Linshang Chemical
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1-Bromo-2-Chloro-4-Iodobenzene
Linshang Chemical
|
HS Code |
906527 |
| Chemical Formula | C6H3BrClI |
| Molar Mass | 333.35 g/mol |
| Appearance | Solid |
| Color | White to off - white |
| Odor | Typical aromatic odor |
| Solubility In Water | Insoluble |
| Solubility In Organic Solvents | Soluble in common organic solvents like dichloromethane, chloroform |
| Melting Point | 47 - 51 °C |
| Boiling Point | Estimated around 260 - 280 °C |
| Density | Estimated, relatively high due to heavy halogens |
| Stability | Stable under normal conditions, but may react with strong oxidizing agents |
As an accredited 1-Bromo-2-Chloro-4-Iodobenzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100g of 1 - bromo - 2 - chloro - 4 - iodobenzene packaged in a sealed glass bottle. |
| Storage | 1 - Bromo - 2 - chloro - 4 - iodobenzene should be stored in a cool, dry, well - ventilated area. Keep it away from heat sources, flames, and oxidizing agents. Store in a tightly - sealed container to prevent evaporation and exposure to moisture or air, which could potentially lead to degradation or reaction. Label the container clearly to avoid misidentification. |
| Shipping | 1 - Bromo - 2 - chloro - 4 - iodobenzene is shipped in well - sealed, corrosion - resistant containers. Shipment follows strict hazardous chemical regulations, ensuring proper handling, storage, and transport to prevent spills and exposure. |
Competitive 1-Bromo-2-Chloro-4-Iodobenzene 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 1-Bromo-2-Chloro-4-Iodobenzene in China?
As a trusted 1-Bromo-2-Chloro-4-Iodobenzene 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 1-Bromo-2-Chloro-4-Iodobenzene 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-2-chloro-4-iodobenzene?
Mercury, bromine, astatine, and francium are all special substances, each with unique physical properties.
Mercury is the only liquid metal element at room temperature and pressure. Its color is silver-white, with a metallic luster, and its fluidity is very good. The density of mercury is quite high, reaching 13.59 g/cm ³, which is nearly twice that of common metals such as iron at 7.87 g/cm ³. Its melting point is -38.87 ° C and its boiling point is 356.6 ° C. Such a low melting point and relatively moderate boiling point keep mercury in a liquid state over a wide temperature range. Mercury has a high surface tension and often aggregates into spheres when dropped on a plane. And mercury has good electrical conductivity and is used in electrical instruments such as mercury switches.
Bromine, a dark reddish-brown smoky volatile liquid at room temperature. The density of bromine is 3.119 g/cm ³, which is heavier than water. Melting point -7.2 ° C, boiling point 58.8 ° C. Bromine has a strong irritating odor and is toxic. Its vapor has a strong irritating effect on the eyes and respiratory mucosa. Bromine has a small solubility in water, but it is easily soluble in organic solvents, such as carbon tetrachloride, which can make the organic phase appear orange-red in color.
Astatine, the heaviest of the halogen elements, is radioactive. Due to its short half-life, it is extremely small in nature. The physical properties of astatine are mostly known from theoretical speculation and a few experiments. It is speculated that the astatine is either solid at room temperature and black in color, which is consistent with the law of darkening the color of halogen elements from top to bottom. The melting point and boiling point of astatine are expected to be higher than that of iodine, because with the increase of atomic number, the intermolecular force of halogen elements increases.
Francium, also radioactive, is an alkali metal element. The melting point of francium is about 27 ° C, and the boiling point is about 677 ° C. Due to its unstable nucleus and extremely short half-life, only about 22 minutes, research is limited. Francium has the typical properties of alkali metals, is soft and has a metallic luster. Its density is slightly higher than that of water, and it reacts violently with water to generate hydrogen and francium hydroxide. The reaction is more intense than that of alkali metals such as sodium and potassium.
Mercury is the only liquid metal element at room temperature and pressure. Its color is silver-white, with a metallic luster, and its fluidity is very good. The density of mercury is quite high, reaching 13.59 g/cm ³, which is nearly twice that of common metals such as iron at 7.87 g/cm ³. Its melting point is -38.87 ° C and its boiling point is 356.6 ° C. Such a low melting point and relatively moderate boiling point keep mercury in a liquid state over a wide temperature range. Mercury has a high surface tension and often aggregates into spheres when dropped on a plane. And mercury has good electrical conductivity and is used in electrical instruments such as mercury switches.
Bromine, a dark reddish-brown smoky volatile liquid at room temperature. The density of bromine is 3.119 g/cm ³, which is heavier than water. Melting point -7.2 ° C, boiling point 58.8 ° C. Bromine has a strong irritating odor and is toxic. Its vapor has a strong irritating effect on the eyes and respiratory mucosa. Bromine has a small solubility in water, but it is easily soluble in organic solvents, such as carbon tetrachloride, which can make the organic phase appear orange-red in color.
Astatine, the heaviest of the halogen elements, is radioactive. Due to its short half-life, it is extremely small in nature. The physical properties of astatine are mostly known from theoretical speculation and a few experiments. It is speculated that the astatine is either solid at room temperature and black in color, which is consistent with the law of darkening the color of halogen elements from top to bottom. The melting point and boiling point of astatine are expected to be higher than that of iodine, because with the increase of atomic number, the intermolecular force of halogen elements increases.
Francium, also radioactive, is an alkali metal element. The melting point of francium is about 27 ° C, and the boiling point is about 677 ° C. Due to its unstable nucleus and extremely short half-life, only about 22 minutes, research is limited. Francium has the typical properties of alkali metals, is soft and has a metallic luster. Its density is slightly higher than that of water, and it reacts violently with water to generate hydrogen and francium hydroxide. The reaction is more intense than that of alkali metals such as sodium and potassium.
What are the chemical properties of 1-bromo-2-chloro-4-iodobenzene?
Mercury, such as mercury, is liquid at room temperature, silver-white and metallic luster, easy to disperse, highly toxic, and is one of the heavy non-ferrous metal elements. Its chemical properties are unique, it can evaporate at room temperature, and the vapor is extremely toxic. Inhalation can easily cause serious damage to the human body, such as mercury poisoning. Mercury can form amalgams with many metals, and this process is like a wonderful fusion. When mercury meets sulfur, it can easily combine to form mercury sulfide.
Bromine, at room temperature and pressure, is a dark reddish-brown smoky liquid with a unique and pungent smell, which is highly corrosive and toxic. Bromine is chemically active and highly oxidizing, and can react with many metals and non-metals. Bromine can oxidize metal iron and other metals to form corresponding bromides. It can also react with water to form hydrobromic acid and hypobromic acid.
Astatine is one of the halogen elements and is radioactive. Because of its radioactivity, it is difficult to study its properties. Theoretically, the chemical properties of astatine are similar to iodine, or it can form salts with metals, but the stability of its compounds may be worse than that of iodine compounds. Astatine may react with hydrogen under specific conditions to form hydrogen astatine, but due to the radioactivity and rarity of astatine, such reactions are extremely difficult to carry out and observe.
Of these three, mercury is a liquid metal, bromine is a liquid non-metal, and astatine is radioactive. They all have unique chemical properties and play a role in the field of chemistry. However, due to their toxicity, corrosiveness, or radioactivity, they need to be studied and used with extreme caution.
Bromine, at room temperature and pressure, is a dark reddish-brown smoky liquid with a unique and pungent smell, which is highly corrosive and toxic. Bromine is chemically active and highly oxidizing, and can react with many metals and non-metals. Bromine can oxidize metal iron and other metals to form corresponding bromides. It can also react with water to form hydrobromic acid and hypobromic acid.
Astatine is one of the halogen elements and is radioactive. Because of its radioactivity, it is difficult to study its properties. Theoretically, the chemical properties of astatine are similar to iodine, or it can form salts with metals, but the stability of its compounds may be worse than that of iodine compounds. Astatine may react with hydrogen under specific conditions to form hydrogen astatine, but due to the radioactivity and rarity of astatine, such reactions are extremely difficult to carry out and observe.
Of these three, mercury is a liquid metal, bromine is a liquid non-metal, and astatine is radioactive. They all have unique chemical properties and play a role in the field of chemistry. However, due to their toxicity, corrosiveness, or radioactivity, they need to be studied and used with extreme caution.
What are the applications of 1-bromo-2-chloro-4-iodobenzene in organic synthesis?
Mercury, neon, and krypton have the following applications in organic synthesis:
In organic synthesis, mercury was often used for some special reactions in the past. For example, in the hydration reaction of olefins catalyzed by mercury salts, olefins and water can form alcohols under the action of mercury salts. Like acetylene and water catalyzed by mercury sulfate, acetaldehyde can be generated, which is an important way to obtain acetaldehyde. However, mercury is toxic and harmful to the environment and human body. Nowadays, with the rise of green chemistry, the application of mercury in organic synthesis is gradually limited. Chemists are trying to find more green and environmentally friendly alternatives.
Neon gas in organic synthesis reaction systems, although it is usually not directly involved in chemical reactions, has important uses. Due to its stable chemical properties, it can be filled into the reaction vessel as a protective gas to avoid side reactions between organic reactants, catalysts, etc. and oxygen and water vapor in the air, creating a stable reaction environment for organic synthesis. For example, in some metal-organic catalytic reactions that are sensitive to oxygen and water vapor, neon gas can ensure the smooth progress of the reaction.
Krypton gas is similar to neon gas and has stable properties. In organic synthesis, krypton gas can also be used as a protective gas. In some high-end organic synthesis experiments, especially when it involves extremely active intermediates or reactions that require harsh reaction conditions, krypton gas can rely on its inertness to prevent the reactants from being oxidized, hydrolyzed, etc., and ensure that the reaction proceeds in the desired direction. Furthermore, in a specific photochemical reaction device, a special lamp filled with krypton gas can provide a light source of a specific wavelength to stimulate organic molecules to undergo photochemical reactions, thus promoting the realization of organic synthesis reactions.
In organic synthesis, mercury was often used for some special reactions in the past. For example, in the hydration reaction of olefins catalyzed by mercury salts, olefins and water can form alcohols under the action of mercury salts. Like acetylene and water catalyzed by mercury sulfate, acetaldehyde can be generated, which is an important way to obtain acetaldehyde. However, mercury is toxic and harmful to the environment and human body. Nowadays, with the rise of green chemistry, the application of mercury in organic synthesis is gradually limited. Chemists are trying to find more green and environmentally friendly alternatives.
Neon gas in organic synthesis reaction systems, although it is usually not directly involved in chemical reactions, has important uses. Due to its stable chemical properties, it can be filled into the reaction vessel as a protective gas to avoid side reactions between organic reactants, catalysts, etc. and oxygen and water vapor in the air, creating a stable reaction environment for organic synthesis. For example, in some metal-organic catalytic reactions that are sensitive to oxygen and water vapor, neon gas can ensure the smooth progress of the reaction.
Krypton gas is similar to neon gas and has stable properties. In organic synthesis, krypton gas can also be used as a protective gas. In some high-end organic synthesis experiments, especially when it involves extremely active intermediates or reactions that require harsh reaction conditions, krypton gas can rely on its inertness to prevent the reactants from being oxidized, hydrolyzed, etc., and ensure that the reaction proceeds in the desired direction. Furthermore, in a specific photochemical reaction device, a special lamp filled with krypton gas can provide a light source of a specific wavelength to stimulate organic molecules to undergo photochemical reactions, thus promoting the realization of organic synthesis reactions.
What are the methods for preparing 1-bromo-2-chloro-4-iodobenzene?
The method of forging a sword, the sword case mentioned by the teacher, is especially good.
The first heavy material for casting a sword, one is steel, which needs to be carefully selected and pure in texture, and impurities must be removed. This is the bone of the sword, which is related to the toughness of the blade. The second is water, which is clear and pure. When quenching, the advantages and disadvantages of water can change the stiffness and softness of the sword. The third is charcoal, which has a moderate heat to make the steel suitable for melting and casting. These three are the foundation for casting swords.
The system of the sword case is related to the hiding and protection of the sword. Choose the wood with strong quality and beautiful patterns, such as sandalwood, peach wood, etc. Its wood is warm and moist, and has a fragrance, which can protect the sword body from moths. When making a box, first measure the length and width of the sword, and measure it accurately, with no difference in millimeters. The inner wall of the box needs to be polished smoothly to prevent damage to the blade. The appearance of the box can be carefully crafted, either for the clouds of mountains and rivers, or for the auspicious beasts of dragons and phoenixes, which not only enhances the appearance, but also contains auspicious meaning.
After the sword is completed, put it in the box for collection, and choose a dry and ventilated place to prevent moisture and rust. Always wipe the box and the sword body with a soft cloth to keep it clean. And the opening and closing of the box should also be gentle, so that the sword can be protected for a long time, so that the edge of the sword will not be damaged, and the exquisite box will last forever. Sword casting and box making are both the essence of skills, and only with care can you get a good product handed down from generation to generation.
The first heavy material for casting a sword, one is steel, which needs to be carefully selected and pure in texture, and impurities must be removed. This is the bone of the sword, which is related to the toughness of the blade. The second is water, which is clear and pure. When quenching, the advantages and disadvantages of water can change the stiffness and softness of the sword. The third is charcoal, which has a moderate heat to make the steel suitable for melting and casting. These three are the foundation for casting swords.
The system of the sword case is related to the hiding and protection of the sword. Choose the wood with strong quality and beautiful patterns, such as sandalwood, peach wood, etc. Its wood is warm and moist, and has a fragrance, which can protect the sword body from moths. When making a box, first measure the length and width of the sword, and measure it accurately, with no difference in millimeters. The inner wall of the box needs to be polished smoothly to prevent damage to the blade. The appearance of the box can be carefully crafted, either for the clouds of mountains and rivers, or for the auspicious beasts of dragons and phoenixes, which not only enhances the appearance, but also contains auspicious meaning.
After the sword is completed, put it in the box for collection, and choose a dry and ventilated place to prevent moisture and rust. Always wipe the box and the sword body with a soft cloth to keep it clean. And the opening and closing of the box should also be gentle, so that the sword can be protected for a long time, so that the edge of the sword will not be damaged, and the exquisite box will last forever. Sword casting and box making are both the essence of skills, and only with care can you get a good product handed down from generation to generation.
What are the effects of 1-bromo-2-chloro-4-iodobenzene on the environment and humans?
The effects of mercury, radon, and polonium bismuth on the environment and human body have been observed in ancient times.
Mercury is highly toxic. In the environment, it can exist in soil and water. In soil, it can inhibit the growth of plants, cause vegetation to wither, and accumulate through the food chain, endangering many organisms. In water bodies, it can be converted into methylmercury, which is even more toxic. If aquatic organisms are ingested, the population may be severely damaged. In humans, mercury is ingested through respiration, skin contact, and diet, which damages the nervous system, causes trembling, insomnia, memory loss, and also damages the kidneys and other organs. If pregnant women are poisoned by mercury, the fetus is easily deformed or brain damaged.
Radon, a colorless and odorless radioactive gas. In the environment, it is mostly derived from rocks, soil, and groundwater. It accumulates indoors and is difficult to disperse. In humans, after inhaling radon gas, the particles produced by decay will hit lung cells, causing cell damage and greatly increasing the risk of lung cancer. If the concentration of radon in the residence is high, the risk of cancer in people who live for a long time is much higher than that of ordinary people.
Polonium bismuth is radioactive. Polonium is extremely toxic and can be lethal in very small amounts. In the environment, if released, it can pollute soil and water sources, causing imbalance in the surrounding ecology. On the human body, entering the body through ingestion, inhalation, or wounds can damage cells and cause serious diseases such as organ failure and hematopoietic dysfunction. Although bismuth is less radioactive, long-term exposure or ingestion can also accumulate in the body, damage the kidneys and other organs, and affect the normal metabolism of the human body.
In summary, mercury, radon, and Polonium bismuth pose a great threat to the balance of the environment and ecology and the health of the human body.
Mercury is highly toxic. In the environment, it can exist in soil and water. In soil, it can inhibit the growth of plants, cause vegetation to wither, and accumulate through the food chain, endangering many organisms. In water bodies, it can be converted into methylmercury, which is even more toxic. If aquatic organisms are ingested, the population may be severely damaged. In humans, mercury is ingested through respiration, skin contact, and diet, which damages the nervous system, causes trembling, insomnia, memory loss, and also damages the kidneys and other organs. If pregnant women are poisoned by mercury, the fetus is easily deformed or brain damaged.
Radon, a colorless and odorless radioactive gas. In the environment, it is mostly derived from rocks, soil, and groundwater. It accumulates indoors and is difficult to disperse. In humans, after inhaling radon gas, the particles produced by decay will hit lung cells, causing cell damage and greatly increasing the risk of lung cancer. If the concentration of radon in the residence is high, the risk of cancer in people who live for a long time is much higher than that of ordinary people.
Polonium bismuth is radioactive. Polonium is extremely toxic and can be lethal in very small amounts. In the environment, if released, it can pollute soil and water sources, causing imbalance in the surrounding ecology. On the human body, entering the body through ingestion, inhalation, or wounds can damage cells and cause serious diseases such as organ failure and hematopoietic dysfunction. Although bismuth is less radioactive, long-term exposure or ingestion can also accumulate in the body, damage the kidneys and other organs, and affect the normal metabolism of the human body.
In summary, mercury, radon, and Polonium bismuth pose a great threat to the balance of the environment and ecology and the health of the human body.
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