Linshang Chemical
PRODUCTS
Hexachlorobenzene
Linshang Chemical
|
HS Code |
258493 |
| Chemical Formula | C6Cl6 |
| Molar Mass | 284.78 g/mol |
| Appearance | Colorless to pale yellow solid |
| Odor | Slight, sweet odor |
| Melting Point | 230.8 °C |
| Boiling Point | 323.7 °C |
| Density | 2.044 g/cm³ |
| Solubility In Water | Very low (0.005 mg/L at 25 °C) |
| Vapor Pressure | 1.3×10⁻⁵ mmHg at 25 °C |
| Log Kow Octanol Water Partition Coefficient | 5.73 |
| Stability | Thermally stable, resists biodegradation |
As an accredited Hexachlorobenzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Hexachlorobenzene packaged in 1 - kg containers for chemical storage and transport. |
| Storage | Hexachlorobenzene should be stored in a cool, dry, well - ventilated area, away from sources of ignition and heat. Keep it in a tightly closed container, preferably made of corrosion - resistant materials like steel or high - density polyethylene. Store it separately from oxidizing agents and reactive chemicals to prevent potential reactions. |
| Shipping | Hexachlorobenzene is a hazardous chemical. It must be shipped in accordance with strict regulations, using appropriate containers to prevent leakage, and with proper labeling indicating its dangerous nature. |
Competitive Hexachlorobenzene 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 Hexachlorobenzene in China?
As a trusted Hexachlorobenzene 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 Hexachlorobenzene 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 main uses of hexachlorobenzene?
The main use of pentaborane is particularly important. Pentaborane is active and has extraordinary uses in many fields.
First, in the field of aerospace, pentaborane can be a high-energy fuel. Its combustion heat is very high, which can provide strong power for aircraft. In the past, the demand for fuel in the aviation industry was extremely high, and high-energy and efficient fuels were needed. Due to its own characteristics, pentaborane can release a huge amount of heat energy during combustion, which can give aircraft a high thrust, help it travel through the sky, and even set foot in deep space exploration.
Second, in chemical synthesis, pentaborane is also a key reagent. Chemists can use its unique structure and reactivity to synthesize many special compounds. For example, it can be used to prepare boron-containing organic compounds, which have unique properties in the field of materials science, or have excellent heat resistance and corrosion resistance, and can be used to make materials for special purposes, such as components of high-end electronic devices, special protective coatings, etc.
Third, in materials science, pentaborane has made great contributions to the research and development of new materials. Materials that participate in the synthesis may have unique physical and chemical properties. For example, some boron-containing ceramic materials, with the action of pentaborane, have the characteristics of high hardness and low density, and can be used in aerospace, military equipment and other fields that require strict material properties to improve the performance and reliability of equipment.
Fourth, in the semiconductor industry, pentaborane also has its place. It can be used in the doping process of semiconductor materials to precisely control the electrical properties of semiconductors, so that the performance of semiconductor devices is better, and it helps electronic devices develop in the direction of smaller size and higher performance.
First, in the field of aerospace, pentaborane can be a high-energy fuel. Its combustion heat is very high, which can provide strong power for aircraft. In the past, the demand for fuel in the aviation industry was extremely high, and high-energy and efficient fuels were needed. Due to its own characteristics, pentaborane can release a huge amount of heat energy during combustion, which can give aircraft a high thrust, help it travel through the sky, and even set foot in deep space exploration.
Second, in chemical synthesis, pentaborane is also a key reagent. Chemists can use its unique structure and reactivity to synthesize many special compounds. For example, it can be used to prepare boron-containing organic compounds, which have unique properties in the field of materials science, or have excellent heat resistance and corrosion resistance, and can be used to make materials for special purposes, such as components of high-end electronic devices, special protective coatings, etc.
Third, in materials science, pentaborane has made great contributions to the research and development of new materials. Materials that participate in the synthesis may have unique physical and chemical properties. For example, some boron-containing ceramic materials, with the action of pentaborane, have the characteristics of high hardness and low density, and can be used in aerospace, military equipment and other fields that require strict material properties to improve the performance and reliability of equipment.
Fourth, in the semiconductor industry, pentaborane also has its place. It can be used in the doping process of semiconductor materials to precisely control the electrical properties of semiconductors, so that the performance of semiconductor devices is better, and it helps electronic devices develop in the direction of smaller size and higher performance.
What are the hazards of hexachlorobenzene to the environment?
According to "Tiangong Kaiwu", although sulfur hexafluoride is an odorless and non-toxic gas, it also poses various hazards to the environment.
It is one of the strong greenhouse gases, and the greenhouse effect potential is huge. It is estimated that the greenhouse effect potential of sulfur hexafluoride is about 23,500 times that of carbon dioxide within the century scale. This means that a very small amount of sulfur hexafluoride escapes into the atmosphere, but the greenhouse effect caused by it is very significant. In the long run, it may accelerate the global climate warming and change the climate model. Extreme climate events such as rainstorms, droughts, extreme heat, and severe cold occur more frequently and violently, endangering the ecological balance and human survival environment.
And sulfur hexafluoride has extremely stable chemical properties and persists in the atmosphere for a long time. It can be stored in the atmosphere for a contract renewal of 3200 years, and it will continue to exert the greenhouse effect for a long time, and its long-term impact on the global climate cannot be ignored.
Furthermore, sulfur hexafluoride is mostly used in electrical equipment, such as circuit breakers, transformers, etc. During equipment operation, maintenance and maintenance, if it is not properly disposed of, sulfur hexafluoride gas is easy to leak. And the power industry is widely used. Once the leakage control is poor, a large amount of sulfur hexafluoride enters the atmosphere, which will exacerbate its harm to the environment.
To sum up, sulfur hexafluoride poses a serious threat to the environment due to factors such as high greenhouse effect potential, long gas retention time and potential leakage risk in application. It should be treated with caution to reduce its negative impact on the ecological environment.
It is one of the strong greenhouse gases, and the greenhouse effect potential is huge. It is estimated that the greenhouse effect potential of sulfur hexafluoride is about 23,500 times that of carbon dioxide within the century scale. This means that a very small amount of sulfur hexafluoride escapes into the atmosphere, but the greenhouse effect caused by it is very significant. In the long run, it may accelerate the global climate warming and change the climate model. Extreme climate events such as rainstorms, droughts, extreme heat, and severe cold occur more frequently and violently, endangering the ecological balance and human survival environment.
And sulfur hexafluoride has extremely stable chemical properties and persists in the atmosphere for a long time. It can be stored in the atmosphere for a contract renewal of 3200 years, and it will continue to exert the greenhouse effect for a long time, and its long-term impact on the global climate cannot be ignored.
Furthermore, sulfur hexafluoride is mostly used in electrical equipment, such as circuit breakers, transformers, etc. During equipment operation, maintenance and maintenance, if it is not properly disposed of, sulfur hexafluoride gas is easy to leak. And the power industry is widely used. Once the leakage control is poor, a large amount of sulfur hexafluoride enters the atmosphere, which will exacerbate its harm to the environment.
To sum up, sulfur hexafluoride poses a serious threat to the environment due to factors such as high greenhouse effect potential, long gas retention time and potential leakage risk in application. It should be treated with caution to reduce its negative impact on the ecological environment.
What is the metabolic pathway of hexachlorobenzene in the human body?
The metabolism of sulfur hexafluoride in the human body is very complicated. Sulfur hexafluoride is a colorless, odorless, odorless and non-toxic inert gas at room temperature and pressure. Its chemical properties are extremely stable, and it rarely reacts with the human body under normal conditions.
After the human body inhales sulfur hexafluoride, most of it is exhaled directly through the respiratory tract. Due to its high chemical stability, there is no enzyme or biochemical mechanism in the human body that can react significantly with it. Because the lungs have a high-efficiency gas exchange function, the inhaled sulfur hexafluoride gas is excreted from the body with the exhalation because it does not participate in the biochemical reaction in the body when the gas is exchanged between the alveoli and the capillaries.
Although the metabolic pathway of sulfur hexafluoride is simple, in certain environments, sulfur hexafluoride may decompose due to factors such as electrical equipment discharge, resulting in fluorine-containing compounds and other products. These decomposition products may be toxic. After being inhaled by the human body, or circulating through the blood to various tissues and organs of the body, they chemically react with substances in the body and interfere with normal physiological functions.
For example, if some fluorinated compounds or combine with calcium and magnesium plasma in the body, it will affect the development of bones and teeth, or cause damage to the nervous system, respiratory system, etc. However, this situation mostly occurs when sulfur hexafluoride is decomposed in a large amount in a specific environment and the human body is exposed to a high degree. Under normal circumstances, sulfur hexafluoride is metabolized by the human body in its original state through respiration
After the human body inhales sulfur hexafluoride, most of it is exhaled directly through the respiratory tract. Due to its high chemical stability, there is no enzyme or biochemical mechanism in the human body that can react significantly with it. Because the lungs have a high-efficiency gas exchange function, the inhaled sulfur hexafluoride gas is excreted from the body with the exhalation because it does not participate in the biochemical reaction in the body when the gas is exchanged between the alveoli and the capillaries.
Although the metabolic pathway of sulfur hexafluoride is simple, in certain environments, sulfur hexafluoride may decompose due to factors such as electrical equipment discharge, resulting in fluorine-containing compounds and other products. These decomposition products may be toxic. After being inhaled by the human body, or circulating through the blood to various tissues and organs of the body, they chemically react with substances in the body and interfere with normal physiological functions.
For example, if some fluorinated compounds or combine with calcium and magnesium plasma in the body, it will affect the development of bones and teeth, or cause damage to the nervous system, respiratory system, etc. However, this situation mostly occurs when sulfur hexafluoride is decomposed in a large amount in a specific environment and the human body is exposed to a high degree. Under normal circumstances, sulfur hexafluoride is metabolized by the human body in its original state through respiration
What are the detection methods for hexachlorobenzene?
For hexachlorobenzene, the best method is the method. One is the phase chromatography method. In this case, hexachlorobenzene is separated from the stationary phase by the flow phase. First, the product is taken, placed in a specific setting, vaporized, and then entered into the phase chromatography. Due to the adsorption or distribution of hexachlorobenzene in the stationary phase, the flow phase is shifted, resulting in its separation. The presence and amount of hexachlorobenzene can be known according to the retention, peak surface, etc.
Furthermore, the high-performance liquid phase chromatography method can also be used. In this high-quality liquid system, the hexachlorobenzene phase is pumped into the color column, and the hexachlorobenzene in the product is distributed in the stationary phase, and the hexachlorobenzene is distributed out due to the distribution of the hexachlorobenzene. As a result, the phase of hexachlorobenzene can be disrupted. There is another method.
It emulsifies the hexachlorobenzene product to generate hexachlorobenzene particles, which are divided into magnetism or magnetism according to their different charge ratios. The molecular weight of hexachlorobenzene can be obtained, and the phase color or liquid phase color can be obtained, such as the use of (GC-MS), liquid use (LC-MS), which can improve the sensitivity and accuracy of hexachlorobenzene.
In addition, the external light method is also a way. Hexachlorobenzene has specific functions. Under the irradiation of external light, different functions can absorb the light of specific waves, and the vibration and energy can be determined. The external absorption light, the position and degree of the absorption peak, etc., can determine hexachlorobenzene, and the approximation of its transformation can be known. Each method has its own shortcoming, depending on the needs of the product, the characteristics of the product, etc. The method of combining the product is hexachlorobenzene.
Furthermore, the high-performance liquid phase chromatography method can also be used. In this high-quality liquid system, the hexachlorobenzene phase is pumped into the color column, and the hexachlorobenzene in the product is distributed in the stationary phase, and the hexachlorobenzene is distributed out due to the distribution of the hexachlorobenzene. As a result, the phase of hexachlorobenzene can be disrupted. There is another method.
It emulsifies the hexachlorobenzene product to generate hexachlorobenzene particles, which are divided into magnetism or magnetism according to their different charge ratios. The molecular weight of hexachlorobenzene can be obtained, and the phase color or liquid phase color can be obtained, such as the use of (GC-MS), liquid use (LC-MS), which can improve the sensitivity and accuracy of hexachlorobenzene.
In addition, the external light method is also a way. Hexachlorobenzene has specific functions. Under the irradiation of external light, different functions can absorb the light of specific waves, and the vibration and energy can be determined. The external absorption light, the position and degree of the absorption peak, etc., can determine hexachlorobenzene, and the approximation of its transformation can be known. Each method has its own shortcoming, depending on the needs of the product, the characteristics of the product, etc. The method of combining the product is hexachlorobenzene.
What is the production process of hexachlorobenzene?
"Where arsenic is made, it is said that arsenic is used to burn arsenic stone. Where arsenic stone is produced in the southwest, it is also like cinnabar, but it is not produced with realgar. Its stone is yellow, and it is used for sulfur gas. It is sprayed with wine, and after half a day of calcination, the smoke will fly snow-white and condense on the tank." This is the production process of six arsenic.
Arsenic is often produced in the southwest, and it is yellow in color and smells of sulfur. First spray arsenic with wine to make it clean. Then it is placed in a kiln and calcined for about half a day. During the calcination process, the arsenic stone is heated, the composition of it changes, and the smoke rises. And this smoke condenses on the tank when it is cold, and the final snow-white condensate is arsenic.
Although this process can produce arsenic, arsenic is highly toxic and affects human life. It is necessary to use and produce it with extreme caution. In the past, people explored the production process, and at the same time, they were well aware of its dangers. Today, the production and application of such special substances should not be taken lightly under the premise of following scientific and safety guidelines, which will cause harm.
Arsenic is often produced in the southwest, and it is yellow in color and smells of sulfur. First spray arsenic with wine to make it clean. Then it is placed in a kiln and calcined for about half a day. During the calcination process, the arsenic stone is heated, the composition of it changes, and the smoke rises. And this smoke condenses on the tank when it is cold, and the final snow-white condensate is arsenic.
Although this process can produce arsenic, arsenic is highly toxic and affects human life. It is necessary to use and produce it with extreme caution. In the past, people explored the production process, and at the same time, they were well aware of its dangers. Today, the production and application of such special substances should not be taken lightly under the premise of following scientific and safety guidelines, which will cause harm.
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