Linshang Chemical
PRODUCTS
Benzene, 2-Bromo-5-Chloro-1,3-Difluoro-
Linshang Chemical
|
HS Code |
256461 |
| Chemical Formula | C6H2BrClF2 |
As an accredited Benzene, 2-Bromo-5-Chloro-1,3-Difluoro- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100g of 2 - bromo - 5 - chloro - 1,3 - difluorobenzene in a sealed, labeled chemical bottle. |
| Storage | Store “Benzene, 2 - bromo - 5 - chloro - 1,3 - difluoro -” in a cool, well - ventilated area, away from heat, flames, and ignition sources. Keep it in a tightly sealed container, preferably made of corrosion - resistant materials like stainless steel or glass. Store it separately from oxidizing agents, reducing agents, and reactive chemicals to prevent hazardous reactions. |
| Shipping | Ship "2 - bromo - 5 - chloro - 1,3 - difluorobenzene" in well - sealed, corrosion - resistant containers. Follow strict hazardous chemical shipping regulations, ensuring proper labeling and documentation for safe transportation. |
Competitive Benzene, 2-Bromo-5-Chloro-1,3-Difluoro- 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, 2-Bromo-5-Chloro-1,3-Difluoro- in China?
As a trusted Benzene, 2-Bromo-5-Chloro-1,3-Difluoro- 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, 2-Bromo-5-Chloro-1,3-Difluoro- supplier, we deliver high-quality products across diverse grades to meet evolving needs, empowering global customers with safe, efficient, and compliant chemical solutions.
What is the Chinese name of this compound?
What is the Chinese name of this compound, because there is no specific compound-related information mentioned, it is difficult to answer exactly. However, if you follow the classical Chinese style of "Tiangong Kaiwu", try to answer the hypothesis as follows:
All things in the world, there are many categories, and the quality of the compound has its own name. However, you have not mentioned the characteristics, composition, source and other details of this compound, so it is difficult for me to determine its exact name.
As mentioned in Guanfu's "Tiangong Kaiwu", all kinds of substances have their own names. Either according to its shape, or according to its nature, or because of the place used, or the place from which it came. Such as hardware and the like, gold is yellow in color and heavy in quality, and does not corrode for a long time, so it is called "gold"; silver is white in color like the light of silver and Han, and the quality is soft and can be cast, so it is called "silver". And like the medicines made by all kinds of plants and trees, it is named after its efficacy and origin.
If the compound you are asking about today is the genus of gold and stone, its name may be related to its color, texture and hardness. If it is formed by the combination of plants and trees, or is related to the genus of plants and trees, and the method of processing. And if it is produced by the combination of water and fire, and the combination of various things, its name may involve the appearance of change and the power of action.
However, there is no detailed appearance or characteristics as evidence, and it is only based on empty speculation, which is not a good way. If I can tell you in detail about its composition, appearance, and purpose, I will do my best to know it, and use quaint words to clarify its correct name, so that you can solve the doubts in your heart.
All things in the world, there are many categories, and the quality of the compound has its own name. However, you have not mentioned the characteristics, composition, source and other details of this compound, so it is difficult for me to determine its exact name.
As mentioned in Guanfu's "Tiangong Kaiwu", all kinds of substances have their own names. Either according to its shape, or according to its nature, or because of the place used, or the place from which it came. Such as hardware and the like, gold is yellow in color and heavy in quality, and does not corrode for a long time, so it is called "gold"; silver is white in color like the light of silver and Han, and the quality is soft and can be cast, so it is called "silver". And like the medicines made by all kinds of plants and trees, it is named after its efficacy and origin.
If the compound you are asking about today is the genus of gold and stone, its name may be related to its color, texture and hardness. If it is formed by the combination of plants and trees, or is related to the genus of plants and trees, and the method of processing. And if it is produced by the combination of water and fire, and the combination of various things, its name may involve the appearance of change and the power of action.
However, there is no detailed appearance or characteristics as evidence, and it is only based on empty speculation, which is not a good way. If I can tell you in detail about its composition, appearance, and purpose, I will do my best to know it, and use quaint words to clarify its correct name, so that you can solve the doubts in your heart.
What are the characteristics of the molecular structure of this compound?
The molecular properties of this compound are unique. It is as delicate as an artifact.
First, the way atoms are connected is unique. Each atom hooks up with each other according to a specific law, like a delicate tenon and mortise, creating a solid frame. Its corners are all precisely matched, so that the energy is the lowest and it is fixed. This characterization makes the compound able to maintain its inherent characteristics under various conditions, and it is not easy to be biodegradable.
For the second time, the empty shape of the molecule is also exquisite. Or it is arranged in a precise way, such as empty space, which is extraordinary; or it is set up in the shape of a box, which is like a strange box, hidden in mystery. For example, some vertical types can make it have a specific optical rotation, which has a special appearance in the optical domain; while the organic type may affect its solubility in certain solutions.
Furthermore, the distribution of functional properties is also an important property of molecules. Different functional properties can give compounds their chemical activity. Or it can give rise to nuclear substitution of other substances, or it can perform the opposite of oxidizing. Functional properties also affect each other, and their sub-effects affect each other. Atomic connection, empty space type, and functional distribution are combined to shape their unique characteristics and functions, and to display their charm and power in the world of transformation.
First, the way atoms are connected is unique. Each atom hooks up with each other according to a specific law, like a delicate tenon and mortise, creating a solid frame. Its corners are all precisely matched, so that the energy is the lowest and it is fixed. This characterization makes the compound able to maintain its inherent characteristics under various conditions, and it is not easy to be biodegradable.
For the second time, the empty shape of the molecule is also exquisite. Or it is arranged in a precise way, such as empty space, which is extraordinary; or it is set up in the shape of a box, which is like a strange box, hidden in mystery. For example, some vertical types can make it have a specific optical rotation, which has a special appearance in the optical domain; while the organic type may affect its solubility in certain solutions.
Furthermore, the distribution of functional properties is also an important property of molecules. Different functional properties can give compounds their chemical activity. Or it can give rise to nuclear substitution of other substances, or it can perform the opposite of oxidizing. Functional properties also affect each other, and their sub-effects affect each other. Atomic connection, empty space type, and functional distribution are combined to shape their unique characteristics and functions, and to display their charm and power in the world of transformation.
What are the possible chemical properties of this compound?
This compound may have the following chemical properties:
First, in terms of acidity and alkalinity, if it contains a carboxyl group (-COOH), it is acidic and can be neutralized with bases. For example, acetic acid reacts with sodium hydroxide to form sodium acetate and water. If it contains an amino group (-NH2O), it is alkaline, like ammonia can react with acids to form ammonium salts.
Second, it is redox and contains unsaturated bonds, such as carbon-carbon double bonds (C = C) and carbon-carbon triple bonds (C ≡ C), which are easily oxidized. Take ethylene as an example, it can be oxidized by acidic potassium permanganate solution to make it fade. At the same time, if an element in the compound is in a low-priced state, such as ferrous ions (Fe ² ²), it is reductive and can be oxidized to a high-valence state by strong oxidants. If there are high-valence elements, such as manganese in potassium permanganate, at + 7 valence, it has strong oxidizing properties and can oxidize other substances.
Third, the nature of the substitution reaction, if there is an alkyl group in the molecule, under light conditions, the hydrogen atom on the alkyl group is easily replaced by a halogen atom. Taking the reaction of methane and chlorine as an example, when the light is irradiated, the hydrogen atom in the methane molecule is gradually replaced by the chlorine atom to form monochloromethane, dichloromethane, trichloromethane and carbon tetrachloride. If there is a benzene ring structure, the hydrogen atom on the benzene ring can be replaced by nit
Fourth, addition reaction properties, compounds containing carbon-carbon double bonds and carbon-carbon triple bonds can be added to hydrogen, halogen elements, hydrogen halide, etc. For example, ethylene and hydrogen can be added to form ethane under the action of a catalyst; acetylene and hydrogen chloride can be added to form vinyl chloride.
Fifth, hydrolysis reaction properties, if it is an ester compound, it can be hydrolyzed under the catalysis of an acid or a base. Like ethyl acetate hydrolyzed under acidic conditions to form acetic acid and ethanol; under alkaline conditions, hydrolysis is more thorough, resulting in acetate and ethanol. If it is a halogenated hydrocarbon, it will be hydrolyzed to form alcohol when heated in an aqueous solution of sodium hydroxide.
First, in terms of acidity and alkalinity, if it contains a carboxyl group (-COOH), it is acidic and can be neutralized with bases. For example, acetic acid reacts with sodium hydroxide to form sodium acetate and water. If it contains an amino group (-NH2O), it is alkaline, like ammonia can react with acids to form ammonium salts.
Second, it is redox and contains unsaturated bonds, such as carbon-carbon double bonds (C = C) and carbon-carbon triple bonds (C ≡ C), which are easily oxidized. Take ethylene as an example, it can be oxidized by acidic potassium permanganate solution to make it fade. At the same time, if an element in the compound is in a low-priced state, such as ferrous ions (Fe ² ²), it is reductive and can be oxidized to a high-valence state by strong oxidants. If there are high-valence elements, such as manganese in potassium permanganate, at + 7 valence, it has strong oxidizing properties and can oxidize other substances.
Third, the nature of the substitution reaction, if there is an alkyl group in the molecule, under light conditions, the hydrogen atom on the alkyl group is easily replaced by a halogen atom. Taking the reaction of methane and chlorine as an example, when the light is irradiated, the hydrogen atom in the methane molecule is gradually replaced by the chlorine atom to form monochloromethane, dichloromethane, trichloromethane and carbon tetrachloride. If there is a benzene ring structure, the hydrogen atom on the benzene ring can be replaced by nit
Fourth, addition reaction properties, compounds containing carbon-carbon double bonds and carbon-carbon triple bonds can be added to hydrogen, halogen elements, hydrogen halide, etc. For example, ethylene and hydrogen can be added to form ethane under the action of a catalyst; acetylene and hydrogen chloride can be added to form vinyl chloride.
Fifth, hydrolysis reaction properties, if it is an ester compound, it can be hydrolyzed under the catalysis of an acid or a base. Like ethyl acetate hydrolyzed under acidic conditions to form acetic acid and ethanol; under alkaline conditions, hydrolysis is more thorough, resulting in acetate and ethanol. If it is a halogenated hydrocarbon, it will be hydrolyzed to form alcohol when heated in an aqueous solution of sodium hydroxide.
In what fields might this compound have applications?
This compound has a wide range of applications. In the field of medicine, it may be used to develop new medicines. The ancient medicine and the combination of medicine and stone have their own effects. Today's compound may act precisely on the focus and help heal the disease.
In the context of agriculture, it may be able to contribute to the growth of fertile soil. In ancient agriculture, natural things were used to fertilize the field. Today's compound may be able to adjust the ratio of nutrients according to the nature of the soil and the needs of the plant, so that the crop is lush and the people's livelihood is prosperous.
In the domain of industry, its use is also diverse. Such as manufacturing equipment, the compound may increase the toughness and durability of the device, making it durable. The ancient equipment was made of limited materials. Nowadays, it relies on this compound, and the technology of industry is improving day by day, and the energy of the equipment is getting stronger and stronger.
For the genus of daily use, it may also have its own function. Such as all kinds of fabrics and utensils, which are treated with compound materials, or have the effects of waterproofing, anti-wear and color enhancement, making the daily use more suitable and convenient for life.
Furthermore, in the construction industry, compound materials may improve the quality of building materials. Ancient construction is based on earth, stone and wood. Today's compound materials can make building materials fire-resistant, heat-insulating and earthquake-resistant, building a stable residence and a safe place for the people. Therefore, this compound may have considerable applications in the fields of medicine, agriculture, industry, daily use, and construction, contributing to the progress of the world and the well-being of the people.
In the context of agriculture, it may be able to contribute to the growth of fertile soil. In ancient agriculture, natural things were used to fertilize the field. Today's compound may be able to adjust the ratio of nutrients according to the nature of the soil and the needs of the plant, so that the crop is lush and the people's livelihood is prosperous.
In the domain of industry, its use is also diverse. Such as manufacturing equipment, the compound may increase the toughness and durability of the device, making it durable. The ancient equipment was made of limited materials. Nowadays, it relies on this compound, and the technology of industry is improving day by day, and the energy of the equipment is getting stronger and stronger.
For the genus of daily use, it may also have its own function. Such as all kinds of fabrics and utensils, which are treated with compound materials, or have the effects of waterproofing, anti-wear and color enhancement, making the daily use more suitable and convenient for life.
Furthermore, in the construction industry, compound materials may improve the quality of building materials. Ancient construction is based on earth, stone and wood. Today's compound materials can make building materials fire-resistant, heat-insulating and earthquake-resistant, building a stable residence and a safe place for the people. Therefore, this compound may have considerable applications in the fields of medicine, agriculture, industry, daily use, and construction, contributing to the progress of the world and the well-being of the people.
What is the preparation method of this compound?
The method of preparing a chemical compound is related to many chemical principles and techniques. This imitation of "Tiangong Kaiwu" is described in Chinese.
When making a chemical compound, the first thing to do is to understand its chemical properties, understand its composition, and clarify the rules of each compound. If making metal salts, the metal and the corresponding acid are often used as the starting materials. If making copper sulfate, take copper as the quality first and put it in the utensils. Copper is metallic, strong and malleable.
Prepare an appropriate amount of dilute sulfuric acid and slowly pour it into the copper container. Sulfuric acid, strong acid is also corrosive, and caution is required when operating. The two meet, and there is no significant appearance at first. However, with slight heat, copper gradually combines with sulfuric acid. Cover heat can promote the movement of its molecules and increase the rate of reaction.
During the reaction process, bubbles can be seen gradually forming, which is the gas produced by the chemical reaction. The color of the solution also gradually changes from colorless to blue, because of the color development of copper ions in the solution. When the reaction is complete, the solution is a solution of copper sulfate.
If you want to obtain the solid of copper sulfate, you can heat and evaporate this solution. With the gradual loss of water, the concentration of the solution gradually increases, and to a certain extent, copper sulfate precipitates as a crystal. At this time, it can be collected with a clean device to obtain copper sulfate crystals.
Another example is the preparation of organic compounds, often by organic reaction. For example, in the esterification reaction, alcohol and carboxylic acid are taken as materials, and concentrated sulfuric acid is added as a catalyst. Under the catalysis of concentrated sulfuric acid, alcohol and carboxylic acid are co-heated to undergo esterification reaction, resulting in ester and water. Esters have a special aroma, and this reaction process also needs to pay attention to the ratio of temperature to raw materials. Improper proportions will affect the yield.
In short, the preparation of compounds requires careful observation of the properties of each substance, following the laws of chemistry, and being careful about operation and controlling its conditions. Only then can the desired compounds be obtained and the desired ones can be obtained.
When making a chemical compound, the first thing to do is to understand its chemical properties, understand its composition, and clarify the rules of each compound. If making metal salts, the metal and the corresponding acid are often used as the starting materials. If making copper sulfate, take copper as the quality first and put it in the utensils. Copper is metallic, strong and malleable.
Prepare an appropriate amount of dilute sulfuric acid and slowly pour it into the copper container. Sulfuric acid, strong acid is also corrosive, and caution is required when operating. The two meet, and there is no significant appearance at first. However, with slight heat, copper gradually combines with sulfuric acid. Cover heat can promote the movement of its molecules and increase the rate of reaction.
During the reaction process, bubbles can be seen gradually forming, which is the gas produced by the chemical reaction. The color of the solution also gradually changes from colorless to blue, because of the color development of copper ions in the solution. When the reaction is complete, the solution is a solution of copper sulfate.
If you want to obtain the solid of copper sulfate, you can heat and evaporate this solution. With the gradual loss of water, the concentration of the solution gradually increases, and to a certain extent, copper sulfate precipitates as a crystal. At this time, it can be collected with a clean device to obtain copper sulfate crystals.
Another example is the preparation of organic compounds, often by organic reaction. For example, in the esterification reaction, alcohol and carboxylic acid are taken as materials, and concentrated sulfuric acid is added as a catalyst. Under the catalysis of concentrated sulfuric acid, alcohol and carboxylic acid are co-heated to undergo esterification reaction, resulting in ester and water. Esters have a special aroma, and this reaction process also needs to pay attention to the ratio of temperature to raw materials. Improper proportions will affect the yield.
In short, the preparation of compounds requires careful observation of the properties of each substance, following the laws of chemistry, and being careful about operation and controlling its conditions. Only then can the desired compounds be obtained and the desired ones can be obtained.
Scan to WhatsApp
