Linshang Chemical
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1-(2-Chloroethyl)-4-Methoxybenzene
Linshang Chemical
|
HS Code |
160060 |
| Chemical Formula | C9H11ClO |
| Molar Mass | 170.64 g/mol |
As an accredited 1-(2-Chloroethyl)-4-Methoxybenzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100g of 1-(2 - chloroethyl)-4-methoxybenzene packaged in a sealed, labeled bottle. |
| Storage | 1-(2 - chloroethyl)-4 - methoxybenzene should be stored in a cool, dry, well - ventilated area. Keep it away from heat sources, open flames, and oxidizing agents. Store in a tightly sealed container to prevent leakage and vapor release. Since it is a chemical, proper labeling is essential for easy identification and to ensure safe handling. |
| Shipping | 1-(2 - chloroethyl)-4 - methoxybenzene is shipped in sealed, corrosion - resistant containers. Shipment follows strict chemical transportation regulations to ensure safety during transit, avoiding exposure to heat, moisture, and incompatible substances. |
Competitive 1-(2-Chloroethyl)-4-Methoxybenzene 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 1-(2-Chloroethyl)-4-Methoxybenzene 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 1- (2-chloroethyl) -4 -methoxybenzene?
1 - (2 - cyanoethyl) - 4 - methoxyphenyl silicone oil has a wide range of main uses. This silicone oil has unique physical and chemical properties and has important applications in many fields.
In the textile field, it can be used as a fabric finishing agent. It can endow fabrics with many excellent characteristics, such as soft touch, making fabrics smoother and more comfortable to touch, like caressing clouds, with high texture; and can enhance the anti-wrinkle performance of fabrics, so that fabrics can still remain flat and crisp after daily wear and washing, just like when they were first made; it can also improve the waterproof performance of fabrics, making water droplets roll off the surface of fabrics, just like the water repellent of lotus leaves, greatly enhancing the durability and practicality of fabrics.
In the leather industry, 1- (2-cyanoethyl) -4-methoxyphenyl silicone oil also plays a key role. It can be used as a leather finishing agent to form a uniform and tough protective film on the surface of the leather, which can not only improve the gloss of the leather, but also make the leather glow with a warm and elegant luster, just like a treasure that has been deposited over time. It can also enhance the wear resistance of the leather, prolong the service life of the leather, make it not easy to damage in daily use, and maintain good appearance and quality.
In the field of cosmetics, this silicone oil has become an important raw material for many cosmetics due to its good lubrication and breathability. In skin care products, it can make skin care products easier to apply and evenly cover the surface of the skin, just like putting a light and breathable "invisibility cloak" on the skin, while helping the skin absorb nutrients, keeping the skin hydrated and smooth; in makeup products, it can improve the ductility and durability of the product, make the makeup more docile and long-lasting, not easy to take off makeup, and allow users to maintain delicate makeup at all times.
In addition, in plastics, rubber and other industries, 1- (2-cyanoethyl) -4-methoxyphenyl silicone oil can be used as a processing aid. It can improve the processing performance of plastics and rubber, reduce the friction between materials and equipment during processing, make the processing process smoother, improve production efficiency, and improve the physical properties of products, such as enhancing product flexibility, weather resistance, etc., and broaden the application range of products.
In the textile field, it can be used as a fabric finishing agent. It can endow fabrics with many excellent characteristics, such as soft touch, making fabrics smoother and more comfortable to touch, like caressing clouds, with high texture; and can enhance the anti-wrinkle performance of fabrics, so that fabrics can still remain flat and crisp after daily wear and washing, just like when they were first made; it can also improve the waterproof performance of fabrics, making water droplets roll off the surface of fabrics, just like the water repellent of lotus leaves, greatly enhancing the durability and practicality of fabrics.
In the leather industry, 1- (2-cyanoethyl) -4-methoxyphenyl silicone oil also plays a key role. It can be used as a leather finishing agent to form a uniform and tough protective film on the surface of the leather, which can not only improve the gloss of the leather, but also make the leather glow with a warm and elegant luster, just like a treasure that has been deposited over time. It can also enhance the wear resistance of the leather, prolong the service life of the leather, make it not easy to damage in daily use, and maintain good appearance and quality.
In the field of cosmetics, this silicone oil has become an important raw material for many cosmetics due to its good lubrication and breathability. In skin care products, it can make skin care products easier to apply and evenly cover the surface of the skin, just like putting a light and breathable "invisibility cloak" on the skin, while helping the skin absorb nutrients, keeping the skin hydrated and smooth; in makeup products, it can improve the ductility and durability of the product, make the makeup more docile and long-lasting, not easy to take off makeup, and allow users to maintain delicate makeup at all times.
In addition, in plastics, rubber and other industries, 1- (2-cyanoethyl) -4-methoxyphenyl silicone oil can be used as a processing aid. It can improve the processing performance of plastics and rubber, reduce the friction between materials and equipment during processing, make the processing process smoother, improve production efficiency, and improve the physical properties of products, such as enhancing product flexibility, weather resistance, etc., and broaden the application range of products.
What are the physical properties of 1- (2 -chloroethyl) -4 -methoxybenzene?
(1) This substance is called 1- (2-cyanoethyl) -4-methoxyphenyl sulfone. Its physical properties are diverse, and it is useful for those who are familiar with alchemy methods and physical properties.
(2) In terms of appearance, it is often in the state of white to slightly yellow crystalline powder, just like winter snow, delicate and pure, and like a light yellow stamen, with a light color. Under sunlight, its surface is slightly glowing, as if it contains fine stars, flashing with subtle light.
(3) The melting point is quite critical, about a certain temperature range, this temperature is like a cardinal of physical properties change. When the temperature is gradually near the melting point, this thing will wake up like a sleeping thing, and the solid shape will begin to melt, from solid to soft, just like ice melting in a spring stream, slowly changing. This melting point characteristic can be the basis for accurate temperature control in many refining and blending techniques, which is related to success or failure.
(4) Solubility is also an important physical property. In some organic solvents, this substance, such as salt, dissolves in water, quietly disperses, and uniformly dissolves. It can be dissolved in specific organic liquids, such as alcohols, ethers, and other partial solvents, just like fish entering rivers and swimming freely. This solubility provides the possibility of dispersion and fusion when blending various formulas and medicinal pills, and can make all ingredients uniformly mixed and play an effective role.
(5) In terms of stability, under the environment of room temperature and no special disturbance, this object is like a hermit in the mountains, safe and quiet, stable in nature, and does not easily change with the surrounding objects. However, in case of extreme conditions such as high temperature, strong acid and alkali, it will be subject to sudden changes in the situation, and its structure and properties may change, such as burning wood, making it difficult to maintain the initial state. Knowing this stability, alchemists can create a suitable environment when refining and storing, and keep their physical properties intact.
(2) In terms of appearance, it is often in the state of white to slightly yellow crystalline powder, just like winter snow, delicate and pure, and like a light yellow stamen, with a light color. Under sunlight, its surface is slightly glowing, as if it contains fine stars, flashing with subtle light.
(3) The melting point is quite critical, about a certain temperature range, this temperature is like a cardinal of physical properties change. When the temperature is gradually near the melting point, this thing will wake up like a sleeping thing, and the solid shape will begin to melt, from solid to soft, just like ice melting in a spring stream, slowly changing. This melting point characteristic can be the basis for accurate temperature control in many refining and blending techniques, which is related to success or failure.
(4) Solubility is also an important physical property. In some organic solvents, this substance, such as salt, dissolves in water, quietly disperses, and uniformly dissolves. It can be dissolved in specific organic liquids, such as alcohols, ethers, and other partial solvents, just like fish entering rivers and swimming freely. This solubility provides the possibility of dispersion and fusion when blending various formulas and medicinal pills, and can make all ingredients uniformly mixed and play an effective role.
(5) In terms of stability, under the environment of room temperature and no special disturbance, this object is like a hermit in the mountains, safe and quiet, stable in nature, and does not easily change with the surrounding objects. However, in case of extreme conditions such as high temperature, strong acid and alkali, it will be subject to sudden changes in the situation, and its structure and properties may change, such as burning wood, making it difficult to maintain the initial state. Knowing this stability, alchemists can create a suitable environment when refining and storing, and keep their physical properties intact.
What are the chemical properties of 1- (2 -chloroethyl) -4 -methoxybenzene?
The chemical properties of 1- (2-hydroxyethyl) -4-methoxybenzene are as follows:
This compound has unique chemical properties. In its structure, the hydroxyl group of hydroxyethyl group is hydrophilic and can participate in the formation of hydrogen bonds. It interacts with water molecules or other molecules with hydrogen bond receptors or donors, which affects its solubility and intermolecular forces in polar solvents. For example, in alcoholic solvents, the hydroxy group forms hydrogen bonds with solvent molecules, which can make it have good solubility.
Methoxy group acts as a power supply group, which affects the electron cloud density of the benzene ring through conjugation effect and induction effect. It increases the density of the electron cloud of the benzene ring o and para-position, and is more prone to electrophilic substitution. Such as with halogenated hydrocarbons under the action of appropriate catalysts, alkylation reactions can occur on benzene rings, and electrophilic reagents are more inclined to attack methoxy ortho and para-sites.
The whole molecule has certain stability and rigidity due to the presence of benzene rings, which affects its physical properties, such as relatively high melting point and boiling point. At the same time, this rigid structure also affects the spatial arrangement and conformation of molecules, which in turn affects their mutual recognition and reactivity with other molecules.
In addition, hydroxyl groups can be oxidized, and different oxidation products such as aldehyde groups and carboxyl groups can be formed according to different oxidation conditions. Under the action of appropriate oxidants such as mild Dess-Martin oxidants, hydroxyl groups can be oxidized to aldehyde groups to achieve functional group conversion, which is used to construct more complex organic compounds. Methoxy groups can also undergo demethylation reaction under specific conditions, releasing methyl groups, providing the possibility for further structural modification.
This compound is rich in chemical properties and is widely used in organic synthesis, medicinal chemistry and other fields. Through the understanding and utilization of its chemical properties, the synthesis of various compounds and the preparation of functional materials can be realized.
This compound has unique chemical properties. In its structure, the hydroxyl group of hydroxyethyl group is hydrophilic and can participate in the formation of hydrogen bonds. It interacts with water molecules or other molecules with hydrogen bond receptors or donors, which affects its solubility and intermolecular forces in polar solvents. For example, in alcoholic solvents, the hydroxy group forms hydrogen bonds with solvent molecules, which can make it have good solubility.
Methoxy group acts as a power supply group, which affects the electron cloud density of the benzene ring through conjugation effect and induction effect. It increases the density of the electron cloud of the benzene ring o and para-position, and is more prone to electrophilic substitution. Such as with halogenated hydrocarbons under the action of appropriate catalysts, alkylation reactions can occur on benzene rings, and electrophilic reagents are more inclined to attack methoxy ortho and para-sites.
The whole molecule has certain stability and rigidity due to the presence of benzene rings, which affects its physical properties, such as relatively high melting point and boiling point. At the same time, this rigid structure also affects the spatial arrangement and conformation of molecules, which in turn affects their mutual recognition and reactivity with other molecules.
In addition, hydroxyl groups can be oxidized, and different oxidation products such as aldehyde groups and carboxyl groups can be formed according to different oxidation conditions. Under the action of appropriate oxidants such as mild Dess-Martin oxidants, hydroxyl groups can be oxidized to aldehyde groups to achieve functional group conversion, which is used to construct more complex organic compounds. Methoxy groups can also undergo demethylation reaction under specific conditions, releasing methyl groups, providing the possibility for further structural modification.
This compound is rich in chemical properties and is widely used in organic synthesis, medicinal chemistry and other fields. Through the understanding and utilization of its chemical properties, the synthesis of various compounds and the preparation of functional materials can be realized.
What are the synthesis methods of 1- (2-chloroethyl) -4 -methoxybenzene?
To make 1 - (2 - cyanoethyl) - 4 - methoxybenzene, the synthesis method is so delicate, let me go one by one.
One method can be used as the starting material of methoxybenzene. First make it and halogenated cyanoethane under suitable conditions, catalyzed by alkali, carry out nucleophilic substitution. In this process, the power of base can activate the aromatic ring of methoxybenzene, and the halogen atom of halogenated cyanoethane is active. The halogen atom leaves, and the cyanoethyl group connects to the benzene ring to obtain 1 - (2 - cyanoethyl) - 4 - methoxybenzene. At the time of reaction, the temperature, time and amount of alkali need to be precisely controlled. If the temperature is too high, or side reactions will occur; if the temperature is too low, the reaction will be slow and the yield will not be high. If the time is too short, the reaction will not be completed; if the time is too long, it will consume resources. Too much alkali may damage the substrate; if the amount of alkali is too small, the catalysis will be insufficient.
The second method can first construct the benzene ring structure. Appropriate phenolic compounds and reagents containing methoxy and cyanoethyl groups can be used to gradually splice into rings with the help of specific catalysts in the context of condensation reactions. Among them, the choice of catalyst is crucial, and its activity and selectivity are all related to the purity and yield of the product. The reaction environment also needs to be carefully created, and the conditions of anhydrous and oxygen-free may be necessary to prevent the deterioration of the substrate and intermediate.
The third method uses halogenated anisole as the starting material. First, it is combined with metal reagents, such as magnesium, to make Grignard's reagent. Then, the Grignard reagent is reacted with a carbonyl compound containing cyanoethyl group, and through a series of transformations, the synthesis of the target product can also be achieved. In this process, the preparation of Grignard's reagent needs to be careful. It is extremely sensitive to water and oxygen, and it will fail if it is not careful. Subsequent reactions with carbonyl compounds also need to be selected at a time to control the reaction process.
In the process of synthesis, each method has its advantages and disadvantages, and it needs to be selected according to the actual situation, such as the availability of raw materials, cost considerations, and product purity requirements. Careful operation can achieve satisfactory results.
One method can be used as the starting material of methoxybenzene. First make it and halogenated cyanoethane under suitable conditions, catalyzed by alkali, carry out nucleophilic substitution. In this process, the power of base can activate the aromatic ring of methoxybenzene, and the halogen atom of halogenated cyanoethane is active. The halogen atom leaves, and the cyanoethyl group connects to the benzene ring to obtain 1 - (2 - cyanoethyl) - 4 - methoxybenzene. At the time of reaction, the temperature, time and amount of alkali need to be precisely controlled. If the temperature is too high, or side reactions will occur; if the temperature is too low, the reaction will be slow and the yield will not be high. If the time is too short, the reaction will not be completed; if the time is too long, it will consume resources. Too much alkali may damage the substrate; if the amount of alkali is too small, the catalysis will be insufficient.
The second method can first construct the benzene ring structure. Appropriate phenolic compounds and reagents containing methoxy and cyanoethyl groups can be used to gradually splice into rings with the help of specific catalysts in the context of condensation reactions. Among them, the choice of catalyst is crucial, and its activity and selectivity are all related to the purity and yield of the product. The reaction environment also needs to be carefully created, and the conditions of anhydrous and oxygen-free may be necessary to prevent the deterioration of the substrate and intermediate.
The third method uses halogenated anisole as the starting material. First, it is combined with metal reagents, such as magnesium, to make Grignard's reagent. Then, the Grignard reagent is reacted with a carbonyl compound containing cyanoethyl group, and through a series of transformations, the synthesis of the target product can also be achieved. In this process, the preparation of Grignard's reagent needs to be careful. It is extremely sensitive to water and oxygen, and it will fail if it is not careful. Subsequent reactions with carbonyl compounds also need to be selected at a time to control the reaction process.
In the process of synthesis, each method has its advantages and disadvantages, and it needs to be selected according to the actual situation, such as the availability of raw materials, cost considerations, and product purity requirements. Careful operation can achieve satisfactory results.
What are the precautions for storing and transporting 1- (2-chloroethyl) -4 -methoxybenzene?
1 - (2 -hydroxyethyl) - 4 -methoxybenzyl should pay attention to the following matters during storage and transportation:
First, because of its chemical properties, it must be stored in a cool, dry and well-ventilated place. Humid environment can easily cause it to react with moisture, affecting quality; high temperature may cause chemical changes, or cause material decomposition, deterioration, and even potential safety risks.
Second, keep away from fire and heat sources. This substance may be flammable, and it is easy to burn in case of open flames and hot topics. In severe cases, it may cause fires. Therefore, smoking and hot work are strictly prohibited in the storage area, and suitable fire equipment should be equipped at the same time.
Third, it needs to be stored separately from oxidants, acids, alkalis, etc. Due to its chemical structure characteristics, violent chemical reactions may occur in contact with these substances, resulting in dangerous conditions such as explosions, toxic gases, etc.
Fourth, during transportation, it is necessary to ensure that the packaging is complete and sealed. Avoid material leakage caused by package damage, which will not only cause material loss, but also cause pollution to the environment, and contact with the human body may also endanger health.
Fifth, the means of transportation should have good sun protection, rain protection, and high temperature protection measures. Prevent direct sunlight and rain, maintain a suitable transportation environment, and avoid changes in material properties due to environmental factors.
Sixth, the operator must receive professional training and strictly follow the operating procedures. Whether it is handling during storage, stacking, or loading and unloading during transportation, standardizing the operation can prevent safety accidents caused by improper operation.
First, because of its chemical properties, it must be stored in a cool, dry and well-ventilated place. Humid environment can easily cause it to react with moisture, affecting quality; high temperature may cause chemical changes, or cause material decomposition, deterioration, and even potential safety risks.
Second, keep away from fire and heat sources. This substance may be flammable, and it is easy to burn in case of open flames and hot topics. In severe cases, it may cause fires. Therefore, smoking and hot work are strictly prohibited in the storage area, and suitable fire equipment should be equipped at the same time.
Third, it needs to be stored separately from oxidants, acids, alkalis, etc. Due to its chemical structure characteristics, violent chemical reactions may occur in contact with these substances, resulting in dangerous conditions such as explosions, toxic gases, etc.
Fourth, during transportation, it is necessary to ensure that the packaging is complete and sealed. Avoid material leakage caused by package damage, which will not only cause material loss, but also cause pollution to the environment, and contact with the human body may also endanger health.
Fifth, the means of transportation should have good sun protection, rain protection, and high temperature protection measures. Prevent direct sunlight and rain, maintain a suitable transportation environment, and avoid changes in material properties due to environmental factors.
Sixth, the operator must receive professional training and strictly follow the operating procedures. Whether it is handling during storage, stacking, or loading and unloading during transportation, standardizing the operation can prevent safety accidents caused by improper operation.
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