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3,4,5,6-Tetrachlorobenzene-1,2-Dicarboxylic Acid
Linshang Chemical
|
HS Code |
692668 |
| Name | 3,4,5,6-Tetrachlorobenzene-1,2-Dicarboxylic Acid |
| Molecular Formula | C8H2Cl4O4 |
| Molecular Weight | 303.91 g/mol |
| Appearance | Solid (presumed, common for such organic acids) |
| Solubility In Water | Low (organic acids with chlorinated aromatic rings are generally sparingly soluble in water) |
| Melting Point | Data specific to this compound would need to be sourced from literature |
| Boiling Point | Data specific to this compound would need to be sourced from literature |
| Density | Data specific to this compound would need to be sourced from literature |
| Pka | Data specific to this compound would need to be sourced from literature |
| Vapor Pressure | Low (due to its solid state and relatively high molecular weight) |
As an accredited 3,4,5,6-Tetrachlorobenzene-1,2-Dicarboxylic Acid factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 500g of 3,4,5,6 - tetrachlorobenzene - 1,2 - dicarboxylic acid packaged in sealed plastic bags. |
| Storage | 3,4,5,6 - tetrachlorobenzene - 1,2 - dicarboxylic acid should be stored in a cool, dry, well - ventilated area. Keep it away from sources of heat, ignition, and incompatible substances like strong oxidizing agents. Store in a tightly - sealed container, preferably made of corrosion - resistant material, to prevent leakage and contamination. |
| Shipping | 3,4,5,6 - tetrachlorobenzene - 1,2 - dicarboxylic acid is shipped in well - sealed containers, following strict chemical transportation regulations. Packaging ensures no leakage during transit to safeguard handlers and the environment. |
Competitive 3,4,5,6-Tetrachlorobenzene-1,2-Dicarboxylic Acid 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.
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Tel: +8615365006308
Email: info@alchemist-chem.com
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What are the chemical properties of 3,4,5,6-tetrachlorobenzene-1,2-dicarboxylic acid
Trivalent boron, tetravalent carbon, pentavalent nitrogen, and hexavalent oxygen are common valence states of chemical elements. Monovalent hydrogen and divalent sulfur are also common valence states.
Carbon tetrachloride, its properties are stable, and it is a colorless, transparent and volatile liquid at room temperature and pressure. It is insoluble in water and can be miscible with most organic solvents. It has certain toxicity and was often used as a fire extinguishing agent in the past, but now it is less used because of its destructive effect on the ozone layer.
Carbon disulfide, a colorless or yellowish transparent liquid at room temperature and pressure, is also volatile and has a foul odor. It is flammable, and its vapor and air can form an explosive mixture, which can cause combustion and explosion in case of open flame and high heat energy. Carbon disulfide can be used to make rayon, pesticides, etc. However, it is also toxic to the human body and can damage the nervous system and liver and other organs.
These all have unique chemical properties and have their own uses in chemical industry, scientific research and other fields. However, they need to be treated with caution to avoid harm.
Carbon tetrachloride, its properties are stable, and it is a colorless, transparent and volatile liquid at room temperature and pressure. It is insoluble in water and can be miscible with most organic solvents. It has certain toxicity and was often used as a fire extinguishing agent in the past, but now it is less used because of its destructive effect on the ozone layer.
Carbon disulfide, a colorless or yellowish transparent liquid at room temperature and pressure, is also volatile and has a foul odor. It is flammable, and its vapor and air can form an explosive mixture, which can cause combustion and explosion in case of open flame and high heat energy. Carbon disulfide can be used to make rayon, pesticides, etc. However, it is also toxic to the human body and can damage the nervous system and liver and other organs.
These all have unique chemical properties and have their own uses in chemical industry, scientific research and other fields. However, they need to be treated with caution to avoid harm.
In which fields is 3,4,5,6-tetrachlorobenzene-1,2-dicarboxylic acid used?
Carbon trioxide, nitrous oxide, phosphorus pentoxide, and sulfur hexafluoride are all commonly used in the chemical industry, electronics, and other fields. Carbon trioxide may have applications in metallurgy and other industries, and can participate in some chemical reactions and help ore refining. Nitrous oxide is mostly used in rocket propellants. Because of its strong oxidation, it can react violently with fuels and provide strong thrust. It is an indispensable element in the journey of aerospace exploration. Phosphorus pentoxide has strong water absorption and is often used as a desiccant. It is used in chemical production and laboratories to ensure a dry environment and prevent materials from being damp and deteriorated. Sulfur hexafluoride has excellent insulation and arc extinguishing properties. It is widely used in high-voltage switches, transformers and other equipment in power systems to ensure safe and stable power transmission.
As for carbon monoxide and carbon dioxide, although carbon monoxide is toxic, it can be used as a reducing agent in the metallurgical industry to help metals recover and precipitate from its oxides. Carbon dioxide is more widely used, filling it into carbonated beverages in the beverage industry; in agriculture, it can be used as a gas fertilizer to promote plant photosynthesis and increase crop yield; in the field of fire protection, because it does not support combustion and has a higher density than air, it is often used as a fire extinguishing agent to extinguish flames.
To sum up, these numbers have important applications in many fields such as chemical industry, aerospace, electric power, agriculture, fire protection, etc., and have made great contributions to the development of production and life.
As for carbon monoxide and carbon dioxide, although carbon monoxide is toxic, it can be used as a reducing agent in the metallurgical industry to help metals recover and precipitate from its oxides. Carbon dioxide is more widely used, filling it into carbonated beverages in the beverage industry; in agriculture, it can be used as a gas fertilizer to promote plant photosynthesis and increase crop yield; in the field of fire protection, because it does not support combustion and has a higher density than air, it is often used as a fire extinguishing agent to extinguish flames.
To sum up, these numbers have important applications in many fields such as chemical industry, aerospace, electric power, agriculture, fire protection, etc., and have made great contributions to the development of production and life.
What is the preparation method of 3,4,5,6-tetrachlorobenzene-1,2-dicarboxylic acid?
To prepare silicon tetrachloride and secondary acid, the method is as follows:
First take an appropriate amount of 3%, 4%, 5%, 6% of the matter, these four substances or silicon-containing raw materials, need to be carefully prepared, check its purity and texture, do not let impurities disturb it. And prepare another important substance required for silicon tetrachloride, that is, chlorine-related reactants, whose quantity and quality also need to be precisely controlled.
In a special appliance, put the silicon-containing raw materials and chlorine-related substances in an appropriate proportion and order. When operating, be careful and pay attention to the reaction conditions. For example, the temperature should be controlled by suitable heat conditions. If it is overheated, the reaction will be too fast, and accidents may occur. If it is too cold, the reaction will be slow and time-consuming. The pressure should also be adjusted to an appropriate degree so that the two can fully react to form silicon tetrachloride. During the process, gas may escape, and it should be collected and treated in a reasonable way so as not to pollute the environment.
As for the preparation of secondary acid, take 1% or 2% of the matter first. These two may be the basic raw materials for acid production. Place it in a specific reactor and add an appropriate amount of catalyst. This catalyst can promote the reaction speed and increase the amount of product. Similarly, conditions such as temperature and pressure need to be strictly controlled. Observe the process of the reaction and adjust it in a timely manner to fully convert the raw material into secondary acid. After the reaction is completed, the product is purified by a fine method to remove impurities and obtain pure secondary acid.
Preparation of these two requires fine operation in each step and follows the rules to obtain high-quality products.
First take an appropriate amount of 3%, 4%, 5%, 6% of the matter, these four substances or silicon-containing raw materials, need to be carefully prepared, check its purity and texture, do not let impurities disturb it. And prepare another important substance required for silicon tetrachloride, that is, chlorine-related reactants, whose quantity and quality also need to be precisely controlled.
In a special appliance, put the silicon-containing raw materials and chlorine-related substances in an appropriate proportion and order. When operating, be careful and pay attention to the reaction conditions. For example, the temperature should be controlled by suitable heat conditions. If it is overheated, the reaction will be too fast, and accidents may occur. If it is too cold, the reaction will be slow and time-consuming. The pressure should also be adjusted to an appropriate degree so that the two can fully react to form silicon tetrachloride. During the process, gas may escape, and it should be collected and treated in a reasonable way so as not to pollute the environment.
As for the preparation of secondary acid, take 1% or 2% of the matter first. These two may be the basic raw materials for acid production. Place it in a specific reactor and add an appropriate amount of catalyst. This catalyst can promote the reaction speed and increase the amount of product. Similarly, conditions such as temperature and pressure need to be strictly controlled. Observe the process of the reaction and adjust it in a timely manner to fully convert the raw material into secondary acid. After the reaction is completed, the product is purified by a fine method to remove impurities and obtain pure secondary acid.
Preparation of these two requires fine operation in each step and follows the rules to obtain high-quality products.
What are the environmental effects of 3,4,5,6-tetrachlorobenzene-1,2-dicarboxylic acid
Today, there are 3% 2C4% 2C5% 2C6, which is a genus of tetraalkane, and 1% 2C2, which is a diolefin. The impact of these two on the environment is really related to the change of heaven and earth, which cannot be ignored.
Tetraalkane and the like, 3% 2C4% 2C5% 2C6, their properties are relatively stable, and they are mostly gaseous or liquid at room temperature. In the atmosphere, if a large amount of escape, although it does not directly harm the life of organisms, it can cause the greenhouse effect to gradually strengthen. Because it is exposed to sunlight, it can absorb infrared radiation, causing the temperature of the atmosphere to rise, causing climate variation, wind and rain disorders, glaciers to melt, and sea levels to rise gradually. Many coastal places will be submerged by water, and life will be charred.
As for 1% 2C2 of diolefins, its chemical activity is quite high. If released in the environment, it can photochemically react with various substances in the atmosphere to generate secondary pollutants such as ozone. Ozone can protect life on earth from ultraviolet rays at high altitudes. However, near the ground, if the concentration is too high, it is harmful to human health. It can cause shortness of breath, cough, asthma, and damage to plants, causing their growth to be blocked, leaves to fall, and ecological balance to be disrupted.
Furthermore, if these two types of substances enter water or soil, it will also cause many problems. Tetane is insoluble in water, but it can float on the water surface, hindering the gas exchange between water and the atmosphere, resulting in a decrease in the amount of dissolved oxygen in water, making it difficult for aquatic organisms to survive. And diolefins may react with substances in water, change the chemical properties of water bodies, and affect the growth and reproduction of aquatic animals and plants. In the soil, it may affect the activities of soil microorganisms, damage the soil structure, and cause soil fertility to decline, which in turn affects the growth of crops and endangers people's livelihood.
Therefore, at this time, it is necessary to pay attention to the discharge of these substances to ensure the safety of the earth and the environment and the peace of all living things.
Tetraalkane and the like, 3% 2C4% 2C5% 2C6, their properties are relatively stable, and they are mostly gaseous or liquid at room temperature. In the atmosphere, if a large amount of escape, although it does not directly harm the life of organisms, it can cause the greenhouse effect to gradually strengthen. Because it is exposed to sunlight, it can absorb infrared radiation, causing the temperature of the atmosphere to rise, causing climate variation, wind and rain disorders, glaciers to melt, and sea levels to rise gradually. Many coastal places will be submerged by water, and life will be charred.
As for 1% 2C2 of diolefins, its chemical activity is quite high. If released in the environment, it can photochemically react with various substances in the atmosphere to generate secondary pollutants such as ozone. Ozone can protect life on earth from ultraviolet rays at high altitudes. However, near the ground, if the concentration is too high, it is harmful to human health. It can cause shortness of breath, cough, asthma, and damage to plants, causing their growth to be blocked, leaves to fall, and ecological balance to be disrupted.
Furthermore, if these two types of substances enter water or soil, it will also cause many problems. Tetane is insoluble in water, but it can float on the water surface, hindering the gas exchange between water and the atmosphere, resulting in a decrease in the amount of dissolved oxygen in water, making it difficult for aquatic organisms to survive. And diolefins may react with substances in water, change the chemical properties of water bodies, and affect the growth and reproduction of aquatic animals and plants. In the soil, it may affect the activities of soil microorganisms, damage the soil structure, and cause soil fertility to decline, which in turn affects the growth of crops and endangers people's livelihood.
Therefore, at this time, it is necessary to pay attention to the discharge of these substances to ensure the safety of the earth and the environment and the peace of all living things.
What is the market outlook for 3,4,5,6-tetrachlorobenzene-1,2-dicarboxylic acid?
Today, there are three, four, five, and six numbers related to tetrahydronaphthalene; and one and two numbers related to secondary acids. As for its market prospects, let me tell you in detail.
tetrahydronaphthalene is an organic compound with a wide range of uses. In the chemical industry, it is often used as a solvent with good solubility and can be used for the dissolution and separation of various substances. And because of its certain chemical activity, it can participate in many organic synthesis reactions, making it an important raw material for the preparation of various fine chemicals. With the rapid development of today's industry, the demand for fine chemicals is increasing, so the market demand for tetrahydronaphthalene is also rising. In addition, it is also used in the synthesis of pharmaceutical intermediates, and the vigorous development of the pharmaceutical industry has injected strong impetus into the tetrahydronaphthalene market. Therefore, the market prospect of tetrahydronaphthalene is quite broad and is expected to continue to grow in the future.
And secondary acids also play an important role in chemical production. In some specific chemical reactions, secondary acids can play a unique catalytic role, improving reaction efficiency and product purity. In the field of materials science, secondary acids can be used to modify the properties of materials to make materials have better characteristics. With the advancement of science and technology, the demand for high-performance materials continues to increase, and the market demand for secondary acids, as an important auxiliary agent for material modification, will also increase steadily. At the same time, with the increasing awareness of environmental protection, if secondary acids can be applied to green chemical processes, they will be able to open up a broader market space.
To sum up, both tetralin and secondary acids have good market prospects due to the development trend of their industries, and may have considerable development in the future.
tetrahydronaphthalene is an organic compound with a wide range of uses. In the chemical industry, it is often used as a solvent with good solubility and can be used for the dissolution and separation of various substances. And because of its certain chemical activity, it can participate in many organic synthesis reactions, making it an important raw material for the preparation of various fine chemicals. With the rapid development of today's industry, the demand for fine chemicals is increasing, so the market demand for tetrahydronaphthalene is also rising. In addition, it is also used in the synthesis of pharmaceutical intermediates, and the vigorous development of the pharmaceutical industry has injected strong impetus into the tetrahydronaphthalene market. Therefore, the market prospect of tetrahydronaphthalene is quite broad and is expected to continue to grow in the future.
And secondary acids also play an important role in chemical production. In some specific chemical reactions, secondary acids can play a unique catalytic role, improving reaction efficiency and product purity. In the field of materials science, secondary acids can be used to modify the properties of materials to make materials have better characteristics. With the advancement of science and technology, the demand for high-performance materials continues to increase, and the market demand for secondary acids, as an important auxiliary agent for material modification, will also increase steadily. At the same time, with the increasing awareness of environmental protection, if secondary acids can be applied to green chemical processes, they will be able to open up a broader market space.
To sum up, both tetralin and secondary acids have good market prospects due to the development trend of their industries, and may have considerable development in the future.
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