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Benzenethiosulfonic Acid S-Trichloromethyl Ester
Linshang Chemical
|
HS Code |
817187 |
| Chemical Formula | C7H5Cl3O2S2 |
| Molar Mass | 277.507 g/mol |
As an accredited Benzenethiosulfonic Acid S-Trichloromethyl Ester factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100g of Benzenethiosulfonic Acid S - trichloromethyl Ester in a sealed chemical - grade bottle. |
| Storage | Benzenethiosulfonic Acid S - trichloromethyl Ester should be stored in a cool, dry, well - ventilated area, away from heat sources and open flames. It should be kept in a tightly sealed container to prevent moisture and air exposure, which could lead to decomposition. Store it separately from incompatible substances like oxidizing agents to avoid potential reactions. |
| Shipping | Benzenethiosulfonic Acid S - trichloromethyl Ester is shipped in accordance with strict chemical transport regulations. It's packaged securely in corrosion - resistant containers to prevent leakage during transit, ensuring safety. |
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What is the use of S-trichloromethyl benzene thiosulfonate?
Borax-substituted alkaline acid S-trichloromethane, although it is not detailed in ancient books, its use is quite extensive today.
Borax-substituted alkaline acid S-trichloromethane, in the printing and dyeing industry, has significant effect. It can be a mordant, and the aid dye is closely combined with the fabric, so that the color is uniform and firm. The color of dyeing is fresh for a long time and does not fade easily. Therefore, printing and dyeing craftsmen often rely on it to make exquisite fabrics.
It is also useful in the field of medicine. It has certain disinfection and sterilization ability, and can be used for wound cleaning, preventing infection, and protecting the human body from minor diseases. Doctors use it occasionally when dealing with trauma, but the dosage and method of use need to be carefully considered to prevent damage to the body.
In the field of chemical experiments, borax-substituted alkaline acid S-trichloromethane is also indispensable. It can be a reaction solvent, providing a suitable environment for many chemical reactions, and promoting smooth and efficient reactions. Chemists use its characteristics to explore the mysteries of substances and reveal the laws of chemical changes.
In industrial manufacturing, it can also be seen. In the synthesis of some special materials, it can be used as a catalyst or auxiliary agent to accelerate the reaction process, optimize material properties, and improve the efficiency and quality of industrial production. The manufacture of auxiliary devices is more sophisticated.
Although borax-substituted alkaline acid S-trichloromethane has various uses, its properties may pose certain hazards. When using it, it is necessary to strictly abide by the procedures and operate cautiously to achieve the purpose of making good use of its benefits and avoiding its drawbacks.
Borax-substituted alkaline acid S-trichloromethane, in the printing and dyeing industry, has significant effect. It can be a mordant, and the aid dye is closely combined with the fabric, so that the color is uniform and firm. The color of dyeing is fresh for a long time and does not fade easily. Therefore, printing and dyeing craftsmen often rely on it to make exquisite fabrics.
It is also useful in the field of medicine. It has certain disinfection and sterilization ability, and can be used for wound cleaning, preventing infection, and protecting the human body from minor diseases. Doctors use it occasionally when dealing with trauma, but the dosage and method of use need to be carefully considered to prevent damage to the body.
In the field of chemical experiments, borax-substituted alkaline acid S-trichloromethane is also indispensable. It can be a reaction solvent, providing a suitable environment for many chemical reactions, and promoting smooth and efficient reactions. Chemists use its characteristics to explore the mysteries of substances and reveal the laws of chemical changes.
In industrial manufacturing, it can also be seen. In the synthesis of some special materials, it can be used as a catalyst or auxiliary agent to accelerate the reaction process, optimize material properties, and improve the efficiency and quality of industrial production. The manufacture of auxiliary devices is more sophisticated.
Although borax-substituted alkaline acid S-trichloromethane has various uses, its properties may pose certain hazards. When using it, it is necessary to strictly abide by the procedures and operate cautiously to achieve the purpose of making good use of its benefits and avoiding its drawbacks.
What are the physical properties of S-trichloromethyl benzene thiosulfonate?
The physical properties of S-trifluoromethylhydrazine are density, melting point, boiling point, solubility and stability.
In terms of its density, this substance contains fluorine atoms due to its molecular structure. For fluorine, the atomic weight is small and the electronegativity is strong, resulting in a special intermolecular force, and its density is different from that of ordinary organic compounds. Usually, the density of fluorine-containing organic compounds often varies with the number and distribution of fluorine atoms. According to its structure, density or range, the exact value of S-trifluoromethylhydrazine needs to be tested experimentally.
As for the melting point, the interatomic bonding and intermolecular force in the molecule of the compound are controlled together. The silicon germanium element participates in bonding, interacts with carbon, nitrogen, fluorine and other elements, so that the molecular lattice structure has its own characteristics. And the introduction of trifluoromethyl increases the distance between molecules and affects the force, so the melting point may be different from that of common organic hydrazines, or at a certain temperature range, which also needs to be investigated experimentally.
At one end of the boiling point, intermolecular forces such as van der Waals force and hydrogen bond play a key role. Although there is no typical strong hydrogen bond in this substance, the fluorine atom has a large electronegativity, which can cause a strong dipole-dipole force between molecules. In addition, silicon germanium participates in the molecular structure, so that its boiling point presents a specific value, which may rise or fall compared with ordinary fluorine-free hydrazines. The real value depends on the experiment.
In terms of solubility, "similar miscibility" is the law. This compound has both elements such as silicon germanium and trifluoromethyl, and its polarity is different from that of common organic solvents. In polar solvents, the solubility may be limited due to the different matching degree of molecular polarity and solvent; in non-polar solvents, although trifluoromethyl has a certain degree of non-polarity, it affects the overall molecular structure and solubility. The type and temperature of organic solvents can be controlled.
In terms of stability, the bond properties of silicon germanium-carbon, silicon germanium-nitrogen and the stability of trifluoromethyl are all important factors. Silicon germanium bonds with surrounding atoms, and its bond energy affects the resistance of compounds to heat and chemical reagents. Trifluoromethyl has strong electron absorption and can stabilize the molecular structure. However, under specific conditions, such as high temperature, strong acid and alkali, strong oxidizing agents, etc., it may cause reactions such as chemical bond cracking and rearrangement, causing its stability to be broken.
In terms of its density, this substance contains fluorine atoms due to its molecular structure. For fluorine, the atomic weight is small and the electronegativity is strong, resulting in a special intermolecular force, and its density is different from that of ordinary organic compounds. Usually, the density of fluorine-containing organic compounds often varies with the number and distribution of fluorine atoms. According to its structure, density or range, the exact value of S-trifluoromethylhydrazine needs to be tested experimentally.
As for the melting point, the interatomic bonding and intermolecular force in the molecule of the compound are controlled together. The silicon germanium element participates in bonding, interacts with carbon, nitrogen, fluorine and other elements, so that the molecular lattice structure has its own characteristics. And the introduction of trifluoromethyl increases the distance between molecules and affects the force, so the melting point may be different from that of common organic hydrazines, or at a certain temperature range, which also needs to be investigated experimentally.
At one end of the boiling point, intermolecular forces such as van der Waals force and hydrogen bond play a key role. Although there is no typical strong hydrogen bond in this substance, the fluorine atom has a large electronegativity, which can cause a strong dipole-dipole force between molecules. In addition, silicon germanium participates in the molecular structure, so that its boiling point presents a specific value, which may rise or fall compared with ordinary fluorine-free hydrazines. The real value depends on the experiment.
In terms of solubility, "similar miscibility" is the law. This compound has both elements such as silicon germanium and trifluoromethyl, and its polarity is different from that of common organic solvents. In polar solvents, the solubility may be limited due to the different matching degree of molecular polarity and solvent; in non-polar solvents, although trifluoromethyl has a certain degree of non-polarity, it affects the overall molecular structure and solubility. The type and temperature of organic solvents can be controlled.
In terms of stability, the bond properties of silicon germanium-carbon, silicon germanium-nitrogen and the stability of trifluoromethyl are all important factors. Silicon germanium bonds with surrounding atoms, and its bond energy affects the resistance of compounds to heat and chemical reagents. Trifluoromethyl has strong electron absorption and can stabilize the molecular structure. However, under specific conditions, such as high temperature, strong acid and alkali, strong oxidizing agents, etc., it may cause reactions such as chemical bond cracking and rearrangement, causing its stability to be broken.
What are the chemical properties of S-trichloromethyl benzene thiosulfonate?
The chemical properties of borax substitute acid S-trifluoromethanesulfonic acid are particularly important and affect the characteristics of many applications.
This acid is strongly acidic, and its acidity is even more than that of common inorganic acids. It can be used as a high-efficiency catalyst in the field of organic synthesis, which can significantly accelerate the process of many reactions. Due to its strong acidity, it can make the substrate more prone to protonation and promote the improvement of reaction activity, such as esterification reaction, alkylation reaction, etc. With its catalysis, it can often obtain high yield and good selectivity.
And the acid has good thermal stability. Under high temperature environment, its chemical structure can also be maintained stable and not easily decomposed. This property allows it to play a catalytic role stably in reactions that require high temperature conditions, and is not affected by large temperature fluctuations, ensuring a smooth and orderly reaction.
In addition, its solubility is also characterized, and it can be soluble in many organic solvents, which provides convenience for organic synthesis. In a homogeneous reaction system, it can be fully contacted with the substrate and distributed evenly, making the reaction easier to control, and the quality and purity of the product are also more easily guaranteed.
However, there are also points to be noted. Strong acidity makes it corrosive. Extra caution must be taken during operation to prevent damage to equipment and people. Strict specifications must be followed for access and storage, and appropriate protective measures must be used to ensure the safety of the experiment. In short, acid S-trifluoromethanesulfonic acid has unique chemical properties and has considerable application value in organic synthesis and other fields. It only needs to be properly controlled to avoid risks and make the best use of it.
This acid is strongly acidic, and its acidity is even more than that of common inorganic acids. It can be used as a high-efficiency catalyst in the field of organic synthesis, which can significantly accelerate the process of many reactions. Due to its strong acidity, it can make the substrate more prone to protonation and promote the improvement of reaction activity, such as esterification reaction, alkylation reaction, etc. With its catalysis, it can often obtain high yield and good selectivity.
And the acid has good thermal stability. Under high temperature environment, its chemical structure can also be maintained stable and not easily decomposed. This property allows it to play a catalytic role stably in reactions that require high temperature conditions, and is not affected by large temperature fluctuations, ensuring a smooth and orderly reaction.
In addition, its solubility is also characterized, and it can be soluble in many organic solvents, which provides convenience for organic synthesis. In a homogeneous reaction system, it can be fully contacted with the substrate and distributed evenly, making the reaction easier to control, and the quality and purity of the product are also more easily guaranteed.
However, there are also points to be noted. Strong acidity makes it corrosive. Extra caution must be taken during operation to prevent damage to equipment and people. Strict specifications must be followed for access and storage, and appropriate protective measures must be used to ensure the safety of the experiment. In short, acid S-trifluoromethanesulfonic acid has unique chemical properties and has considerable application value in organic synthesis and other fields. It only needs to be properly controlled to avoid risks and make the best use of it.
What is the preparation method of S-trichloromethyl benzene thiosulfonate?
To make sodium thiosulfate\ (S -\) trichloroacetaldehyde, it is necessary to prepare all kinds of materials and utensils, and follow the specific method.
First take an appropriate amount of sulfur, put it in a dry pot, and place it on the fire. When it is heated and melted, it is like a liquid, tumbling and surging, and the color is golden.
Prepare another container to hold the solution of sodium sulfite. This liquid needs to be mixed with an appropriate amount of water and sodium sulfite powder in advance, so that it is fully dissolved and clear without dross.
Once the sulfur has melted completely, pour it slowly into the sodium sulfite solution, and pour it slowly to make the two blend evenly. After pouring, stir it lightly with a stick to promote the reaction, and the solution gradually changes.
Then, move the mixed liquid to a warm fire and heat it slowly. During this period, pay attention to the heat, do not make it too strong, cause the liquid to splash or the reaction is too fast. When heating, the reaction continues, the color of the solution may change, or some bubbles may appear.
After a long time, when the reaction is complete, stop heating. Let it stand and let the solution cool naturally. As the temperature gradually decreases, crystals can be seen to precipitate, which is sodium thiosulfate\ (S -\) trichloroacetaldehyde.
Then, filter the liquid containing crystals through filter paper. The filter paper should be spread over the funnel, smooth and unpleated. Pour the liquid slowly, so that the liquid penetrates the filter paper, and the crystals remain on the filter paper.
After filtration, rinse the crystals with an appropriate amount of cold water to remove their impurities. After rinsing, move the crystals to a clean and dry container, let them air dry naturally, or let them dry in a dry place, so that they can be completely dried.
In this way, sodium thiosulfate\ (S -\) trichloroacetaldehyde can be prepared to obtain a pure product for use.
First take an appropriate amount of sulfur, put it in a dry pot, and place it on the fire. When it is heated and melted, it is like a liquid, tumbling and surging, and the color is golden.
Prepare another container to hold the solution of sodium sulfite. This liquid needs to be mixed with an appropriate amount of water and sodium sulfite powder in advance, so that it is fully dissolved and clear without dross.
Once the sulfur has melted completely, pour it slowly into the sodium sulfite solution, and pour it slowly to make the two blend evenly. After pouring, stir it lightly with a stick to promote the reaction, and the solution gradually changes.
Then, move the mixed liquid to a warm fire and heat it slowly. During this period, pay attention to the heat, do not make it too strong, cause the liquid to splash or the reaction is too fast. When heating, the reaction continues, the color of the solution may change, or some bubbles may appear.
After a long time, when the reaction is complete, stop heating. Let it stand and let the solution cool naturally. As the temperature gradually decreases, crystals can be seen to precipitate, which is sodium thiosulfate\ (S -\) trichloroacetaldehyde.
Then, filter the liquid containing crystals through filter paper. The filter paper should be spread over the funnel, smooth and unpleated. Pour the liquid slowly, so that the liquid penetrates the filter paper, and the crystals remain on the filter paper.
After filtration, rinse the crystals with an appropriate amount of cold water to remove their impurities. After rinsing, move the crystals to a clean and dry container, let them air dry naturally, or let them dry in a dry place, so that they can be completely dried.
In this way, sodium thiosulfate\ (S -\) trichloroacetaldehyde can be prepared to obtain a pure product for use.
What are the precautions for the storage and transportation of S-trichloromethyl benzene thiosulfonate?
When storing and transporting S-trifluoromethyl thiophosphate carboxylic acid, it is necessary to pay attention to many matters.
Many of its properties are special, and when storing, the first thing to do is to choose a suitable place. This agent should be placed in a cool, dry and well-ventilated place, and must not be exposed to direct sunlight, nor near heat and fire sources. If it is flammable, it may be dangerous in case of open flame or hot topic, causing fire or even explosion.
Furthermore, the storage device should also be carefully selected. When using corrosion-resistant materials, S-trifluoromethyl thiophosphate carboxylic acid may chemically react with certain materials, causing damage to the container and leakage of the agent. And the storage place should be kept away from oxidants, alkalis and other substances to prevent interaction and cause adverse consequences.
As for transportation, it should not be ignored. Transport personnel must be familiar with its characteristics and emergency response methods. During handling, the action must be gentle, and do not load and unload brutally to avoid damage to the container. Transport vehicles also need to ensure that they are in good condition and have corresponding fire and explosion-proof devices. At the same time, the planning of transportation routes should also be thorough, and crowded places and important facilities should be avoided.
In addition, whether it is storage or transportation, the relevant signs must be clear. Warning signs must be able to accurately communicate their danger, so that contacts can see at a glance, for safety. The environmental conditions of storage and transportation, such as temperature, humidity, etc., should also be closely monitored and recorded. If there is any abnormality, it should be disposed of immediately. Only in this way can S-trifluoromethyl ether be kept safe during storage and transportation.
Many of its properties are special, and when storing, the first thing to do is to choose a suitable place. This agent should be placed in a cool, dry and well-ventilated place, and must not be exposed to direct sunlight, nor near heat and fire sources. If it is flammable, it may be dangerous in case of open flame or hot topic, causing fire or even explosion.
Furthermore, the storage device should also be carefully selected. When using corrosion-resistant materials, S-trifluoromethyl thiophosphate carboxylic acid may chemically react with certain materials, causing damage to the container and leakage of the agent. And the storage place should be kept away from oxidants, alkalis and other substances to prevent interaction and cause adverse consequences.
As for transportation, it should not be ignored. Transport personnel must be familiar with its characteristics and emergency response methods. During handling, the action must be gentle, and do not load and unload brutally to avoid damage to the container. Transport vehicles also need to ensure that they are in good condition and have corresponding fire and explosion-proof devices. At the same time, the planning of transportation routes should also be thorough, and crowded places and important facilities should be avoided.
In addition, whether it is storage or transportation, the relevant signs must be clear. Warning signs must be able to accurately communicate their danger, so that contacts can see at a glance, for safety. The environmental conditions of storage and transportation, such as temperature, humidity, etc., should also be closely monitored and recorded. If there is any abnormality, it should be disposed of immediately. Only in this way can S-trifluoromethyl ether be kept safe during storage and transportation.
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