Linshang Chemical
PRODUCTS
1-Iodo-2-Fluoro-4-Chloro-6-Bromobenzene
Linshang Chemical
|
HS Code |
841911 |
| Name | 1-Iodo-2-Fluoro-4-Chloro-6-Bromobenzene |
| Molecular Formula | C6H2BrClFI |
| Molecular Weight | 327.34 g/mol |
| Appearance | Typically a solid |
| Melting Point | Data may vary, needs experimental determination |
| Boiling Point | Data may vary, needs experimental determination |
| Density | Data may vary, needs experimental determination |
| Solubility In Water | Low solubility, likely insoluble |
| Solubility In Organic Solvents | Soluble in common organic solvents like dichloromethane |
| Purity | Can be produced in various purity levels |
| Reactivity | Reactive towards nucleophilic substitution reactions due to halogen atoms |
As an accredited 1-Iodo-2-Fluoro-4-Chloro-6-Bromobenzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100g of 1 - iodo - 2 - fluoro - 4 - chloro - 6 - bromobenzene in a sealed glass bottle. |
| Storage | 1 - iodo - 2 - fluoro - 4 - chloro - 6 - bromobenzene should be stored in a cool, dry, well - ventilated area. Keep it away from heat sources, open flames, and oxidizing agents. Store in a tightly sealed container to prevent leakage and exposure to air or moisture, which could potentially cause decomposition or reactivity issues. |
| Shipping | 1 - iodo - 2 - fluoro - 4 - chloro - 6 - bromobenzene is shipped in sealed, corrosion - resistant containers. It adheres to strict hazardous chemical shipping regulations, with proper labeling for safe transportation. |
Competitive 1-Iodo-2-Fluoro-4-Chloro-6-Bromobenzene 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-Iodo-2-Fluoro-4-Chloro-6-Bromobenzene in China?
As a trusted 1-Iodo-2-Fluoro-4-Chloro-6-Bromobenzene 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-Iodo-2-Fluoro-4-Chloro-6-Bromobenzene 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 chemical properties of 1-iodine-2-fluoro-4-chloro-6-bromobenzene?
Mercury is highly toxic and highly reactive. At room temperature, it is liquid and volatile into mercury vapor, which is also highly toxic.
Mercury has many unique chemical properties. First, mercury can form amalgams with many metals, such as alkali metals such as sodium and potassium. When it meets, it can quickly combine to form amalgams. The formation of this amalgam may change the original physical and chemical properties of the metal.
Second, mercury can react with oxygen. Under heating conditions, mercury will combine with oxygen to form mercury oxide. This reaction can be regarded as an oxidation process, indicating that mercury has certain reductivity.
Third, the reaction of mercury in acid is quite special. In case of nitric acid, mercury can react with it to produce products such as mercury nitrate and nitrogen oxides. However, mercury and hydrochloric acid are usually difficult to react because of the order of metal activity.
Fourth, mercury compounds have various properties. Such as mercury chloride, which is highly toxic and oxidizing; mercury sulfide is relatively stable and is commonly found in cinnabar ores.
The chemical properties of mercury make it both important and harmful in many fields. In the past, mercury was widely used in metallurgy, chemical industry, medicine and other industries. However, due to its strong toxicity, it is easy to cause environmental pollution and personal injury. Today, its use has been strictly controlled. When the world is well aware of the chemical properties of mercury, it should be treated with caution to avoid its harm and make good use of it.
Mercury has many unique chemical properties. First, mercury can form amalgams with many metals, such as alkali metals such as sodium and potassium. When it meets, it can quickly combine to form amalgams. The formation of this amalgam may change the original physical and chemical properties of the metal.
Second, mercury can react with oxygen. Under heating conditions, mercury will combine with oxygen to form mercury oxide. This reaction can be regarded as an oxidation process, indicating that mercury has certain reductivity.
Third, the reaction of mercury in acid is quite special. In case of nitric acid, mercury can react with it to produce products such as mercury nitrate and nitrogen oxides. However, mercury and hydrochloric acid are usually difficult to react because of the order of metal activity.
Fourth, mercury compounds have various properties. Such as mercury chloride, which is highly toxic and oxidizing; mercury sulfide is relatively stable and is commonly found in cinnabar ores.
The chemical properties of mercury make it both important and harmful in many fields. In the past, mercury was widely used in metallurgy, chemical industry, medicine and other industries. However, due to its strong toxicity, it is easy to cause environmental pollution and personal injury. Today, its use has been strictly controlled. When the world is well aware of the chemical properties of mercury, it should be treated with caution to avoid its harm and make good use of it.
What are the main uses of 1-iodine-2-fluoro-4-chloro-6-bromobenzene?
Mercury, lead, cadmium, arsenic, etc. are all toxic heavy metals. Mercury has a wide range of uses. In ancient times, it was often used in alchemy techniques. Scholars believed that mercury alchemy could be used as a medicine for immortality. Although it was absurd, it reflected the understanding and use of mercury at that time. In the medical field, mercury amalgam was used to fill teeth in the past, but now due to the toxicity of mercury, this application is becoming less and less. Mercury is also found in the chemical industry. It can be used to make batteries containing mercury, etc. However, it is easy to cause environmental pollution after being discarded.
The main uses of lead are many. First, in building materials, lead plates have good radiation protection properties and are often used in hospital radiology departments, nuclear industry-related places, etc., to protect against the harm of radiation to the human body. Second, in the field of lead-acid batteries, lead is a key material. Due to its good electrochemical properties, it is widely used in the manufacture of batteries for automobiles, electric vehicles, etc., to provide reliable protection for start-up and power supply.
The use of cadmium cannot be ignored. In the electroplating industry, cadmium is often used for electroplating on metal surfaces. Metals plated with cadmium can enhance their corrosion resistance and wear resistance. For example, some precision instruments, aerospace parts, etc., cadmium electroplating process will be used to improve quality. In the manufacture of pigments, cadmium pigments have bright colors and good stability. They are often used in painting pigments, ceramic coloring and other fields.
Although arsenic is toxic, it also has certain uses. In the field of medicine, in the past, arsenic-containing drugs were used to treat certain diseases, such as arsenic (the main ingredient is arsenic trioxide) for the treatment of leukemia. After modern medical research and improvement, it can be accurately applied to the treatment of specific diseases. In agriculture, arsenic preparations were once used as pesticides, but their use is now strictly limited due to their great harm to the environment and human body.
Although these numbers have their own uses, their toxicity also poses a serious threat to the environment and human health. Therefore, during use, it should be used with caution, and attention should be paid to protection and proper disposal to reduce their harm.
The main uses of lead are many. First, in building materials, lead plates have good radiation protection properties and are often used in hospital radiology departments, nuclear industry-related places, etc., to protect against the harm of radiation to the human body. Second, in the field of lead-acid batteries, lead is a key material. Due to its good electrochemical properties, it is widely used in the manufacture of batteries for automobiles, electric vehicles, etc., to provide reliable protection for start-up and power supply.
The use of cadmium cannot be ignored. In the electroplating industry, cadmium is often used for electroplating on metal surfaces. Metals plated with cadmium can enhance their corrosion resistance and wear resistance. For example, some precision instruments, aerospace parts, etc., cadmium electroplating process will be used to improve quality. In the manufacture of pigments, cadmium pigments have bright colors and good stability. They are often used in painting pigments, ceramic coloring and other fields.
Although arsenic is toxic, it also has certain uses. In the field of medicine, in the past, arsenic-containing drugs were used to treat certain diseases, such as arsenic (the main ingredient is arsenic trioxide) for the treatment of leukemia. After modern medical research and improvement, it can be accurately applied to the treatment of specific diseases. In agriculture, arsenic preparations were once used as pesticides, but their use is now strictly limited due to their great harm to the environment and human body.
Although these numbers have their own uses, their toxicity also poses a serious threat to the environment and human health. Therefore, during use, it should be used with caution, and attention should be paid to protection and proper disposal to reduce their harm.
What is the synthesis of 1-iodine-2-fluoro-4-chloro-6-bromobenzene?
To prepare 1, 2, 4, and 6 alcohols, the method is as follows:
First of all, 1-alcohol can be prepared. The aqueous solution of halogenated hydrocarbons and strong bases can be heated together, and the hydrolysis reaction occurs. The halogen atom is replaced by the hydroxyl group, and then the 1-alcohol is obtained. For example, chloroethane and sodium hydroxide aqueous solution are heated together, and the chlorine atom leaves, and the hydroxyl group replaces it to generate ethanol. This is a classic method. It can also be obtained by reduction of alaldehyde or ketone. Taking aldehyde as an example, metal hydrides such as sodium borohydride are used. The hydrogen negative ion has strong reductivity, and the aldehyde group can be reduced to a hydroxyl group to obtain 1-alcohol.
As for the synthesis of 2-alcohol. The addition reaction of alkenes and water in the presence of acidic catalysts follows the Markov rule. Hydrogen atoms are added to double-bonded carbons containing more hydrogen, and hydroxyl groups are added to double-bonded carbons containing less hydrogen to obtain 2-alcohol. For example, propylene reacts with water under the catalysis of sulfuric acid to generate 2-propanol. The reaction of aldosterone with Grignard's reagent is also a good method. The negative ion of the hydrocarbon group in Grignard's reagent attacks the carbonyl carbon of aldosterone, and then hydrolyzes to obtain 2-alcohol.
Synthesis of 4-alcohol can be achieved by the corresponding halogenated hydrocarbon through a multi-step reaction. First, the halogenated hydrocarbon is converted into an olefin, and then the hydroxyl group is introduced into the appropriate position by controlling the reaction conditions through addition and substitution Or use some special organic synthesis routes, such as building a suitable carbon skeleton through a diene synthesis reaction, then converting it into a functional group, introducing hydroxyl groups at the desired position to produce 4-alcohol.
The preparation of 6-alcohol is more complicated. It can start from the construction of carbon chains, such as using the addition reaction of alkynes to grow the carbon chain, and then converting the alkynyl group into the corresponding functional group, and gradually introducing hydroxyl groups. It can also be constructed by a multi-step carbon-carbon bond formation reaction, such as the Fu-gram reaction, to construct a carbon skeleton containing six carbons, and then through oxidation and reduction reactions, the appropriate functional group is converted into a hydroxyl group to obtain 6-alcohol.
The synthesis of these numbers requires careful selection of appropriate synthesis paths according to specific raw materials, reaction conditions and product requirements in order to achieve the desired effect.
First of all, 1-alcohol can be prepared. The aqueous solution of halogenated hydrocarbons and strong bases can be heated together, and the hydrolysis reaction occurs. The halogen atom is replaced by the hydroxyl group, and then the 1-alcohol is obtained. For example, chloroethane and sodium hydroxide aqueous solution are heated together, and the chlorine atom leaves, and the hydroxyl group replaces it to generate ethanol. This is a classic method. It can also be obtained by reduction of alaldehyde or ketone. Taking aldehyde as an example, metal hydrides such as sodium borohydride are used. The hydrogen negative ion has strong reductivity, and the aldehyde group can be reduced to a hydroxyl group to obtain 1-alcohol.
As for the synthesis of 2-alcohol. The addition reaction of alkenes and water in the presence of acidic catalysts follows the Markov rule. Hydrogen atoms are added to double-bonded carbons containing more hydrogen, and hydroxyl groups are added to double-bonded carbons containing less hydrogen to obtain 2-alcohol. For example, propylene reacts with water under the catalysis of sulfuric acid to generate 2-propanol. The reaction of aldosterone with Grignard's reagent is also a good method. The negative ion of the hydrocarbon group in Grignard's reagent attacks the carbonyl carbon of aldosterone, and then hydrolyzes to obtain 2-alcohol.
Synthesis of 4-alcohol can be achieved by the corresponding halogenated hydrocarbon through a multi-step reaction. First, the halogenated hydrocarbon is converted into an olefin, and then the hydroxyl group is introduced into the appropriate position by controlling the reaction conditions through addition and substitution Or use some special organic synthesis routes, such as building a suitable carbon skeleton through a diene synthesis reaction, then converting it into a functional group, introducing hydroxyl groups at the desired position to produce 4-alcohol.
The preparation of 6-alcohol is more complicated. It can start from the construction of carbon chains, such as using the addition reaction of alkynes to grow the carbon chain, and then converting the alkynyl group into the corresponding functional group, and gradually introducing hydroxyl groups. It can also be constructed by a multi-step carbon-carbon bond formation reaction, such as the Fu-gram reaction, to construct a carbon skeleton containing six carbons, and then through oxidation and reduction reactions, the appropriate functional group is converted into a hydroxyl group to obtain 6-alcohol.
The synthesis of these numbers requires careful selection of appropriate synthesis paths according to specific raw materials, reaction conditions and product requirements in order to achieve the desired effect.
What are the precautions for storing and transporting 1-iodine-2-fluoro-4-chloro-6-bromobenzene?
When storing and transporting alum, pulp, halogen, and alkali, many matters need to be paid attention to.
Alum is dry and easy to absorb moisture and agglomerate. Therefore, when storing, it should be placed in a dry and ventilated place, and do not coexist with other objects with heavy moisture to avoid their qualitative change. During transportation, also beware of moisture intrusion caused by package damage. If the package leaks, alum absorbs moisture or reacts biochemically, which affects its quality.
The pulp is perishable. Storage should be in a low temperature and clean environment to prevent the growth of microorganisms and its deterioration. When transporting, the utensils used must be clean, and thermal insulation measures should be taken to avoid its high temperature and corrosion.
The halogen is corrosive. The containers used for storage must be corrosion-resistant materials, such as ceramics, specific plastics, etc. Metal containers must not be used, otherwise they will be easily corroded, which will not only damage the container, but also cause impure halogen. During transportation, make sure that the container is well sealed to prevent the leakage of halogen liquid from corroding surrounding items.
Alkali, which absorbs moisture and reacts easily with acid. Storage should be in a dry place, away from acidic substances. When transporting, the packaging should be tight to avoid mixing with acidic items, otherwise if it comes into contact, it may react violently and endanger safety.
All these items should be protected and properly disposed of according to their characteristics during storage and transportation to ensure their quality and safety.
Alum is dry and easy to absorb moisture and agglomerate. Therefore, when storing, it should be placed in a dry and ventilated place, and do not coexist with other objects with heavy moisture to avoid their qualitative change. During transportation, also beware of moisture intrusion caused by package damage. If the package leaks, alum absorbs moisture or reacts biochemically, which affects its quality.
The pulp is perishable. Storage should be in a low temperature and clean environment to prevent the growth of microorganisms and its deterioration. When transporting, the utensils used must be clean, and thermal insulation measures should be taken to avoid its high temperature and corrosion.
The halogen is corrosive. The containers used for storage must be corrosion-resistant materials, such as ceramics, specific plastics, etc. Metal containers must not be used, otherwise they will be easily corroded, which will not only damage the container, but also cause impure halogen. During transportation, make sure that the container is well sealed to prevent the leakage of halogen liquid from corroding surrounding items.
Alkali, which absorbs moisture and reacts easily with acid. Storage should be in a dry place, away from acidic substances. When transporting, the packaging should be tight to avoid mixing with acidic items, otherwise if it comes into contact, it may react violently and endanger safety.
All these items should be protected and properly disposed of according to their characteristics during storage and transportation to ensure their quality and safety.
What are the environmental effects of 1-iodine-2-fluoro-4-chloro-6-bromobenzene?
"All mercury is poisonous to hardware, and its gas rises. If a person inhales it, the stomach will fester and the limbs will be damaged. And the associated mercury, such as lead, alum, sand, etc., are also toxic." Mercury, which is mercury, is cold and highly toxic, and has a great impact on the environment.
Mercury is highly volatile and can be turned into mercury vapor at room temperature and escape in the air. Once it enters the environment, it will go through a complex process of migration and transformation. In the atmosphere, mercury vapor can be transported over long distances by air currents, causing global pollution. Once it settles in water and soil, mercury will be converted into methylmercury under the action of microorganisms. Methylmercury has strong fat solubility, which is easily enriched in organisms and amplified by the food chain, eventually endangering human health.
Lead and mercury are often accompanied, and lead is also a heavy metal poison. After it enters the environment, it will accumulate in soil and water bodies. Lead in soil can inhibit the absorption of nutrients and water by plant roots, hinder plant growth and development, and reduce crop production. In water bodies, lead can poison aquatic organisms and destroy the balance of aquatic ecology.
Alum substances, if a large amount of water flows into water bodies, will cause eutrophication of water bodies. Plankton such as algae overmultiply due to excess nutrients, consuming a large amount of dissolved oxygen in water, causing aquatic organisms to die of hypoxia and deterioration of water quality.
Although cinnabar is a traditional Chinese medicine and pigment raw material, its main ingredient is mercury sulfide, which also contains mercury. If used improperly or the waste is not disposed of properly, mercury will be released into the environment, causing mercury pollution.
Mercury and its associated minerals are extremely harmful to the environment. Today, it is necessary to mine and utilize mercury-containing resources in a scientific way, properly dispose of mercury-containing wastes, and strengthen environmental monitoring and governance in order to protect the ecological environment and ensure the sustainable development of human society.
Mercury is highly volatile and can be turned into mercury vapor at room temperature and escape in the air. Once it enters the environment, it will go through a complex process of migration and transformation. In the atmosphere, mercury vapor can be transported over long distances by air currents, causing global pollution. Once it settles in water and soil, mercury will be converted into methylmercury under the action of microorganisms. Methylmercury has strong fat solubility, which is easily enriched in organisms and amplified by the food chain, eventually endangering human health.
Lead and mercury are often accompanied, and lead is also a heavy metal poison. After it enters the environment, it will accumulate in soil and water bodies. Lead in soil can inhibit the absorption of nutrients and water by plant roots, hinder plant growth and development, and reduce crop production. In water bodies, lead can poison aquatic organisms and destroy the balance of aquatic ecology.
Alum substances, if a large amount of water flows into water bodies, will cause eutrophication of water bodies. Plankton such as algae overmultiply due to excess nutrients, consuming a large amount of dissolved oxygen in water, causing aquatic organisms to die of hypoxia and deterioration of water quality.
Although cinnabar is a traditional Chinese medicine and pigment raw material, its main ingredient is mercury sulfide, which also contains mercury. If used improperly or the waste is not disposed of properly, mercury will be released into the environment, causing mercury pollution.
Mercury and its associated minerals are extremely harmful to the environment. Today, it is necessary to mine and utilize mercury-containing resources in a scientific way, properly dispose of mercury-containing wastes, and strengthen environmental monitoring and governance in order to protect the ecological environment and ensure the sustainable development of human society.
Scan to WhatsApp
