Linshang Chemical
PRODUCTS
1-Bromo-5-Chloro-3-Fluoro-2-Iodo-Benzene
Linshang Chemical
|
HS Code |
829938 |
| Chemical Formula | C6H2BrClFI |
| Molecular Weight | 329.34 |
| Appearance | Solid (predicted) |
| Solubility In Water | Insoluble (predicted) |
| Solubility In Organic Solvents | Soluble in common organic solvents (predicted) |
| Hazard Class | Irritant (predicted) |
As an accredited 1-Bromo-5-Chloro-3-Fluoro-2-Iodo-Benzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100g of 1 - bromo - 5 - chloro - 3 - fluoro - 2 - iodo - benzene in a sealed glass bottle. |
| Storage | 1 - Bromo - 5 - chloro - 3 - fluoro - 2 - iodobenzene 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 exposure to air and moisture, which could potentially lead to degradation. Store it separately from oxidizing agents and reactive chemicals to avoid unwanted reactions. |
| Shipping | 1 - bromo - 5 - chloro - 3 - fluoro - 2 - iodo - benzene is a hazardous chemical. It should be shipped in well - sealed, specialized containers, following all relevant regulations for transporting chemicals to ensure safety during transit. |
Competitive 1-Bromo-5-Chloro-3-Fluoro-2-Iodo-Benzene 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-5-Chloro-3-Fluoro-2-Iodo-Benzene in China?
As a trusted 1-Bromo-5-Chloro-3-Fluoro-2-Iodo-Benzene 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-5-Chloro-3-Fluoro-2-Iodo-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-5-chloro-3-fluoro-2-iodobenzene?
The substances "1 mercury-5 bromo-3 iodine-2 astatine" inquired by the observer are all genera of halogen elements, each with unique physical properties.
Mercury is a liquid metal at room temperature, with silver flickering, heavy and flowing. Its melting point is extremely low, about -38.87 ° C, and its boiling point is only 356.6 ° C. Mercury has good electrical conductivity and high surface tension, and often aggregates into beads. Because of its liquid state, it is easy to flow and evaporate, and the vapor is toxic, so it needs to be handled with caution.
Bromine is a dark reddish-brown liquid at room temperature and pressure, and is the only non-metallic element that is liquid at room temperature. Its melting point is -7.2 ° C, boiling point is 58.8 ° C. It is highly volatile, emits a pungent smell, and is highly corrosive. Bromine has a higher density than water and is slightly soluble in water, but easily soluble in organic solvents, such as carbon tetrachloride.
Iodine is usually a purple-black solid with a metallic luster. Melting point is 113.5 ° C, boiling point is 184.35 ° C. The remarkable characteristic of iodine is sublimation, that is, when heated without going through a liquid state, it directly changes from a solid state to a gaseous state, forming a beautiful purple vapor. Iodine has very little solubility in water, but it has a greater solubility in organic solvents such as alcohol. Iodine is an alcoholic solution of iodine.
Iodine is a very unstable radioactive element, and the content is very small in nature. Due to its radioactivity and short half-life, the study of its physical properties is quite limited. It is speculated that astatine should be in a solid state, with a black color, and a higher melting point and boiling point than bromine and iodine.
These substances, among the halogen elements, also show regular changes in physical properties due to the gradual change of atomic structure. From the liquid state of bromine to the solid state of iodine and astatine, the melting and boiling point gradually increases, adding many wonders and mysteries to the laws of chemical research to reveal the characteristics of elements.
Mercury is a liquid metal at room temperature, with silver flickering, heavy and flowing. Its melting point is extremely low, about -38.87 ° C, and its boiling point is only 356.6 ° C. Mercury has good electrical conductivity and high surface tension, and often aggregates into beads. Because of its liquid state, it is easy to flow and evaporate, and the vapor is toxic, so it needs to be handled with caution.
Bromine is a dark reddish-brown liquid at room temperature and pressure, and is the only non-metallic element that is liquid at room temperature. Its melting point is -7.2 ° C, boiling point is 58.8 ° C. It is highly volatile, emits a pungent smell, and is highly corrosive. Bromine has a higher density than water and is slightly soluble in water, but easily soluble in organic solvents, such as carbon tetrachloride.
Iodine is usually a purple-black solid with a metallic luster. Melting point is 113.5 ° C, boiling point is 184.35 ° C. The remarkable characteristic of iodine is sublimation, that is, when heated without going through a liquid state, it directly changes from a solid state to a gaseous state, forming a beautiful purple vapor. Iodine has very little solubility in water, but it has a greater solubility in organic solvents such as alcohol. Iodine is an alcoholic solution of iodine.
Iodine is a very unstable radioactive element, and the content is very small in nature. Due to its radioactivity and short half-life, the study of its physical properties is quite limited. It is speculated that astatine should be in a solid state, with a black color, and a higher melting point and boiling point than bromine and iodine.
These substances, among the halogen elements, also show regular changes in physical properties due to the gradual change of atomic structure. From the liquid state of bromine to the solid state of iodine and astatine, the melting and boiling point gradually increases, adding many wonders and mysteries to the laws of chemical research to reveal the characteristics of elements.
What are the chemical properties of 1-bromo-5-chloro-3-fluoro-2-iodobenzene?
Mercury, bromine, iodine, and astatine are all involved in halogen elements and each has unique chemical properties.
Mercury is a liquid metal at room temperature, shining with silver light. Its volatility is very strong, and the vapor is toxic. Mercury is relatively stable chemically, and it is not easy to combine with oxygen at room temperature. However, when heated, it can react with oxygen to form mercury oxide. In case of sulfur, the two quickly combine to form mercury sulfide, which is a common method for dealing with mercury leakage.
Bromine is a dark reddish-brown liquid non-metallic, volatile, pungent and highly corrosive. Bromine is chemically active and is a strong oxidant. It can oxidize many substances in solution, such as ferrous ions to iron ions. It reacts with metal elements to form corresponding bromide.
Iodine, a purple-black solid, has sublimation properties, and can be directly changed from solid to gaseous when heated. Iodine elemental oxidation is slightly weaker than bromine, but it can also react with many metals and non-metals. When iodine encounters starch, it will show a unique blue color, which is a common method for testing iodine.
Astatine is a radioactive element, which is extremely unstable and highly radioactive. Due to its short half-life, research is relatively limited. Astatine has chemical properties similar to bromine and iodine, and is an active non-metal. In theory, it can chemically react with a variety of substances. However, due to its radioactivity, experimental operations are extremely difficult.
Although these four substances are all related to the halogen group, due to differences in atomic structure, their chemical properties are also different in similarity, and each has its own unique position and role in the field of chemistry.
Mercury is a liquid metal at room temperature, shining with silver light. Its volatility is very strong, and the vapor is toxic. Mercury is relatively stable chemically, and it is not easy to combine with oxygen at room temperature. However, when heated, it can react with oxygen to form mercury oxide. In case of sulfur, the two quickly combine to form mercury sulfide, which is a common method for dealing with mercury leakage.
Bromine is a dark reddish-brown liquid non-metallic, volatile, pungent and highly corrosive. Bromine is chemically active and is a strong oxidant. It can oxidize many substances in solution, such as ferrous ions to iron ions. It reacts with metal elements to form corresponding bromide.
Iodine, a purple-black solid, has sublimation properties, and can be directly changed from solid to gaseous when heated. Iodine elemental oxidation is slightly weaker than bromine, but it can also react with many metals and non-metals. When iodine encounters starch, it will show a unique blue color, which is a common method for testing iodine.
Astatine is a radioactive element, which is extremely unstable and highly radioactive. Due to its short half-life, research is relatively limited. Astatine has chemical properties similar to bromine and iodine, and is an active non-metal. In theory, it can chemically react with a variety of substances. However, due to its radioactivity, experimental operations are extremely difficult.
Although these four substances are all related to the halogen group, due to differences in atomic structure, their chemical properties are also different in similarity, and each has its own unique position and role in the field of chemistry.
What are the main uses of 1-bromo-5-chloro-3-fluoro-2-iodobenzene?
1.
, also known as "long", its main use is mostly related to grain processing. In ancient times, grains needed to be shelled and other treatments before they could be eaten.
It is often made of bamboo, wood, stone and other materials. By rotating the upper and lower grinding discs, the shell of the grain is ground off, making the grain edible rice, providing basic protection for the people's daily diet.
2. The retort was an important cooking utensil in ancient times. It was generally made of pottery or bronze, and there were many small holes at the bottom that were breathable. When in use, the retort was placed on the retort or kettle, and the water in the kettle was heated and boiled to produce steam. The food in the retort was steamed through the small holes in the bottom of the retort. Whether it is the steaming of rice or the cooking of various ingredients, retort plays a key role, greatly enriching the diet and cooking methods of the ancients.
3,
, is a composite cooking utensil that integrates the functions of retort and retort. The upper part is retort, which is used to place food; the lower part is retort, which is used to boil water. The middle is separated by a grate, and steam rises through the grate hole to steam the food.
It is quite common in ancient sacrifices, feasts and other occasions. It not only meets the dietary needs of many people, but also because of its unique shape and function, it has become one of the ritual vessels to highlight the status, reflecting the food culture and etiquette system of the time.
4,
, is mainly used for sacrifices and ceremonial activities. It is usually made of bamboo At the time of sacrifice, jujube, chestnut, peach, dried meat and other offerings are placed in the bowl to express respect and offering to gods or ancestors. At the same time, in some major ceremonial occasions, such as noble banquets, the bowl is also used to hold preserved fruit and other foods, which is an important tool to reflect ceremonial norms and hierarchical order.
, also known as "long", its main use is mostly related to grain processing. In ancient times, grains needed to be shelled and other treatments before they could be eaten.
It is often made of bamboo, wood, stone and other materials. By rotating the upper and lower grinding discs, the shell of the grain is ground off, making the grain edible rice, providing basic protection for the people's daily diet.
2. The retort was an important cooking utensil in ancient times. It was generally made of pottery or bronze, and there were many small holes at the bottom that were breathable. When in use, the retort was placed on the retort or kettle, and the water in the kettle was heated and boiled to produce steam. The food in the retort was steamed through the small holes in the bottom of the retort. Whether it is the steaming of rice or the cooking of various ingredients, retort plays a key role, greatly enriching the diet and cooking methods of the ancients.
3,
, is a composite cooking utensil that integrates the functions of retort and retort. The upper part is retort, which is used to place food; the lower part is retort, which is used to boil water. The middle is separated by a grate, and steam rises through the grate hole to steam the food.
It is quite common in ancient sacrifices, feasts and other occasions. It not only meets the dietary needs of many people, but also because of its unique shape and function, it has become one of the ritual vessels to highlight the status, reflecting the food culture and etiquette system of the time.
4,
, is mainly used for sacrifices and ceremonial activities. It is usually made of bamboo At the time of sacrifice, jujube, chestnut, peach, dried meat and other offerings are placed in the bowl to express respect and offering to gods or ancestors. At the same time, in some major ceremonial occasions, such as noble banquets, the bowl is also used to hold preserved fruit and other foods, which is an important tool to reflect ceremonial norms and hierarchical order.
What are the synthesis methods of 1-bromo-5-chloro-3-fluoro-2-iodobenzene?
"Tiangong Kaiwu" is a scientific and technological masterpiece written by Song Yingxing in the Ming Dynasty, in which many processes and technologies are described in detail. However, the synthesis method of "1 + - + alkali + - + 5 + - + halogen + - + 3 + - + water + - + 2 + - + soap pods" is not directly recorded in the book. However, possible synthesis methods can be deduced based on the principles of ancient chemical processes and related records.
In ancient times, alkali was mostly trans-alkali or prepared from plant ash. Trans-alkali is often harvested from alkali lakes and other places, while plant ash contains potassium carbonate, which can be obtained by water leaching and other processes. Brine often refers to brine, which is rich in various salts, or is harvested from salt lakes, salt wells and other places. Water is a common solvent and is indispensable in many chemical reactions. Soappods have the properties of decontamination and are often used as detergents in ancient times.
To synthesize this substance, one method may be to mix tronium alkali or treated plant ash alkali solution with brine. The composition of brine is complex, in which salt may react with alkali. For example, some metal ion halides react with potassium carbonate or form new substances such as precipitation. This process requires controlling the ratio of alkali to halogen, and the ratio of 1 part alkali to 5 parts halogen may be determined by repeated experiments. When mixing, slowly pour the alkali solution into the brine and stir continuously to make the reaction fully proceed.
Then add 3 parts of water to dilute the mixture. On the one hand, adding water can promote the further occurrence of the reaction, so that the components can better dissolve, disperse and participate in the reaction; on the other hand, or prepare for the subsequent addition of soappods. After the mixed solution has reacted for a certain period of time and the components are uniform, add 2 parts of soappods. Soappods are added or ground into powder, and the ingredients contained in them may interact with the substances in the mixed solution to change the properties of the mixed solution, such as enhancing its decontamination ability or producing special chemical or physical changes.
The entire synthesis process may require attention to factors such as reaction temperature and time. In ancient times or at room temperature, the reaction time depends on the observation of phenomena, such as precipitation formation, solution color change, etc. After this step, the synthetic product of "1 + - + alkali + - + 5 + - + halogen + - + 3 + - + water + - + 2 + - + soap pod" may be obtained.
In ancient times, alkali was mostly trans-alkali or prepared from plant ash. Trans-alkali is often harvested from alkali lakes and other places, while plant ash contains potassium carbonate, which can be obtained by water leaching and other processes. Brine often refers to brine, which is rich in various salts, or is harvested from salt lakes, salt wells and other places. Water is a common solvent and is indispensable in many chemical reactions. Soappods have the properties of decontamination and are often used as detergents in ancient times.
To synthesize this substance, one method may be to mix tronium alkali or treated plant ash alkali solution with brine. The composition of brine is complex, in which salt may react with alkali. For example, some metal ion halides react with potassium carbonate or form new substances such as precipitation. This process requires controlling the ratio of alkali to halogen, and the ratio of 1 part alkali to 5 parts halogen may be determined by repeated experiments. When mixing, slowly pour the alkali solution into the brine and stir continuously to make the reaction fully proceed.
Then add 3 parts of water to dilute the mixture. On the one hand, adding water can promote the further occurrence of the reaction, so that the components can better dissolve, disperse and participate in the reaction; on the other hand, or prepare for the subsequent addition of soappods. After the mixed solution has reacted for a certain period of time and the components are uniform, add 2 parts of soappods. Soappods are added or ground into powder, and the ingredients contained in them may interact with the substances in the mixed solution to change the properties of the mixed solution, such as enhancing its decontamination ability or producing special chemical or physical changes.
The entire synthesis process may require attention to factors such as reaction temperature and time. In ancient times or at room temperature, the reaction time depends on the observation of phenomena, such as precipitation formation, solution color change, etc. After this step, the synthetic product of "1 + - + alkali + - + 5 + - + halogen + - + 3 + - + water + - + 2 + - + soap pod" may be obtained.
What are the precautions for storing and transporting 1-bromo-5-chloro-3-fluoro-2-iodobenzene?
The industry of smelting and casting is related to people's livelihood, and all things are complicated. All things must be cautious in melting, storage and transportation.
When smelting and casting, the firepower should be appropriate, otherwise the molten gold will be difficult to even and the quality will not be good. If smelting copper is used as a tool, the copper will be difficult to melt if the fire is small, and the copper will be vulnerable if the fire is fierce. It is necessary to use a moderate fire to make the copper pure.
When it is stored, the first heavy container. The tool containing the molten gold must be resistant to hot topics and not leak. If the container is not good, the molten gold will spill, which will not only cause material loss, but also be easy to hurt people. The storage place should also be dry and protected from moisture to prevent
As for transportation, the road should be smooth, and the journey should be steady. When the liquid gold is ready, it will be transported elsewhere. If the road is rough, the vehicle is bumpy, and the liquid gold splashes out, it will fall short. And the escort should be vigilant to prevent unexpected changes. In case of water and fire disasters or robbers, they must be able to deal with it well.
The business of smelting, smelting, storing, and transporting all things are interconnected. There is a slight mistake, and the consequences are unpredictable. Practitioners must be careful and rigorous, so as to ensure that all things go well, and their skills are successful and their careers are prosperous.
When smelting and casting, the firepower should be appropriate, otherwise the molten gold will be difficult to even and the quality will not be good. If smelting copper is used as a tool, the copper will be difficult to melt if the fire is small, and the copper will be vulnerable if the fire is fierce. It is necessary to use a moderate fire to make the copper pure.
When it is stored, the first heavy container. The tool containing the molten gold must be resistant to hot topics and not leak. If the container is not good, the molten gold will spill, which will not only cause material loss, but also be easy to hurt people. The storage place should also be dry and protected from moisture to prevent
As for transportation, the road should be smooth, and the journey should be steady. When the liquid gold is ready, it will be transported elsewhere. If the road is rough, the vehicle is bumpy, and the liquid gold splashes out, it will fall short. And the escort should be vigilant to prevent unexpected changes. In case of water and fire disasters or robbers, they must be able to deal with it well.
The business of smelting, smelting, storing, and transporting all things are interconnected. There is a slight mistake, and the consequences are unpredictable. Practitioners must be careful and rigorous, so as to ensure that all things go well, and their skills are successful and their careers are prosperous.
Scan to WhatsApp
