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1-Bromo-3-Chloro-2-(Methylsulfanyl)Benzene
Linshang Chemical
|
HS Code |
724240 |
| Name | 1-Bromo-3-Chloro-2-(Methylsulfanyl)Benzene |
| Molecular Formula | C7H6BrClS |
| Molecular Weight | 237.54 |
| Appearance | Typically a liquid (state depends on conditions) |
| Boiling Point | Data may vary, around 250 - 270 °C (est.) |
| Density | Data may vary, around 1.6 - 1.7 g/cm³ (est.) |
| Solubility In Water | Low solubility, organic compound is hydrophobic |
| Solubility In Organic Solvents | Soluble in common organic solvents like ethanol, acetone |
| Flash Point | Data may vary, potentially flammable, flash point around 100 - 120 °C (est.) |
| Purity | Varies depending on source, can be high purity for lab - grade products |
As an accredited 1-Bromo-3-Chloro-2-(Methylsulfanyl)Benzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100 - gram bottles of 1 - bromo - 3 - chloro - 2 - (methylsulfanyl)benzene, tightly sealed. |
| Storage | 1 - Bromo - 3 - chloro - 2 - (methylsulfanyl)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 vapor escape. Store it separately from oxidizing agents and reactive substances to avoid potential chemical reactions. Ensure proper labeling for easy identification. |
| Shipping | 1 - bromo - 3 - chloro - 2 - (methylsulfanyl)benzene is shipped in accordance with strict chemical transportation regulations. It's packaged securely in appropriate containers to prevent leakage during transit, ensuring safety. |
Competitive 1-Bromo-3-Chloro-2-(Methylsulfanyl)Benzene prices that fit your budget—flexible terms and customized quotes for every order.
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Where to Buy 1-Bromo-3-Chloro-2-(Methylsulfanyl)Benzene in China?
As a trusted 1-Bromo-3-Chloro-2-(Methylsulfanyl)Benzene manufacturer, we deliver:
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As a leading 1-Bromo-3-Chloro-2-(Methylsulfanyl)Benzene 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 physical properties of 1-bromo-3-chloro-2- (methylthio) benzene?
1-% mercury-3-oxy-2- (methylphenyl) silicon, which is a strange compound with unique physical properties. Its color state, at room temperature, is often colorless and transparent oily liquid, under sunlight, slightly glowing, like a hidden treasure in the mundane world, its texture is warm and flowing freely, and it has a slippery feeling to touch.
When it comes to volatility, it has moderate volatility. In an open environment, it will slowly dissipate into the surrounding air, but its volatilization rate is slower than that of common light solvents. This property makes it stable in a specific process, and it can gradually evaporate when needed to achieve the desired effect.
Boiling point is also one of the key properties. After repeated measurements by many parties, its boiling point is quite high, about several hundred degrees. This high boiling point means that in order to make it boil and vaporize, a large amount of heat energy needs to be applied, so it can maintain liquid stability under normal temperature environments, providing a reliable raw material or medium for many high temperature processes.
As for solubility, it is particularly outstanding in organic solvents. Such as toluene and xylene from aromatics, chloroform and dichloromethane from halogenated hydrocarbons can be miscible with it, just like water and emulsion. This good solubility makes it an excellent dispersion medium in the preparation of composites, coatings and other fields, helping to uniformly mix different substances to achieve the expected performance.
In addition, the density of 1-% mercury-3-oxo-2- (methylphenyl) silicon is slightly higher than that of water. When placed in water, it will slowly settle, such as a pearl sinking abyss. And it has certain chemical stability. In common acid-base environments, it is not easy to undergo violent chemical reactions in a short time. When encountering strong oxidizing or reducing agents, it still needs to be handled with caution to prevent unexpected chemical changes.
When it comes to volatility, it has moderate volatility. In an open environment, it will slowly dissipate into the surrounding air, but its volatilization rate is slower than that of common light solvents. This property makes it stable in a specific process, and it can gradually evaporate when needed to achieve the desired effect.
Boiling point is also one of the key properties. After repeated measurements by many parties, its boiling point is quite high, about several hundred degrees. This high boiling point means that in order to make it boil and vaporize, a large amount of heat energy needs to be applied, so it can maintain liquid stability under normal temperature environments, providing a reliable raw material or medium for many high temperature processes.
As for solubility, it is particularly outstanding in organic solvents. Such as toluene and xylene from aromatics, chloroform and dichloromethane from halogenated hydrocarbons can be miscible with it, just like water and emulsion. This good solubility makes it an excellent dispersion medium in the preparation of composites, coatings and other fields, helping to uniformly mix different substances to achieve the expected performance.
In addition, the density of 1-% mercury-3-oxo-2- (methylphenyl) silicon is slightly higher than that of water. When placed in water, it will slowly settle, such as a pearl sinking abyss. And it has certain chemical stability. In common acid-base environments, it is not easy to undergo violent chemical reactions in a short time. When encountering strong oxidizing or reducing agents, it still needs to be handled with caution to prevent unexpected chemical changes.
What are the chemical properties of 1-bromo-3-chloro-2- (methylthio) benzene?
1-%-3--2- (methylsilyl) ether is a chemical compound, and its properties are special.
In this compound, the silicon atom is located in the methyl group and exists as an ether. As far as physical properties are concerned, it usually has a certain degree of stability. Due to the resistance of the ether, the molecular force is not high, and it is often liquid or low-melt solid. Under normal conditions, it can be observed that it has a certain degree of evaporation in a dense container.
And chemical properties, first of all, its silicon-oxygen properties have a certain activity. Due to the different properties of silicon and oxygen, it is vulnerable to nuclear attack. For example, in an aqueous solution such as oxidization, silicon-oxides may crack to form phase siloxides and alcoholic compounds.
Furthermore, the methyl moiety is not completely inert. Under suitable reaction conditions, methyl groups can be substituted for antibodies. If there are antibodies, the atom on the methyl group may be substituted by the atom. This process often requires the help of catalysis. For example, some gold compounds can be catalyzed, which can change the reaction rate and make the reaction easier to perform.
In addition, 1-% 3-3-2- (methylsilyl) ethers are also important in the synthesis of antibodies. Due to their unique properties, they can be used as silicon-based support groups to protect certain sensitive functions. In the synthesis of molecules, it is first used to maintain a specific function until other reactions are completed, and then the appropriate components are removed from the silicon base to restore the original activity of the function. This property makes it useful in the field of synthesis.
In this compound, the silicon atom is located in the methyl group and exists as an ether. As far as physical properties are concerned, it usually has a certain degree of stability. Due to the resistance of the ether, the molecular force is not high, and it is often liquid or low-melt solid. Under normal conditions, it can be observed that it has a certain degree of evaporation in a dense container.
And chemical properties, first of all, its silicon-oxygen properties have a certain activity. Due to the different properties of silicon and oxygen, it is vulnerable to nuclear attack. For example, in an aqueous solution such as oxidization, silicon-oxides may crack to form phase siloxides and alcoholic compounds.
Furthermore, the methyl moiety is not completely inert. Under suitable reaction conditions, methyl groups can be substituted for antibodies. If there are antibodies, the atom on the methyl group may be substituted by the atom. This process often requires the help of catalysis. For example, some gold compounds can be catalyzed, which can change the reaction rate and make the reaction easier to perform.
In addition, 1-% 3-3-2- (methylsilyl) ethers are also important in the synthesis of antibodies. Due to their unique properties, they can be used as silicon-based support groups to protect certain sensitive functions. In the synthesis of molecules, it is first used to maintain a specific function until other reactions are completed, and then the appropriate components are removed from the silicon base to restore the original activity of the function. This property makes it useful in the field of synthesis.
What is the synthesis method of 1-bromo-3-chloro-2- (methylthio) benzene?
To prepare 1-hydroxyl-3-alkane-2- (methylsilyl) naphthalene, the method is as follows:
First take an appropriate amount of naphthalene as the starting material, in a specific reaction vessel, under suitable reaction conditions, add the corresponding reagent, so that the naphthalene substitution reaction occurs, and a specific group is introduced at a specific position to obtain an intermediate product. This step requires attention to the reaction temperature, time and reagent ratio to avoid side reactions.
Then, transfer the intermediate product to another reaction system, add a reagent that can introduce a silicon group, and through careful regulation of the reaction conditions, the silicon group is successfully integrated to generate a silicon-containing intermediate compound. This process requires a high reaction environment and needs to maintain the purity and stability of the system. In addition, the intermediate compounds containing silicon groups are further processed, and suitable hydroxylation reagents and alkylation reagents are used to carry out the hydroxylation and alkylation reactions in sequence. During the hydroxylation reaction, the reaction rate and degree need to be controlled to ensure that the hydroxyl groups are accurately connected to the target position; the same is true for the alkylation reaction, and the reagent activity and reaction selectivity need to be paid attention to, and finally 1-hydroxyl-3-alkane-2 - (methylsilyl) naphthalene is obtained.
Throughout the synthesis process, each step of the reaction requires fine operation, strict control of reaction conditions, including temperature, pressure, reaction time, reagent purity and dosage, etc. Each step of the product must be carefully separated and purified to improve the purity and yield of the product, so that the target product can be obtained.
First take an appropriate amount of naphthalene as the starting material, in a specific reaction vessel, under suitable reaction conditions, add the corresponding reagent, so that the naphthalene substitution reaction occurs, and a specific group is introduced at a specific position to obtain an intermediate product. This step requires attention to the reaction temperature, time and reagent ratio to avoid side reactions.
Then, transfer the intermediate product to another reaction system, add a reagent that can introduce a silicon group, and through careful regulation of the reaction conditions, the silicon group is successfully integrated to generate a silicon-containing intermediate compound. This process requires a high reaction environment and needs to maintain the purity and stability of the system. In addition, the intermediate compounds containing silicon groups are further processed, and suitable hydroxylation reagents and alkylation reagents are used to carry out the hydroxylation and alkylation reactions in sequence. During the hydroxylation reaction, the reaction rate and degree need to be controlled to ensure that the hydroxyl groups are accurately connected to the target position; the same is true for the alkylation reaction, and the reagent activity and reaction selectivity need to be paid attention to, and finally 1-hydroxyl-3-alkane-2 - (methylsilyl) naphthalene is obtained.
Throughout the synthesis process, each step of the reaction requires fine operation, strict control of reaction conditions, including temperature, pressure, reaction time, reagent purity and dosage, etc. Each step of the product must be carefully separated and purified to improve the purity and yield of the product, so that the target product can be obtained.
In which fields is 1-bromo-3-chloro-2- (methylthio) benzene used?
1-% mercury-3-% arsenic-2- (methylphenyl) ether, a highly toxic chemical, is strictly controlled in many fields, and its "application" is rarely mentioned. However, in some very special and strictly regulated fields, there may be very limited involvement:
First, in the field of chemical analysis of scientific research, because of its unique chemical properties, it can be used as a reagent for specific analytical experiments. For example, in some experiments that accurately determine the content of specific elements, it may be used as a tracer to determine the presence and content of specific groups or elements in certain complex compounds through its special reaction. However, this application requires top experimental conditions and professional operation, and a slight mistake will lead to disaster.
Second, in some very rare industrial production processes in the past, such as the synthesis of certain types of high-end materials, it was theoretically or envisaged to use it as a reaction intermediate, with its special structure to guide the reaction in a specific direction, in order to prepare materials with special properties. However, most of these ideas are due to high safety risks and other relatively safe alternatives, and few are actually put into large-scale production applications.
Third, in the very cutting-edge field of pharmaceutical research and development, some researchers may have considered its special chemical structure to explore whether it can be used for the design of targeted drugs after specific modifications. However, due to the high toxicity of mercury, arsenic and other elements, this exploration faces great challenges, and the progress is extremely slow, and more are in the theoretical and preliminary experimental stage.
Overall, due to their high toxicity and great harm to the environment and human health, most countries and regions implement strict regulations on the use, storage, and transportation of such mercury and arsenic compounds, and their application scope is narrowed to a very small and highly professional and strictly regulated field.
First, in the field of chemical analysis of scientific research, because of its unique chemical properties, it can be used as a reagent for specific analytical experiments. For example, in some experiments that accurately determine the content of specific elements, it may be used as a tracer to determine the presence and content of specific groups or elements in certain complex compounds through its special reaction. However, this application requires top experimental conditions and professional operation, and a slight mistake will lead to disaster.
Second, in some very rare industrial production processes in the past, such as the synthesis of certain types of high-end materials, it was theoretically or envisaged to use it as a reaction intermediate, with its special structure to guide the reaction in a specific direction, in order to prepare materials with special properties. However, most of these ideas are due to high safety risks and other relatively safe alternatives, and few are actually put into large-scale production applications.
Third, in the very cutting-edge field of pharmaceutical research and development, some researchers may have considered its special chemical structure to explore whether it can be used for the design of targeted drugs after specific modifications. However, due to the high toxicity of mercury, arsenic and other elements, this exploration faces great challenges, and the progress is extremely slow, and more are in the theoretical and preliminary experimental stage.
Overall, due to their high toxicity and great harm to the environment and human health, most countries and regions implement strict regulations on the use, storage, and transportation of such mercury and arsenic compounds, and their application scope is narrowed to a very small and highly professional and strictly regulated field.
What are the storage conditions for 1-bromo-3-chloro-2- (methylthio) benzene?
1-% -3-% nitrate-2- (methylphenyl) ether should be stored in the dark. It is sensitive to its nature, and it is easy to melt when exposed to light, radiation, vibration or oxidation. Therefore, it should be carefully hidden.
The first one should be placed in a dark place. Light, especially ultraviolet light, can excite its molecules, activate its chemical properties, cause decomposition or cause other damage. Hidden in the dark, it can be exposed to light and its shadow, and its integrity should be maintained.
times, its degree should be controlled. This compound is easy to decompose, so it should be stored in the dark, so it should not exceed 20 degrees Celsius.
In addition, the shock-proof device should also be used. Its sensitivity can be broken by strong shocks, which can be reversed, or the danger of explosion can be generated.
In addition, 1-% -3-% nitrate-2- (methylphenyl) ether storage parts need to be dark, cool, shockproof and protected from oxidation, so as to ensure their safety and avoid accidents.
The first one should be placed in a dark place. Light, especially ultraviolet light, can excite its molecules, activate its chemical properties, cause decomposition or cause other damage. Hidden in the dark, it can be exposed to light and its shadow, and its integrity should be maintained.
times, its degree should be controlled. This compound is easy to decompose, so it should be stored in the dark, so it should not exceed 20 degrees Celsius.
In addition, the shock-proof device should also be used. Its sensitivity can be broken by strong shocks, which can be reversed, or the danger of explosion can be generated.
In addition, 1-% -3-% nitrate-2- (methylphenyl) ether storage parts need to be dark, cool, shockproof and protected from oxidation, so as to ensure their safety and avoid accidents.
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