Linshang Chemical
PRODUCTS
Benzene, 1-Chloro-3-Isocyanato-
Linshang Chemical
|
HS Code |
435874 |
| Chemical Formula | C7H4ClNO |
| Molar Mass | 153.565 g/mol |
| Appearance | Colorless to light - yellow liquid |
| Boiling Point | Approximately 235 - 237 °C |
| Density | 1.27 g/cm³ (estimated) |
| Solubility In Water | Insoluble |
| Solubility In Organic Solvents | Soluble in many organic solvents like toluene, dichloromethane |
| Vapor Pressure | Low vapor pressure at room temperature |
| Flash Point | 104 °C (closed cup, estimated) |
As an accredited Benzene, 1-Chloro-3-Isocyanato- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 1 - chloro - 3 - isocyanato - benzene in 1 - kg bottles, well - sealed for chemical protection. |
| Storage | 1 - Chloro - 3 - isocyanatobenzene should be stored in a cool, dry, well - ventilated area, away from sources of heat, ignition, and direct sunlight. Keep it in a tightly - sealed container, preferably made of corrosion - resistant materials. Store it separately from incompatible substances like strong acids, bases, and reducing agents to prevent dangerous reactions. |
| Shipping | 1 - Chloro - 3 - isocyanatobenzene is a hazardous chemical. Shipping requires proper classification, using approved containers. It must comply with international and domestic regulations, with appropriate labeling for its dangerous nature. |
Competitive Benzene, 1-Chloro-3-Isocyanato- 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.
We will respond to you as soon as possible.
Tel: +8615365006308
Email: info@alchemist-chem.com
Where to Buy Benzene, 1-Chloro-3-Isocyanato- in China?
As a trusted Benzene, 1-Chloro-3-Isocyanato- manufacturer, we deliver:
Factory-Direct Value: Competitive pricing with no middleman markups, tailored for bulk orders and project-scale requirements.
Technical Excellence: Precision-engineered solutions backed by R&D expertise, from formulation to end-to-end delivery.
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 Benzene, 1-Chloro-3-Isocyanato- 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-chloro-3-isocyanate benzene?
Mercury and indium triisovalerate, both of which are chemical substances, each with unique physical properties.
Mercury, commonly known as mercury, is the only metal element that is liquid at room temperature and pressure. Its appearance is silver-white and shiny, and its fluidity is very good. The density of mercury is quite high, about 13.59 grams/cubic centimeter, which is more significant than that of many common metals, so it can be clearly felt in the hand. And the surface tension of mercury is high, and it is easy to form small droplets in the shape of beads when sprinkled, rolling on the plane. The melting point of mercury is -38.87 ° C and the boiling point is 356.6 ° C. This wide liquid temperature range makes it used in specific temperature measurement and other fields. However, it should be noted that mercury has certain toxicity. After its vapor is inhaled into the human body, it may cause damage to the nervous system, kidneys, etc.
Indium triisovalerate is usually in a solid state, and its specific physical properties may vary slightly due to factors such as crystal morphology and purity. Generally speaking, the compound is relatively stable at room temperature and pressure. Its color may vary due to factors such as impurities. In a pure state, it may be white to slightly yellow powder or crystalline. In terms of solubility, indium triisovalerate is insoluble in water, but it may have certain solubility in some organic solvents. This property makes it useful in organic synthesis, material preparation, and other fields. Its melting point, boiling point and other thermal properties are different from common inorganic compounds due to the particularity of their structures. When heating them, attention should be paid to their phase transition.
Mercury, commonly known as mercury, is the only metal element that is liquid at room temperature and pressure. Its appearance is silver-white and shiny, and its fluidity is very good. The density of mercury is quite high, about 13.59 grams/cubic centimeter, which is more significant than that of many common metals, so it can be clearly felt in the hand. And the surface tension of mercury is high, and it is easy to form small droplets in the shape of beads when sprinkled, rolling on the plane. The melting point of mercury is -38.87 ° C and the boiling point is 356.6 ° C. This wide liquid temperature range makes it used in specific temperature measurement and other fields. However, it should be noted that mercury has certain toxicity. After its vapor is inhaled into the human body, it may cause damage to the nervous system, kidneys, etc.
Indium triisovalerate is usually in a solid state, and its specific physical properties may vary slightly due to factors such as crystal morphology and purity. Generally speaking, the compound is relatively stable at room temperature and pressure. Its color may vary due to factors such as impurities. In a pure state, it may be white to slightly yellow powder or crystalline. In terms of solubility, indium triisovalerate is insoluble in water, but it may have certain solubility in some organic solvents. This property makes it useful in organic synthesis, material preparation, and other fields. Its melting point, boiling point and other thermal properties are different from common inorganic compounds due to the particularity of their structures. When heating them, attention should be paid to their phase transition.
What are the chemical properties of 1-chloro-3-isocyanate benzene?
Mercury and iridium triisovalerate have a variety of chemical properties. Mercury, which is liquid at room temperature, is silver-white and has a metallic luster. It is volatile, and the vapor is toxic. If accidentally inhaled, it will cause damage to the nervous system and kidneys. Mercury can dissolve many metals to form amalgams, which are used in metallurgy and chemical industry. In addition, mercury is relatively stable chemically. It does not react with oxygen at room temperature and can form mercury oxide when heated.
Iridium triisovalerate, in which iridium is a transition metal and has an empty d orbital, which can form coordination bonds with ligands. Isovalerate, as a ligand, coordinates with iridium through oxygen atoms. The complex can act as a catalyst in organic synthesis reactions, and activate the reaction substrate by virtue of the special electronic structure of the central iridium atom, thereby accelerating the reaction rate and improving the reaction selectivity. At the same time, due to the spatial structure and electronic effect of ligands, iridium triisovalerate also shows unique properties in the fields of light and electricity, and may be applied to luminescent materials, electrochemical sensors, etc. Its stability is affected by factors such as temperature and solvent, and it can maintain structural stability under suitable conditions. When conditions change, ligand dissociation or complex structure rearrangement may occur.
Iridium triisovalerate, in which iridium is a transition metal and has an empty d orbital, which can form coordination bonds with ligands. Isovalerate, as a ligand, coordinates with iridium through oxygen atoms. The complex can act as a catalyst in organic synthesis reactions, and activate the reaction substrate by virtue of the special electronic structure of the central iridium atom, thereby accelerating the reaction rate and improving the reaction selectivity. At the same time, due to the spatial structure and electronic effect of ligands, iridium triisovalerate also shows unique properties in the fields of light and electricity, and may be applied to luminescent materials, electrochemical sensors, etc. Its stability is affected by factors such as temperature and solvent, and it can maintain structural stability under suitable conditions. When conditions change, ligand dissociation or complex structure rearrangement may occur.
What are the main uses of 1-chloro-3-isocyanate benzene?
What are the main uses of iridium 1 + -alkane-3-isovalerate?
Iridium 1 + -alkane-3-isovalerate has important uses in many fields. In the field of chemical synthesis, it often acts as a catalyst. With its unique chemical structure, it can effectively reduce the activation energy required for chemical reactions, make the reaction more likely to occur, and improve the selectivity of the reaction. For example, in the synthesis of specific organic compounds, the use of this compound as a catalyst can accurately guide the reaction in the direction of the desired product, reduce the occurrence of side reactions, and then improve the purity and yield of the product.
In the field of materials science, 1 + -alkane-3-isovalerate iridium also has outstanding performance. Because of its special physical and chemical properties, it can be used to prepare new materials with excellent performance. If you participate in the preparation of materials with special optical and electrical properties, such materials have wide application prospects in optoelectronic devices, sensors, etc. With the addition of this compound, the microstructure and properties of the material can be adjusted to meet the special needs of different application scenarios.
At the level of scientific research and exploration, 1 + -alkane-3-isovalerate iridium provides an important research object for the study of chemical reaction mechanism and material performance regulation mechanism. By conducting in-depth research on its behavior in various reactions and systems, researchers can enhance their understanding of relevant scientific principles and lay a theoretical foundation for further development of new catalytic systems and optimization of material properties. In conclusion, 1 + -alkane-3-isovalerate iridium plays a key role in many fields such as chemistry, materials and scientific research, and is of great significance to promote the development of related fields.
Iridium 1 + -alkane-3-isovalerate has important uses in many fields. In the field of chemical synthesis, it often acts as a catalyst. With its unique chemical structure, it can effectively reduce the activation energy required for chemical reactions, make the reaction more likely to occur, and improve the selectivity of the reaction. For example, in the synthesis of specific organic compounds, the use of this compound as a catalyst can accurately guide the reaction in the direction of the desired product, reduce the occurrence of side reactions, and then improve the purity and yield of the product.
In the field of materials science, 1 + -alkane-3-isovalerate iridium also has outstanding performance. Because of its special physical and chemical properties, it can be used to prepare new materials with excellent performance. If you participate in the preparation of materials with special optical and electrical properties, such materials have wide application prospects in optoelectronic devices, sensors, etc. With the addition of this compound, the microstructure and properties of the material can be adjusted to meet the special needs of different application scenarios.
At the level of scientific research and exploration, 1 + -alkane-3-isovalerate iridium provides an important research object for the study of chemical reaction mechanism and material performance regulation mechanism. By conducting in-depth research on its behavior in various reactions and systems, researchers can enhance their understanding of relevant scientific principles and lay a theoretical foundation for further development of new catalytic systems and optimization of material properties. In conclusion, 1 + -alkane-3-isovalerate iridium plays a key role in many fields such as chemistry, materials and scientific research, and is of great significance to promote the development of related fields.
What are the synthesis methods of 1-chloro-3-isocyanate benzene?
The synthesis of benzyl halogen and isohalate is an important topic in organic synthesis. There are many synthesis methods, each with its advantages and disadvantages, and should be selected according to the specific situation.
First, halogenated hydrocarbons and isohalides are used as raw materials and obtained by nucleophilic substitution reaction. This reaction condition is mild and convenient to operate. For example, halogenated benzyl and sodium isohalate are added to a suitable solvent, and a catalyst is added to control the temperature. Such as benzyl bromide and sodium isochlorate, in acetone solvent, and potassium iodide as a catalyst, when the reaction number is 40-50 ℃, the target product can be obtained. However, there are many side reactions in this reaction, and the yield may be limited.
Second, benzyl alcohol is reacted with halogenating agent and isohalic acid source First halogenate benzyl alcohol, and then react with isohalate. Such as benzyl alcohol and thionyl chloride to give benzyl chloride, and then react with potassium isobromate under basic conditions. The raw materials are common in this way, but the steps are slightly complicated. It is necessary to pay attention to the control of reaction conditions to prevent overreaction.
Third, the coupling reaction catalyzed by transition metals. The formation of carbon-heteroatomic bonds is achieved by using halogenated aromatics, benzyl halides and isohalates as substrates, and transition metal catalysts (such as palladium, copper, etc.). This method has good selectivity and can synthesize complex structural products. If palladium catalyzed, benzyl halides and isofluorates react in suitable bases and solvents in the presence of ligands. However, transition metal catalysts are expensive and need to be recycled and reused to reduce costs.
In addition, microwave radiation, ultrasound-assisted and other technologies are also used for this synthesis. Such techniques can accelerate the reaction and improve the yield and selectivity. For example, under microwave radiation, the reaction of halobenzyl with isohalate can greatly shorten the reaction time and improve the efficiency.
In short, there are various synthesis methods for halogen and isohalate complex benzyl. According to factors such as raw material availability, product requirements, and cost considerations, it should be carefully selected to achieve the best synthetic effect.
First, halogenated hydrocarbons and isohalides are used as raw materials and obtained by nucleophilic substitution reaction. This reaction condition is mild and convenient to operate. For example, halogenated benzyl and sodium isohalate are added to a suitable solvent, and a catalyst is added to control the temperature. Such as benzyl bromide and sodium isochlorate, in acetone solvent, and potassium iodide as a catalyst, when the reaction number is 40-50 ℃, the target product can be obtained. However, there are many side reactions in this reaction, and the yield may be limited.
Second, benzyl alcohol is reacted with halogenating agent and isohalic acid source First halogenate benzyl alcohol, and then react with isohalate. Such as benzyl alcohol and thionyl chloride to give benzyl chloride, and then react with potassium isobromate under basic conditions. The raw materials are common in this way, but the steps are slightly complicated. It is necessary to pay attention to the control of reaction conditions to prevent overreaction.
Third, the coupling reaction catalyzed by transition metals. The formation of carbon-heteroatomic bonds is achieved by using halogenated aromatics, benzyl halides and isohalates as substrates, and transition metal catalysts (such as palladium, copper, etc.). This method has good selectivity and can synthesize complex structural products. If palladium catalyzed, benzyl halides and isofluorates react in suitable bases and solvents in the presence of ligands. However, transition metal catalysts are expensive and need to be recycled and reused to reduce costs.
In addition, microwave radiation, ultrasound-assisted and other technologies are also used for this synthesis. Such techniques can accelerate the reaction and improve the yield and selectivity. For example, under microwave radiation, the reaction of halobenzyl with isohalate can greatly shorten the reaction time and improve the efficiency.
In short, there are various synthesis methods for halogen and isohalate complex benzyl. According to factors such as raw material availability, product requirements, and cost considerations, it should be carefully selected to achieve the best synthetic effect.
What are the precautions for storing and transporting 1-chloro-3-isocyanate benzene?
First of all, because of its nature, it must be dry and pass through the good places. If the tide is in the environment, it is easy to cause other objects to react, or cause danger, and the oxanate group of silicon may also be caused by the tide, which affects its properties.
The second time, the second time, the package must be solid and dense. It is a combustible and flammable material, and there is a slight leakage. In case of open flame, high temperature, etc., it is easy to ignite and explode. Oxygen group silicon also has its particularity. If the package is broken, it will be damaged by external objects, and it may cause adverse reactions.
Furthermore, the degree of resistance is controlled to a certain extent. It is easy to cause the container to rupture due to the increase in temperature, and it is easy to cause the container to rupture.
In addition, the quality of silicon oxynate at different degrees is also low, or it affects its chemical properties. Therefore, it is appropriate to maintain the appropriate degree of stability and avoid its high or low temperature.
In addition, this material is not connected to the material. It is not possible to combine oxidizing substances to prevent strong reactions. It is also necessary to avoid the mixing of acids, chemicals and other substances, because of its chemical activity, encountering or melting.
The person who operates it must be affected by it, and it is clear that its properties are dangerous, and he is familiar with the operation process. In the place where it is stored, it is also necessary to urgently install the equipment in order to prevent it from being damaged. In this way, the safety of silicon, oxygen, and oxanate can be guaranteed in the storage.
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