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1-(Chloromethyl)-4-[2-(Trimethoxysilyl)Ethyl]Benzene
Linshang Chemical
|
HS Code |
345655 |
| Chemical Formula | C12H20O3SiCl |
| Molecular Weight | 276.83 |
| Appearance | Colorless to light yellow liquid |
| Boiling Point | Around 283 - 285 °C |
| Density | Approx. 1.07 - 1.09 g/cm³ |
| Solubility | Soluble in organic solvents like toluene, xylene |
| Vapor Pressure | Low vapor pressure |
| Flash Point | Around 110 - 115 °C |
| Refractive Index | Approx. 1.48 - 1.50 |
As an accredited 1-(Chloromethyl)-4-[2-(Trimethoxysilyl)Ethyl]Benzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100g of 1-(chloromethyl)-4-[2-(trimethoxysilyl)ethyl]benzene in sealed chemical - grade bottle. |
| Storage | 1-(Chloromethyl)-4-[2-(trimethoxysilyl)ethyl]benzene should be stored in a cool, dry, well - ventilated area, away from heat sources and open flames. Keep it in a tightly sealed container to prevent exposure to moisture and air, which could lead to hydrolysis of the silyl groups. Store separately from incompatible substances such as strong oxidizers, bases, and moisture - sensitive compounds. |
| Shipping | 1-(Chloromethyl)-4-[2-(trimethoxysilyl)ethyl]benzene is shipped in well - sealed, corrosion - resistant containers. Strict adherence to hazardous chemical shipping regulations ensures safe transport, minimizing risks during transit. |
Competitive 1-(Chloromethyl)-4-[2-(Trimethoxysilyl)Ethyl]Benzene prices that fit your budget—flexible terms and customized quotes for every order.
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What is the main use of 1- (chloromethyl) -4- [2- (trimethoxysilyl) ethyl] benzene?
1-% (deuteromethyl) -4- [2- (trimethoxysilyl) ethyl] benzene, which is widely used in industry and scientific research.
In the field of organic synthesis, it is often used as a key intermediate. By virtue of specific functional groups within the molecule, such as silicon groups and phenyl rings, it can be modified by various chemical reactions. Trimethoxysilyl is highly reactive and can react with many compounds containing active hydrogen, such as alcohols and phenols, under appropriate conditions to form silicon ether derivatives. This property allows chemists to construct complex organosilicon compounds, providing a variety of possibilities for the development of organic synthesis chemistry.
In the field of materials science, 1-% (deuteromethyl) -4- [2- (trimethoxysilyl) ethyl] benzene also plays an important role. The trimethoxysilyl group can be hydrolyzed and condensed to form a siloxane network structure. Therefore, the compound can be used to prepare organic-inorganic hybrid materials. Such hybrid materials integrate the advantages of organic and inorganic materials, or have excellent mechanical properties, thermal stability and chemical stability, showing broad application prospects in coatings, adhesives, composites and other fields.
In addition, due to the presence of benzene rings in the structure, the molecule is endowed with a certain conjugate system, resulting in the compound may have special optical and electrical properties. Therefore, in the field of optoelectronic materials, it may be used as a potential functional material for the preparation of optoelectronic devices such as Light Emitting Diodes and solar cells, contributing to the progress of new energy and optoelectronics.
In the field of organic synthesis, it is often used as a key intermediate. By virtue of specific functional groups within the molecule, such as silicon groups and phenyl rings, it can be modified by various chemical reactions. Trimethoxysilyl is highly reactive and can react with many compounds containing active hydrogen, such as alcohols and phenols, under appropriate conditions to form silicon ether derivatives. This property allows chemists to construct complex organosilicon compounds, providing a variety of possibilities for the development of organic synthesis chemistry.
In the field of materials science, 1-% (deuteromethyl) -4- [2- (trimethoxysilyl) ethyl] benzene also plays an important role. The trimethoxysilyl group can be hydrolyzed and condensed to form a siloxane network structure. Therefore, the compound can be used to prepare organic-inorganic hybrid materials. Such hybrid materials integrate the advantages of organic and inorganic materials, or have excellent mechanical properties, thermal stability and chemical stability, showing broad application prospects in coatings, adhesives, composites and other fields.
In addition, due to the presence of benzene rings in the structure, the molecule is endowed with a certain conjugate system, resulting in the compound may have special optical and electrical properties. Therefore, in the field of optoelectronic materials, it may be used as a potential functional material for the preparation of optoelectronic devices such as Light Emitting Diodes and solar cells, contributing to the progress of new energy and optoelectronics.
What are the physical properties of 1- (chloromethyl) -4- [2- (trimethoxysilyl) ethyl] benzene?
(This substance) is called 1- (cyanomethyl) -4- [2- (trimethylsiloxy) ethyl] benzene, which is an organic compound. Its physical properties are quite unique, and let me tell them one by one.
Looking at its appearance, under room temperature and pressure, it is mostly in the form of a colorless and transparent liquid, clear and pure, just like a clear spring, flowing under the light with a clear luster.
When it comes to smell, it has a special aromatic smell, like a faint flower fragrance, but it is also unique, lingering on the tip of the nose, which is impressive.
Besides, its boiling point, after rigorous calculation, is about a certain temperature range, which makes it gradually change from liquid to gaseous state, just like the wonders of sublimation. The characteristics of this boiling point play a crucial role in many process operations such as separation and purification, just like the compass of a ship, guiding the direction of operation.
The melting point also has a fixed number. Under a specific low temperature environment, the substance condenses from liquid to solid state, just like water when cooled into ice, showing a different form. The value of the melting point provides a key basis for studying the change of its physical state under different temperature conditions.
As for solubility, this compound exhibits good solubility in organic solvents, like a fish in water. It can blend with many organic solvents to form a uniform and stable system. However, in water, it is insoluble as a stone, as if it is incompatible with water. This difference in solubility is of great significance in the selection of suitable solvents in chemical production and scientific research experiments to achieve specific reaction or separation goals.
In terms of density, it has its own inherent value. Although it is invisible and colorless, it shows its own existence with a unique sense of weight. The characteristics of its density play a role that cannot be ignored in the process of mixing and delamination of substances, just like the weight of the balance, accurately affecting the relationship between substances. The physical properties of 1- (cyanomethyl) -4- [2- (trimethoxysilyl) ethyl] benzene play a pivotal role in many fields such as chemical engineering and scientific research, just like a cornerstone in a high-rise building, laying a solid foundation for the development of related work.
Looking at its appearance, under room temperature and pressure, it is mostly in the form of a colorless and transparent liquid, clear and pure, just like a clear spring, flowing under the light with a clear luster.
When it comes to smell, it has a special aromatic smell, like a faint flower fragrance, but it is also unique, lingering on the tip of the nose, which is impressive.
Besides, its boiling point, after rigorous calculation, is about a certain temperature range, which makes it gradually change from liquid to gaseous state, just like the wonders of sublimation. The characteristics of this boiling point play a crucial role in many process operations such as separation and purification, just like the compass of a ship, guiding the direction of operation.
The melting point also has a fixed number. Under a specific low temperature environment, the substance condenses from liquid to solid state, just like water when cooled into ice, showing a different form. The value of the melting point provides a key basis for studying the change of its physical state under different temperature conditions.
As for solubility, this compound exhibits good solubility in organic solvents, like a fish in water. It can blend with many organic solvents to form a uniform and stable system. However, in water, it is insoluble as a stone, as if it is incompatible with water. This difference in solubility is of great significance in the selection of suitable solvents in chemical production and scientific research experiments to achieve specific reaction or separation goals.
In terms of density, it has its own inherent value. Although it is invisible and colorless, it shows its own existence with a unique sense of weight. The characteristics of its density play a role that cannot be ignored in the process of mixing and delamination of substances, just like the weight of the balance, accurately affecting the relationship between substances. The physical properties of 1- (cyanomethyl) -4- [2- (trimethoxysilyl) ethyl] benzene play a pivotal role in many fields such as chemical engineering and scientific research, just like a cornerstone in a high-rise building, laying a solid foundation for the development of related work.
Is the chemical properties of 1- (chloromethyl) -4- [2- (trimethoxysilyl) ethyl] benzene stable?
Both of them are groups of organic compounds, but the analysis of their stability needs to be viewed from multiple aspects.
First, (cyanomethyl), the cyanyl group (-CN) in its structure has strong electron-withdrawing properties. When connected to methyl group, the electron-withdrawing induction effect of cyanyl group can reduce the density of the linked carbon electron cloud. Although methyl group has electron-induced effect, the electron-withdrawing effect of cyanyl group is weaker than that of cyanyl group. The change of electron cloud distribution makes the carbon linked to cyanyl group in the (cyanomethyl) group more vulnerable to attack by nucleophiles, so its stability is not good from the perspective of electronic effect.
Looking at [2- (trimethoxycarbonyl) ethyl] phenyl, the structure of this group is more complex. Trimethoxycarbonyl has a certain electron-absorbing property, which can affect the distribution of ethyl electron clouds connected to it. However, ethyl is connected to phenyl, and phenyl is a conjugated system, which can disperse electrons through conjugation effect and enhance the stability of the system. And the steric resistance between trimethoxycarbonyl and ethyl and phenyl also affects the stability of the group. Large steric resistance can make the group form a specific conformation in space, which can hinder the attack of external reagents to a certain extent, thereby enhancing the stability.
Overall, [2 - (trimethoxycarbonyl) ethyl] benzene gene conjugation effect and steric resistance are better than (cyanomethyl) stability. However, the stability of the compound is also affected by the environment such as temperature, solvent and other factors, and the actual situation may be more complicated.
First, (cyanomethyl), the cyanyl group (-CN) in its structure has strong electron-withdrawing properties. When connected to methyl group, the electron-withdrawing induction effect of cyanyl group can reduce the density of the linked carbon electron cloud. Although methyl group has electron-induced effect, the electron-withdrawing effect of cyanyl group is weaker than that of cyanyl group. The change of electron cloud distribution makes the carbon linked to cyanyl group in the (cyanomethyl) group more vulnerable to attack by nucleophiles, so its stability is not good from the perspective of electronic effect.
Looking at [2- (trimethoxycarbonyl) ethyl] phenyl, the structure of this group is more complex. Trimethoxycarbonyl has a certain electron-absorbing property, which can affect the distribution of ethyl electron clouds connected to it. However, ethyl is connected to phenyl, and phenyl is a conjugated system, which can disperse electrons through conjugation effect and enhance the stability of the system. And the steric resistance between trimethoxycarbonyl and ethyl and phenyl also affects the stability of the group. Large steric resistance can make the group form a specific conformation in space, which can hinder the attack of external reagents to a certain extent, thereby enhancing the stability.
Overall, [2 - (trimethoxycarbonyl) ethyl] benzene gene conjugation effect and steric resistance are better than (cyanomethyl) stability. However, the stability of the compound is also affected by the environment such as temperature, solvent and other factors, and the actual situation may be more complicated.
What are the applications of 1- (chloromethyl) -4- [2- (trimethoxysilyl) ethyl] benzene in synthesis?
(1- (methoxy) -4- [2- (trimethylacetyl) ethyl] benzene has the following main applications in synthesis:
First, in the field of medicinal chemistry, this compound can be used as a key intermediate. Due to its unique chemical structure, it can construct a molecular structure with specific pharmacological activities through a series of reactions. For example, it can be modified by functional groups to connect different active groups of benzene rings to synthesize drugs targeting specific disease targets. For example, in the development of some anti-tumor drugs, this compound may be used as a starting material to construct drug molecules specifically bound to tumor cell targets through precise chemical synthesis, providing an important path for the creation of cancer treatment drugs.
Second, in the field of materials science, (1- (methoxy) -4- [2- (trimethylacetyl) ethyl] benzene also has potential applications. It can participate in the synthesis process of polymer materials, and by virtue of its structural properties, it endows polymer materials with special properties. For example, when preparing optical materials, introducing it into the main chain or side chain of the polymer may change the optical properties of the material, such as improving the transparency of the material, adjusting the refractive index, etc., so as to meet the special performance requirements of optical materials such as optical lenses and optical fibers.
Third, in organic synthesis chemistry, it can be used as a characteristic structural unit to construct more complex organic molecules. Due to its multiple reactive check points, chemists can gradually expand the molecular framework and synthesize organic compounds with unique structures and functions by using various organic reactions, such as nucleophilic substitution reactions and coupling reactions, according to specific designs.)
First, in the field of medicinal chemistry, this compound can be used as a key intermediate. Due to its unique chemical structure, it can construct a molecular structure with specific pharmacological activities through a series of reactions. For example, it can be modified by functional groups to connect different active groups of benzene rings to synthesize drugs targeting specific disease targets. For example, in the development of some anti-tumor drugs, this compound may be used as a starting material to construct drug molecules specifically bound to tumor cell targets through precise chemical synthesis, providing an important path for the creation of cancer treatment drugs.
Second, in the field of materials science, (1- (methoxy) -4- [2- (trimethylacetyl) ethyl] benzene also has potential applications. It can participate in the synthesis process of polymer materials, and by virtue of its structural properties, it endows polymer materials with special properties. For example, when preparing optical materials, introducing it into the main chain or side chain of the polymer may change the optical properties of the material, such as improving the transparency of the material, adjusting the refractive index, etc., so as to meet the special performance requirements of optical materials such as optical lenses and optical fibers.
Third, in organic synthesis chemistry, it can be used as a characteristic structural unit to construct more complex organic molecules. Due to its multiple reactive check points, chemists can gradually expand the molecular framework and synthesize organic compounds with unique structures and functions by using various organic reactions, such as nucleophilic substitution reactions and coupling reactions, according to specific designs.)
What is the preparation method of 1- (chloromethyl) -4- [2- (trimethoxysilyl) ethyl] benzene?
To make a 1-%28%E6%B0%AF%E7%94%B2%E5%9F%BA%29-4-%5B2-%28%E4%B8%89%E7%94%B2%E6%B0%A7%E5%9F%BA%E7%A1%85%E5%9F%BA%29%E4%B9%99%E5%9F%BA%5D%E8%8B%AF, the method is as follows:
Prepare all the things you need first, and choose a clean one for the field. Take an appropriate amount of starting materials, which should be pure and free of impurities, in order to ensure the quality of the product. According to the ancient method, it is necessary to first clean the dust, wash it with water, and then wipe it dry with a cloth.
Then, in a special kettle, add the starting materials, and gradually heat it up. The heat is the key, do not be too hasty, and do not be too slow. If the raw materials are urgent, they are easy to burn, and if they are slow, they are time-consuming and useless. When the raw materials are slightly soft, add a specific auxiliary agent. The formula of this agent is obtained from the research of the ancestors over the ages, and has the effect of catalysis and reconciliation.
When the raw material is mixed with the agent, stir evenly to make it fully react. At this time, there is a strange color change and gas generation in the kettle, which are all signs of reaction. Keep stirring, observe its changes, and adjust the heat in a timely manner. It may increase or decrease, depending on the experience and eyesight of the operator.
When the reaction is gradually completed, the state of the kettle is gradually stable, the color is warm, and the breath is peaceful. At this time, stop the fire, and pour the product obtained in the kettle into a special mold. The mold needs to be coated with thin oil in advance to prevent adhesion. When it is cooled and formed, this 1-%28%E6%B0%AF%E7%94%B2%E5%9F%BA%29-4-%5B2-%28%E4%B8%89%E7%94%B2%E6%B0%A7%E5%9F%BA%E7%A1%85%E5%9F%BA%29%E4%B9%99%E5%9F%BA%5D%E8%8B%AF can be prepared.
After it is made, it needs to be carefully inspected. Looking at its appearance, when it is regular and complete; looking at its internal quality, it should be pure and uniform. If there is a flaw, it needs to be remade according to the recipe. In this way, you will get a good thing.
Prepare all the things you need first, and choose a clean one for the field. Take an appropriate amount of starting materials, which should be pure and free of impurities, in order to ensure the quality of the product. According to the ancient method, it is necessary to first clean the dust, wash it with water, and then wipe it dry with a cloth.
Then, in a special kettle, add the starting materials, and gradually heat it up. The heat is the key, do not be too hasty, and do not be too slow. If the raw materials are urgent, they are easy to burn, and if they are slow, they are time-consuming and useless. When the raw materials are slightly soft, add a specific auxiliary agent. The formula of this agent is obtained from the research of the ancestors over the ages, and has the effect of catalysis and reconciliation.
When the raw material is mixed with the agent, stir evenly to make it fully react. At this time, there is a strange color change and gas generation in the kettle, which are all signs of reaction. Keep stirring, observe its changes, and adjust the heat in a timely manner. It may increase or decrease, depending on the experience and eyesight of the operator.
When the reaction is gradually completed, the state of the kettle is gradually stable, the color is warm, and the breath is peaceful. At this time, stop the fire, and pour the product obtained in the kettle into a special mold. The mold needs to be coated with thin oil in advance to prevent adhesion. When it is cooled and formed, this 1-%28%E6%B0%AF%E7%94%B2%E5%9F%BA%29-4-%5B2-%28%E4%B8%89%E7%94%B2%E6%B0%A7%E5%9F%BA%E7%A1%85%E5%9F%BA%29%E4%B9%99%E5%9F%BA%5D%E8%8B%AF can be prepared.
After it is made, it needs to be carefully inspected. Looking at its appearance, when it is regular and complete; looking at its internal quality, it should be pure and uniform. If there is a flaw, it needs to be remade according to the recipe. In this way, you will get a good thing.
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