Linshang Chemical
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3,4-Dichloro-Alpha-(Trichloromethyl)Benzenemethyl Acetate
Linshang Chemical
|
HS Code |
724019 |
| Chemical Formula | C10H7Cl5O2 |
| Molar Mass | 322.428 g/mol |
| Appearance | Typically a solid (physical state can vary based on conditions) |
| Boiling Point | Data may vary; generally high due to its molecular structure |
| Melting Point | Specific value depends on purity and experimental conditions |
| Solubility In Water | Low solubility as it is an organic compound with non - polar groups |
| Solubility In Organic Solvents | Soluble in common organic solvents like chloroform, benzene |
| Density | Density values are characteristic and related to its mass - volume ratio |
| Vapor Pressure | Low vapor pressure due to its relatively large and heavy molecule |
| Odor | May have a characteristic, somewhat pungent odor typical of chlorinated organic compounds |
As an accredited 3,4-Dichloro-Alpha-(Trichloromethyl)Benzenemethyl Acetate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 500 - gram bottles containing 3,4 - dichloro - α - (trichloromethyl)benzenemethyl Acetate, well - sealed. |
| Storage | 3,4 - dichloro - α - (trichloromethyl)benzenemethyl acetate should be stored in a cool, dry, well - ventilated area. Keep it away from heat sources, flames, and oxidizing agents. Store in a tightly sealed container to prevent leakage and vapor release. Avoid storing near food or beverages due to its potential toxicity. |
| Shipping | 3,4 - dichloro - α - (trichloromethyl)benzenemethyl Acetate is a chemical. Shipping should follow strict regulations. It must be properly packaged in corrosion - resistant containers, labeled clearly, and transported by carriers licensed for hazardous chemicals. |
Competitive 3,4-Dichloro-Alpha-(Trichloromethyl)Benzenemethyl Acetate prices that fit your budget—flexible terms and customized quotes for every order.
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Tel: +8615365006308
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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-Alpha-(Trichloromethyl)Benzenemethyl Acetate 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 3,4 - dichloro - alpha - (trichloromethyl) benzenemethyl Acetate
3,4-Dichloro - α - ( trichloromethyl) benzyl acetate, this is an organic compound. Its main use is often found in many fields in the field of chemical industry in the past.
First, in the field of pesticide preparation, this compound is often used as a key intermediate. In the past, in order to protect crops from pests, high-efficiency pesticides were required. This compound can be turned into a pesticide component with strong insecticidal effect after a series of delicate chemical reactions, which can precisely eliminate a variety of pests and protect the growth of farmland crops.
Second, in the field of materials science, it also has its application. In the manufacture of certain polymer materials with special properties, 3,4-dichloro - α - ( trichloromethyl) benzyl acetate can participate in the reaction, imparting properties such as better stability and corrosion resistance to the material. For example, the manufacture of protective materials for outdoor harsh environments, through its participation in the reaction, can resist wind, sun and rain for a long time, and maintain the performance and appearance of the material.
Third, in the field of organic synthetic chemistry, it is an important basic raw material. The synthesis of many complex organic compounds is based on this as a starting point. With its unique chemical structure and ingeniously designed reaction paths, chemists can construct organic molecules with diverse structures and functions, providing a key material basis for pharmaceutical research and development, fine chemical product manufacturing and other fields.
In short, 3,4-dichloro - α - ( trichloromethyl) benzyl acetate has played an important role in many fields such as chemical industry, agriculture, and materials in the past, promoting the development and progress of related industries.
First, in the field of pesticide preparation, this compound is often used as a key intermediate. In the past, in order to protect crops from pests, high-efficiency pesticides were required. This compound can be turned into a pesticide component with strong insecticidal effect after a series of delicate chemical reactions, which can precisely eliminate a variety of pests and protect the growth of farmland crops.
Second, in the field of materials science, it also has its application. In the manufacture of certain polymer materials with special properties, 3,4-dichloro - α - ( trichloromethyl) benzyl acetate can participate in the reaction, imparting properties such as better stability and corrosion resistance to the material. For example, the manufacture of protective materials for outdoor harsh environments, through its participation in the reaction, can resist wind, sun and rain for a long time, and maintain the performance and appearance of the material.
Third, in the field of organic synthetic chemistry, it is an important basic raw material. The synthesis of many complex organic compounds is based on this as a starting point. With its unique chemical structure and ingeniously designed reaction paths, chemists can construct organic molecules with diverse structures and functions, providing a key material basis for pharmaceutical research and development, fine chemical product manufacturing and other fields.
In short, 3,4-dichloro - α - ( trichloromethyl) benzyl acetate has played an important role in many fields such as chemical industry, agriculture, and materials in the past, promoting the development and progress of related industries.
What are the physical properties of 3,4 - dichloro - alpha - (trichloromethyl) benzenemethyl Acetate
3%2C4+-+dichloro+-+alpha+-+%28trichloromethyl%29benzenemethyl+Acetate that is, 3,4-dichloro - α - ( trichloromethyl) benzyl acetate, the physical properties of this thing, let me tell you in detail.
Looking at its shape, under normal conditions, or a colorless to light yellow liquid, the appearance is clear and translucent, without obvious impurities and turbidity, just like a clear spring, pure and clear.
Smell its smell, the smell may be irritating, but it is not pungent. This smell may suggest the vitality of its chemical structure, like a silent warning, reminding everyone of the special chemical properties of this thing.
In terms of its solubility, it exhibits good solubility in organic solvents, such as alcohols, ethers, aromatics, etc. Just like fish getting water, it is freely dispersed and integrated in the arms of these organic solvents. This property makes it more convenient to participate in and play a role in many organic reactions and industrial applications.
When it comes to density, compared to water, its density is higher. If it is placed in the same place as water, it will be like a stone sinking to the bottom of the water and living steadily in the lower layer. This property requires special attention and consideration during separation and storage.
Look at its boiling point and melting point. The boiling point may be in a specific temperature range. At this temperature, it will change from liquid to gaseous, opening the free journey of molecules; and the melting point also has its specific value. When the temperature drops below the melting point, it will solidify from liquid to solid, and the molecular arrangement will change from relatively free to regular and orderly, and the morphology will change significantly. These two values are of great significance for the control and application of its state in different temperature environments.
In addition, its stability is also an important physical property. Under normal conditions, without the interference of external special factors, such as high temperature, strong oxidants, strong acids and alkalis, etc., it can maintain a relatively stable state, and the molecular structure is not easily changed. Just like a calm person, it is not easily shaken by external trifles. However, once external conditions change drastically, its stability may be damaged, triggering a series of chemical reactions, which is a key point that cannot be ignored during use and storage.
Looking at its shape, under normal conditions, or a colorless to light yellow liquid, the appearance is clear and translucent, without obvious impurities and turbidity, just like a clear spring, pure and clear.
Smell its smell, the smell may be irritating, but it is not pungent. This smell may suggest the vitality of its chemical structure, like a silent warning, reminding everyone of the special chemical properties of this thing.
In terms of its solubility, it exhibits good solubility in organic solvents, such as alcohols, ethers, aromatics, etc. Just like fish getting water, it is freely dispersed and integrated in the arms of these organic solvents. This property makes it more convenient to participate in and play a role in many organic reactions and industrial applications.
When it comes to density, compared to water, its density is higher. If it is placed in the same place as water, it will be like a stone sinking to the bottom of the water and living steadily in the lower layer. This property requires special attention and consideration during separation and storage.
Look at its boiling point and melting point. The boiling point may be in a specific temperature range. At this temperature, it will change from liquid to gaseous, opening the free journey of molecules; and the melting point also has its specific value. When the temperature drops below the melting point, it will solidify from liquid to solid, and the molecular arrangement will change from relatively free to regular and orderly, and the morphology will change significantly. These two values are of great significance for the control and application of its state in different temperature environments.
In addition, its stability is also an important physical property. Under normal conditions, without the interference of external special factors, such as high temperature, strong oxidants, strong acids and alkalis, etc., it can maintain a relatively stable state, and the molecular structure is not easily changed. Just like a calm person, it is not easily shaken by external trifles. However, once external conditions change drastically, its stability may be damaged, triggering a series of chemical reactions, which is a key point that cannot be ignored during use and storage.
What are the chemical properties of 3,4 - dichloro - alpha - (trichloromethyl) benzenemethyl Acetate
3,4-Dichloro - α - ( trichloromethyl) benzyl acetate, which is an organic compound. Its chemical properties are unique and have certain stability and reactivity.
In terms of stability, the benzene ring, chlorine atom and ester group in the molecular structure endow it with relatively stable properties. The benzene ring conjugation system reduces the molecular energy and enhances the stability; the chlorine atom is highly electronegative. When connected to the benzene ring, it affects the electron cloud distribution through induction effect, which stabilizes the molecule to a certain extent. However, under extreme conditions such as high temperature and strong oxidizing agent, the stability will be affected.
In terms of reactivity, the ester group is the key reaction check point. Hydrolysis can occur, and ester bonds can be broken in acidic or alkaline environments. Under acidic conditions, the corresponding carboxylic acids and alcohols are hydrolyzed; under basic conditions, the hydrolysis is more thorough, and the carboxylic salts and alcohols are formed. At the same time, the electron cloud density of the carbon atom decreases due to the electron-absorbing effect of the chlorine atom, which is electrophilic and easy to react with nucleophilic reagents, such as nucleophilic substitution reactions. In addition, the chlorine atom on the benzene ring can also participate in specific substitution reactions. Under suitable catalyst and reaction conditions, the chlorine atom can be replaced by other groups.
In summary, the stability and reactivity of 3,4-dichloro - α - ( trichloromethyl) benzyl acetate coexist. In organic synthesis and related fields, the reaction conditions need to be reasonably controlled according to their chemical properties.
In terms of stability, the benzene ring, chlorine atom and ester group in the molecular structure endow it with relatively stable properties. The benzene ring conjugation system reduces the molecular energy and enhances the stability; the chlorine atom is highly electronegative. When connected to the benzene ring, it affects the electron cloud distribution through induction effect, which stabilizes the molecule to a certain extent. However, under extreme conditions such as high temperature and strong oxidizing agent, the stability will be affected.
In terms of reactivity, the ester group is the key reaction check point. Hydrolysis can occur, and ester bonds can be broken in acidic or alkaline environments. Under acidic conditions, the corresponding carboxylic acids and alcohols are hydrolyzed; under basic conditions, the hydrolysis is more thorough, and the carboxylic salts and alcohols are formed. At the same time, the electron cloud density of the carbon atom decreases due to the electron-absorbing effect of the chlorine atom, which is electrophilic and easy to react with nucleophilic reagents, such as nucleophilic substitution reactions. In addition, the chlorine atom on the benzene ring can also participate in specific substitution reactions. Under suitable catalyst and reaction conditions, the chlorine atom can be replaced by other groups.
In summary, the stability and reactivity of 3,4-dichloro - α - ( trichloromethyl) benzyl acetate coexist. In organic synthesis and related fields, the reaction conditions need to be reasonably controlled according to their chemical properties.
3,4 - dichloro - alpha - (trichloromethyl) benzenemethyl Acetate in the production process
3,4-Dichloro - α - ( trichloromethyl) benzyl acetate has a number of important precautions to pay attention to during production.
First, it is related to the selection and treatment of materials. For the synthesis of this compound, the raw materials must be strictly selected, the purity must meet the standard, and the content of impurities must be precisely controlled. If the raw materials contain too many impurities, the reaction process will be disturbed, and the product quality will not meet expectations. And when the raw materials are stored and used, they should be properly disposed of according to their characteristics. Measures such as moisture prevention and oxidation prevention are essential to prevent the deterioration of raw materials and affect product output.
Second, the regulation of reaction conditions is crucial. Temperature, pressure, reaction time, and catalyst dosage all have a profound impact on the reaction direction and product yield. If the temperature is too high or too low, the reaction can deviate from the normal track, or the reaction rate can be too slow, or side reactions can be triggered, which will increase the formation of impurities. The control of pressure should not be underestimated, and the appropriate pressure can ensure that the reaction can be carried out in a suitable environment. The accuracy of the catalyst dosage depends on whether the reaction can be efficiently advanced, the dosage is improper, or the catalytic effect is poor, or the cost rises unnecessarily.
Third, the safe production must not be forgotten. This compound may be toxic and corrosive to a certain extent, and the production site must be well ventilated to prevent the accumulation of harmful gases and endanger the health of operators. Staff should also wear protective equipment strictly, such as protective clothing, gloves, goggles, etc., to avoid direct contact. At the same time, for emergencies that may occur during the production process, such as leaks, fires, etc., it is necessary to prepare equipment emergency plans to ensure complete planning.
Fourth, the separation and purification of the product is also a key link. After the reaction is completed, the product is often mixed with impurities, and it is necessary to use appropriate separation and purification methods to obtain high-purity products. Methods such as distillation, extraction, crystallization, etc. should be reasonably selected according to the nature difference between the product and the impurities to ensure that the product quality meets the standards.
First, it is related to the selection and treatment of materials. For the synthesis of this compound, the raw materials must be strictly selected, the purity must meet the standard, and the content of impurities must be precisely controlled. If the raw materials contain too many impurities, the reaction process will be disturbed, and the product quality will not meet expectations. And when the raw materials are stored and used, they should be properly disposed of according to their characteristics. Measures such as moisture prevention and oxidation prevention are essential to prevent the deterioration of raw materials and affect product output.
Second, the regulation of reaction conditions is crucial. Temperature, pressure, reaction time, and catalyst dosage all have a profound impact on the reaction direction and product yield. If the temperature is too high or too low, the reaction can deviate from the normal track, or the reaction rate can be too slow, or side reactions can be triggered, which will increase the formation of impurities. The control of pressure should not be underestimated, and the appropriate pressure can ensure that the reaction can be carried out in a suitable environment. The accuracy of the catalyst dosage depends on whether the reaction can be efficiently advanced, the dosage is improper, or the catalytic effect is poor, or the cost rises unnecessarily.
Third, the safe production must not be forgotten. This compound may be toxic and corrosive to a certain extent, and the production site must be well ventilated to prevent the accumulation of harmful gases and endanger the health of operators. Staff should also wear protective equipment strictly, such as protective clothing, gloves, goggles, etc., to avoid direct contact. At the same time, for emergencies that may occur during the production process, such as leaks, fires, etc., it is necessary to prepare equipment emergency plans to ensure complete planning.
Fourth, the separation and purification of the product is also a key link. After the reaction is completed, the product is often mixed with impurities, and it is necessary to use appropriate separation and purification methods to obtain high-purity products. Methods such as distillation, extraction, crystallization, etc. should be reasonably selected according to the nature difference between the product and the impurities to ensure that the product quality meets the standards.
What are the environmental effects of 3,4 - dichloro - alpha - (trichloromethyl) benzenemethyl Acetate
3,4-Dichloro - α - ( trichloromethyl) benzyl acetate, the impact of this substance on the environment needs to be investigated in detail.
This substance has unique chemical properties. In the natural environment, or due to the complex chemical structure, it is difficult to be easily decomposed by microorganisms. If released into the soil in large quantities, it may accumulate gradually. Soil is the foundation of all things, and fertility and ecological balance are maintained here. The accumulation of this substance may interfere with the normal activities of soil microorganisms, which in turn affects the soil's aggregate structure and nutrient cycle, causing soil fertility to decline and endangering plant growth.
If it flows into the water body, it should not be underestimated. Water is the source of life and aquatic organisms depend on it for survival. This substance may have toxic effects on aquatic organisms such as fish and plankton, interfering with their normal physiological functions, such as respiration and reproduction. Long-term accumulation may cause a sharp decrease in the number of aquatic organisms and destroy the balance of aquatic ecosystems.
In the atmospheric environment, although its volatilization may be limited, it cannot be ignored. If it enters the atmosphere through volatilization, or participates in photochemical reactions, it will generate secondary pollutants, which will have a negative impact on air quality and endanger human health and surrounding ecology.
In summary, 3,4-dichloro - α - ( trichloromethyl) benzyl acetate in the environment, due to its own characteristics, has potential harm to soil, water, atmosphere and other environmental factors, and needs to be treated with caution to ensure the harmony and stability of the ecological environment.
This substance has unique chemical properties. In the natural environment, or due to the complex chemical structure, it is difficult to be easily decomposed by microorganisms. If released into the soil in large quantities, it may accumulate gradually. Soil is the foundation of all things, and fertility and ecological balance are maintained here. The accumulation of this substance may interfere with the normal activities of soil microorganisms, which in turn affects the soil's aggregate structure and nutrient cycle, causing soil fertility to decline and endangering plant growth.
If it flows into the water body, it should not be underestimated. Water is the source of life and aquatic organisms depend on it for survival. This substance may have toxic effects on aquatic organisms such as fish and plankton, interfering with their normal physiological functions, such as respiration and reproduction. Long-term accumulation may cause a sharp decrease in the number of aquatic organisms and destroy the balance of aquatic ecosystems.
In the atmospheric environment, although its volatilization may be limited, it cannot be ignored. If it enters the atmosphere through volatilization, or participates in photochemical reactions, it will generate secondary pollutants, which will have a negative impact on air quality and endanger human health and surrounding ecology.
In summary, 3,4-dichloro - α - ( trichloromethyl) benzyl acetate in the environment, due to its own characteristics, has potential harm to soil, water, atmosphere and other environmental factors, and needs to be treated with caution to ensure the harmony and stability of the ecological environment.
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