of glaze, which can make the surface of ceramics smooth and shiny, and enhance its hardness and wear resistance, and improve the quality of ceramic products.
In the agricultural field, borax is also indispensable. Boron is a trace element required for plant growth. Appropriate amount of borax applied to the soil can replenish boron for plants and help plant growth and development. Especially for crops such as rape and cotton, borax can promote their flowering and fruiting, improve the setting rate, and increase crop yield.
In daily life, borax is also useful. In detergents, borax can be used as an adjuvant to enhance the decontamination ability of detergents and make clothes cleaner after washing. In the food industry, borax was used to increase the toughness and elasticity of food in the past, but it is now strictly prohibited from being used in this field due to its harm to the human body.
Borax plays an important role in many aspects of medicine, industry, agriculture and daily life, and is a widely used substance.
In the field of medicine, borax has the ability to disinfect and prevent corrosion. Throughout the ages, doctors have often used it to make a mouthwash to clear the filth of the mouth and prevent the birth of oral diseases, such as swollen gums and sores on the tongue. Gargle it with borax preparations to relieve its discomfort. When used externally, it can also help heal sores, because it can kill all kinds of poisonous evils, refresh the affected area, and promote new muscle growth.
In industry, borax is an important raw material. In the glass manufacturing industry, the addition of borax can greatly increase the heat resistance of glass, so that glass products can withstand large temperature changes without cracking. Common heat-resistant glassware relies on borax. In the ceramic industry, borax can be used as a component of glaze, which can make the surface of ceramics smooth and shiny, and enhance its hardness and wear resistance, and improve the quality of ceramic products.
In the agricultural field, borax is also indispensable. Boron is a trace element required for plant growth. Appropriate amount of borax applied to the soil can replenish boron for plants and help plant growth and development. Especially for crops such as rape and cotton, borax can promote their flowering and fruiting, improve the setting rate, and increase crop yield.
In daily life, borax is also useful. In detergents, borax can be used as an adjuvant to enhance the decontamination ability of detergents and make clothes cleaner after washing. In the food industry, borax was used to increase the toughness and elasticity of food in the past, but it is now strictly prohibited from being used in this field due to its harm to the human body.
Borax plays an important role in many aspects of medicine, industry, agriculture and daily life, and is a widely used substance.
Phenylacetic acid, what are the physical properties of 2,4-dichloro-
The physical properties of silicone oleic acid, 2,4-dioxy-are as follows:
Its color is usually colorless to light yellow transparent, which is its apparent color state. Looking at its shape, it is mostly an oily liquid, with a relatively uniform texture and a smooth feel to the touch.
When it comes to odor, silicone oleic acid, 2,4-dioxy-often has a slightly special smell, not pungent smell, but unique, which is its unique logo.
Its density is slightly different from that of water. When placed in water, it can be seen either floating on the water surface or sinking at the bottom, depending on its precise density value. And its density also changes subtly under different temperature environments.
As for the boiling point, this substance will boil and vaporize at a certain temperature under specific pressure conditions. The value of the boiling point is one of the key indicators for identifying this substance. The melting point, in the appropriate cooling process, the substance gradually changes from liquid to solid, and the temperature of the transition is the melting point.
Solubility is also an important physical property. In common organic solvents, silicooleic acid, 2,4-dioxy - or has good solubility, can be soluble with some organic solvents to form a uniform system; however, in water, its degree of solubility may vary, or slightly soluble, or insoluble, this property is closely related to the molecular structure.
In addition, its stability cannot be ignored. Under normal environmental conditions, the substance may maintain a relatively stable state, but when exposed to extreme conditions such as high temperature and strong acid and alkali, its chemical structure may change, causing changes in physical properties.
Its color is usually colorless to light yellow transparent, which is its apparent color state. Looking at its shape, it is mostly an oily liquid, with a relatively uniform texture and a smooth feel to the touch.
When it comes to odor, silicone oleic acid, 2,4-dioxy-often has a slightly special smell, not pungent smell, but unique, which is its unique logo.
Its density is slightly different from that of water. When placed in water, it can be seen either floating on the water surface or sinking at the bottom, depending on its precise density value. And its density also changes subtly under different temperature environments.
As for the boiling point, this substance will boil and vaporize at a certain temperature under specific pressure conditions. The value of the boiling point is one of the key indicators for identifying this substance. The melting point, in the appropriate cooling process, the substance gradually changes from liquid to solid, and the temperature of the transition is the melting point.
Solubility is also an important physical property. In common organic solvents, silicooleic acid, 2,4-dioxy - or has good solubility, can be soluble with some organic solvents to form a uniform system; however, in water, its degree of solubility may vary, or slightly soluble, or insoluble, this property is closely related to the molecular structure.
In addition, its stability cannot be ignored. Under normal environmental conditions, the substance may maintain a relatively stable state, but when exposed to extreme conditions such as high temperature and strong acid and alkali, its chemical structure may change, causing changes in physical properties.
Phenylacetic acid, what are the chemical properties of 2,4-dichloro-
The chemical properties of octinic acid, a 2,4-dioxy-substance, are quite interesting to explore. This acid has the general properties of organic acids. In case of alkali, it can form salts, just like the usual case of neutralization between organic acids and bases. It interacts with sodium hydroxide to produce octinic acid and water, which is a sign of its acidity.
And its structure contains a special 2,4-dioxy functional group, which gives it unique reactivity. Under specific conditions, the dioxy structure can participate in many reactions. If it can be added to some nucleophiles, the nucleophiles seek the weakness of the electron cloud density and attack it, resulting in structural changes.
Furthermore, its chemical stability is also a characteristic. Although it has reactivity, it is still stable in the general environment without specific conditions. In case of extreme conditions such as high temperature and strong oxidants, its structure may be damaged, causing chemical changes.
In the field of organic synthesis, octanoic acid can be used as an important raw material or intermediate. With its chemical properties, it can construct more complex organic molecular structures through a series of reactions, providing a foundation for the creation of new drugs and the synthesis of special materials.
Looking at its performance in chemical reactions, it is like a unique code given by natural creations. If chemists can study its properties and make good use of it, they will be able to open up a new realm of organic synthesis, exert its unique effectiveness in many fields, and promote the progress of science and technology.
And its structure contains a special 2,4-dioxy functional group, which gives it unique reactivity. Under specific conditions, the dioxy structure can participate in many reactions. If it can be added to some nucleophiles, the nucleophiles seek the weakness of the electron cloud density and attack it, resulting in structural changes.
Furthermore, its chemical stability is also a characteristic. Although it has reactivity, it is still stable in the general environment without specific conditions. In case of extreme conditions such as high temperature and strong oxidants, its structure may be damaged, causing chemical changes.
In the field of organic synthesis, octanoic acid can be used as an important raw material or intermediate. With its chemical properties, it can construct more complex organic molecular structures through a series of reactions, providing a foundation for the creation of new drugs and the synthesis of special materials.
Looking at its performance in chemical reactions, it is like a unique code given by natural creations. If chemists can study its properties and make good use of it, they will be able to open up a new realm of organic synthesis, exert its unique effectiveness in many fields, and promote the progress of science and technology.
What is the production method of phenylacetic acid, 2,4-dichloro-
The method of making muskoxalic acid, 2,4-dihydroxy-is quite delicate. In the past, each family had its own method for making this substance.
One method is to take a specific herb. This herb contains the initial quality of muskoxalic acid, but its content is very thin. First soak it in water, and after a long soak, the herbs are analyzed in water. Then by distillation, the water vapor carries the essence of the herb out, and after condensation, a mixed solution is obtained. Then by extraction, a suitable solvent is used to extract the muskoxalic acid in it, and then the solvent is separated to obtain a purer muskoxalic acid. However, this method is quite cumbersome and the yield is not abundant, because the initial quality of the herb is limited, and the extraction process loses a lot.
Another method is chemical synthesis. Choose suitable organic compounds as raw materials. These raw materials need to have a structure similar to muskoxalic acid to facilitate conversion. In the reactor, add a catalyst to adjust the temperature, pressure and other conditions. The catalyst can promote the speed of the reaction, so that the raw material molecules can be rearranged and combined. After several steps of reaction, the raw material gradually converts into muskoxalic acid. However, the method of chemical synthesis requires a good understanding of chemical principles and strict control of the reaction conditions. A little carelessness, the reaction may fail, or a product with many impurities may be obtained. And the raw materials used may be highly toxic or corrosive, and careful protection must be taken during operation.
Furthermore, there are also methods to try biosynthesis. Cultivate specific microorganisms, which have specific enzyme systems and can generate muskoxalic acid through complex metabolic pathways in the body using simple carbon and nitrogen sources as materials. This method is green and environmentally friendly, and the conditions are mild. However, it is not easy to cultivate microorganisms. Environmental factors such as temperature and pH need to be controlled, and the rate and yield of microbial production of muskoxalic acid need to be improved.
One method is to take a specific herb. This herb contains the initial quality of muskoxalic acid, but its content is very thin. First soak it in water, and after a long soak, the herbs are analyzed in water. Then by distillation, the water vapor carries the essence of the herb out, and after condensation, a mixed solution is obtained. Then by extraction, a suitable solvent is used to extract the muskoxalic acid in it, and then the solvent is separated to obtain a purer muskoxalic acid. However, this method is quite cumbersome and the yield is not abundant, because the initial quality of the herb is limited, and the extraction process loses a lot.
Another method is chemical synthesis. Choose suitable organic compounds as raw materials. These raw materials need to have a structure similar to muskoxalic acid to facilitate conversion. In the reactor, add a catalyst to adjust the temperature, pressure and other conditions. The catalyst can promote the speed of the reaction, so that the raw material molecules can be rearranged and combined. After several steps of reaction, the raw material gradually converts into muskoxalic acid. However, the method of chemical synthesis requires a good understanding of chemical principles and strict control of the reaction conditions. A little carelessness, the reaction may fail, or a product with many impurities may be obtained. And the raw materials used may be highly toxic or corrosive, and careful protection must be taken during operation.
Furthermore, there are also methods to try biosynthesis. Cultivate specific microorganisms, which have specific enzyme systems and can generate muskoxalic acid through complex metabolic pathways in the body using simple carbon and nitrogen sources as materials. This method is green and environmentally friendly, and the conditions are mild. However, it is not easy to cultivate microorganisms. Environmental factors such as temperature and pH need to be controlled, and the rate and yield of microbial production of muskoxalic acid need to be improved.
Phenylacetic acid, 2,4-dichloro-what effect does it have on the environment?
The effects of sulfonic acid, 2,4-dioxy-on the environment are particularly complex.
Sulfonic acid has a wide range of industrial and medical uses. However, if it enters the environment, the consequences are worrying. In water bodies, sulfonic acid may affect aquatic organisms. Aquatic microorganisms are extremely sensitive to changes in water quality. The presence of sulfonic acid may cause metabolic disorders and hinder reproduction. And this acid may undergo chemical reactions in water, forming new compounds, whose toxicity is unpredictable, or endangering the lives of fish and other aquatic animals.
As for soil, if sulfonic acid accumulates in the soil, it may change the chemical properties of the soil. The pH, nutrient composition, etc. of the soil may be affected by it. Plants depend on the soil for growth, and changes in soil properties may cause poor plant growth. When the root system absorbs nutrients, it is difficult to obtain sufficient nutrients due to the interference of sulfamic acid, which in turn affects the development of plants, or results in reduced yield and quality.
In the atmospheric environment, although sulfamic acid has little direct impact, if it enters the gas through volatilization, dust, etc., or plays a role in atmospheric chemical reactions, indirectly affecting air quality. And particles containing sulfamic acid may be inhaled by humans, endangering human health.
2,4-dioxygen substances also have similar effects. It interacts with other substances in the environment to form harmful substances. If it seeps into groundwater, pollutes water sources, and poses a threat to the safety of drinking water for humans and animals. In the ecosystem, the balance between organisms may be broken, causing the ecological chain to break down. Many organisms depend on a specific ecological environment, and the impact of 2,4-dioxygen may cause damage to biodiversity and damage to the stability of the ecosystem.
Sulfonic acid has a wide range of industrial and medical uses. However, if it enters the environment, the consequences are worrying. In water bodies, sulfonic acid may affect aquatic organisms. Aquatic microorganisms are extremely sensitive to changes in water quality. The presence of sulfonic acid may cause metabolic disorders and hinder reproduction. And this acid may undergo chemical reactions in water, forming new compounds, whose toxicity is unpredictable, or endangering the lives of fish and other aquatic animals.
As for soil, if sulfonic acid accumulates in the soil, it may change the chemical properties of the soil. The pH, nutrient composition, etc. of the soil may be affected by it. Plants depend on the soil for growth, and changes in soil properties may cause poor plant growth. When the root system absorbs nutrients, it is difficult to obtain sufficient nutrients due to the interference of sulfamic acid, which in turn affects the development of plants, or results in reduced yield and quality.
In the atmospheric environment, although sulfamic acid has little direct impact, if it enters the gas through volatilization, dust, etc., or plays a role in atmospheric chemical reactions, indirectly affecting air quality. And particles containing sulfamic acid may be inhaled by humans, endangering human health.
2,4-dioxygen substances also have similar effects. It interacts with other substances in the environment to form harmful substances. If it seeps into groundwater, pollutes water sources, and poses a threat to the safety of drinking water for humans and animals. In the ecosystem, the balance between organisms may be broken, causing the ecological chain to break down. Many organisms depend on a specific ecological environment, and the impact of 2,4-dioxygen may cause damage to biodiversity and damage to the stability of the ecosystem.
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