Linshang Chemical
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Benzenesulfonic Acid, 4-Chloro-, Potassium Salt (1:1)
Linshang Chemical
|
HS Code |
407979 |
| Chemical Name | Benzenesulfonic Acid, 4-Chloro-, Potassium Salt (1:1) |
| Molecular Formula | C6H4ClKO3S |
| Molecular Weight | 232.71 g/mol |
| Appearance | Solid |
| Color | Typically white or off - white |
| Solubility | Soluble in water |
| Odor | Odorless or faint odor |
| Ph | Affects solution pH, details depend on concentration |
| Stability | Stable under normal conditions |
As an accredited Benzenesulfonic Acid, 4-Chloro-, Potassium Salt (1:1) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100 - gram package of 4 - chloro - benzenesulfonic acid potassium salt (1:1) in sealed container. |
| Storage | Store 4 - chloro - benzenesulfonic acid potassium salt (1:1) in a cool, dry place, away from heat and ignition sources. Keep it in a tightly - sealed container to prevent moisture absorption and contamination. Store separately from incompatible substances like strong oxidizing agents and bases to avoid potential chemical reactions. |
| Shipping | The 4 - chloro - benzenesulfonic acid potassium salt (1:1) is shipped in containers suitable for chemical substances. It must comply with strict regulations to ensure safe transportation due to its chemical nature. |
Competitive Benzenesulfonic Acid, 4-Chloro-, Potassium Salt (1:1) 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 Benzenesulfonic Acid, 4-Chloro-, Potassium Salt (1:1) in China?
As a trusted Benzenesulfonic Acid, 4-Chloro-, Potassium Salt (1:1) 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 Benzenesulfonic Acid, 4-Chloro-, Potassium Salt (1:1) 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 potassium 4-chlorobenzenesulfonate (1:1)?
The chemical properties of the silver halide developer (1:1) are very important. The properties of this liquid have the dual characteristics of oxidation and reduction.
From the perspective of oxidation, silver halide can be used as an oxidizing agent in it. Silver ions in silver halide have a higher electrode potential and can be reduced by electrons. For example, during the development process, silver halide meets the developer, and the silver ions are powered by the developer and reduce themselves to metallic silver. This is the key step in image formation, because the precipitation of metallic silver makes the image visible.
On its reducing properties, silver halide can be used as a reducing agent in specific situations. Halogen ions (such as chloride ions, bromine ions, and iodine ions) have certain reductivity. When exposed to stronger oxidants, halogen ions can lose electrons and be oxidized. However, in conventional development systems, this reductivity is weak, and oxidation is the main role in image formation.
In addition, the stability of silver halide developer (1:1) is also a key point of its chemical properties. Its stability is related to the uniformity and durability of the development effect. Temperature, light and other factors have a great impact on its stability. Under high temperature or strong light irradiation, the decomposition rate of silver halide accelerates, causing the developer to fail. Therefore, it needs to be stored at low temperature and protected from light to maintain its chemical stability and ensure the smooth development process and excellent image quality.
The chemical properties, oxidation, reduction and stability of this silver halide developer (1:1) are of great significance in the field of imaging science, and are the foundation for accurately controlling the development effect and obtaining ideal images.
From the perspective of oxidation, silver halide can be used as an oxidizing agent in it. Silver ions in silver halide have a higher electrode potential and can be reduced by electrons. For example, during the development process, silver halide meets the developer, and the silver ions are powered by the developer and reduce themselves to metallic silver. This is the key step in image formation, because the precipitation of metallic silver makes the image visible.
On its reducing properties, silver halide can be used as a reducing agent in specific situations. Halogen ions (such as chloride ions, bromine ions, and iodine ions) have certain reductivity. When exposed to stronger oxidants, halogen ions can lose electrons and be oxidized. However, in conventional development systems, this reductivity is weak, and oxidation is the main role in image formation.
In addition, the stability of silver halide developer (1:1) is also a key point of its chemical properties. Its stability is related to the uniformity and durability of the development effect. Temperature, light and other factors have a great impact on its stability. Under high temperature or strong light irradiation, the decomposition rate of silver halide accelerates, causing the developer to fail. Therefore, it needs to be stored at low temperature and protected from light to maintain its chemical stability and ensure the smooth development process and excellent image quality.
The chemical properties, oxidation, reduction and stability of this silver halide developer (1:1) are of great significance in the field of imaging science, and are the foundation for accurately controlling the development effect and obtaining ideal images.
What are the main uses of potassium 4-chlorobenzenesulfonate (1:1)?
Acid acetyl (1:1) is also a chemical substance. It is mainly used in many fields, and it is useful in all domains.
In the field of, acid acetyl (1:1) is often used as the raw material of the chemical compound. It has certain chemical properties, and can be used for the synthesis of the chemical compound. Those in ancient times did not know the ratio of this refined chemical compound, but now it is used as a basis to study the general chemical compound to treat diseases. For example, some anti-parasitic substances, such as acid acetyl (1:1), can help the substance to better act on parasitism, break its physiological system, and save people.
In chemical research, acidity (1:1) is also an important factor. Chemists, who want to explore the properties and inverse principles of matter, often use this medium. It can be used to transform the properties of matter in a general way, and to observe the images and substances of matter, so as to clarify the law of the interaction of matter. For example, in the synthesis of some gold compounds, acidity (1:1) can control the rate and direction of reaction, so that researchers can obtain the required compounds and promote the next step in the field of chemistry.
Furthermore, in the field of materials, acidity (1:1) is also useful. Today, people strive to develop new materials with excellent performance. Acid acyl (1:1) can be added to the material as an addition. In this way, the physical and chemical properties of the material can be changed, such as increasing the quality of the material, changing its performance, etc. Taking ceramic materials as an example, adding acid acyl (1:1) can make ceramics more resistant and more durable, and expand the application of ceramic materials.
In the field of, acid acetyl (1:1) is often used as the raw material of the chemical compound. It has certain chemical properties, and can be used for the synthesis of the chemical compound. Those in ancient times did not know the ratio of this refined chemical compound, but now it is used as a basis to study the general chemical compound to treat diseases. For example, some anti-parasitic substances, such as acid acetyl (1:1), can help the substance to better act on parasitism, break its physiological system, and save people.
In chemical research, acidity (1:1) is also an important factor. Chemists, who want to explore the properties and inverse principles of matter, often use this medium. It can be used to transform the properties of matter in a general way, and to observe the images and substances of matter, so as to clarify the law of the interaction of matter. For example, in the synthesis of some gold compounds, acidity (1:1) can control the rate and direction of reaction, so that researchers can obtain the required compounds and promote the next step in the field of chemistry.
Furthermore, in the field of materials, acidity (1:1) is also useful. Today, people strive to develop new materials with excellent performance. Acid acyl (1:1) can be added to the material as an addition. In this way, the physical and chemical properties of the material can be changed, such as increasing the quality of the material, changing its performance, etc. Taking ceramic materials as an example, adding acid acyl (1:1) can make ceramics more resistant and more durable, and expand the application of ceramic materials.
4 - What is the production method of potassium chlorobenzenesulfonate (1:1)?
In order to obtain acid (1:1), the method is as follows:
First, the refined food (chlorinated food, $NaCl $) is sulfuric acid ($H_ {2} SO_ {4} $). Take a solid glass retort, put it in the amount of food, and then inject the sulfuric acid. The amount of the two should be considered in the proportion of the chemical, so that the generated acid (1:1) can be combined as needed.
Next, add the retort with charcoal fire or other sources. Add it, and pay attention to the heat, so as not to cause the temperature to break, so as not to break the utensils. In the addition process, the biochemical reaction of sulfuric acid: $2NaCl + H_ {2} SO_ {4}\ stackrel {\ Delta }{=\!=\!=} Na_ {2} SO_ {4} + 2HCl\ uparrow $, the generated chlorine ($HCl $) escapes from the tube of the product.
The chlorine that escapes is introduced into the container containing water. The chlorine is easily soluble in water, so it forms an acid solution. To obtain the acid (1:1), the ratio of chlorinated water can be controlled. The capacity of the water can be determined first, and then the chlorine can be added in proportion.
After the reaction is completed, the cold curl is finished, and the contents of the product are properly processed. The resulting acid solution, in the amount of refined equipment, can be reduced to its degree. If there is no acid (1:1) requirement, chlorine or water can be added to the amount, and the ratio can be adjusted to the correct ratio. In this way, the acid (1:1) can be obtained.
First, the refined food (chlorinated food, $NaCl $) is sulfuric acid ($H_ {2} SO_ {4} $). Take a solid glass retort, put it in the amount of food, and then inject the sulfuric acid. The amount of the two should be considered in the proportion of the chemical, so that the generated acid (1:1) can be combined as needed.
Next, add the retort with charcoal fire or other sources. Add it, and pay attention to the heat, so as not to cause the temperature to break, so as not to break the utensils. In the addition process, the biochemical reaction of sulfuric acid: $2NaCl + H_ {2} SO_ {4}\ stackrel {\ Delta }{=\!=\!=} Na_ {2} SO_ {4} + 2HCl\ uparrow $, the generated chlorine ($HCl $) escapes from the tube of the product.
The chlorine that escapes is introduced into the container containing water. The chlorine is easily soluble in water, so it forms an acid solution. To obtain the acid (1:1), the ratio of chlorinated water can be controlled. The capacity of the water can be determined first, and then the chlorine can be added in proportion.
After the reaction is completed, the cold curl is finished, and the contents of the product are properly processed. The resulting acid solution, in the amount of refined equipment, can be reduced to its degree. If there is no acid (1:1) requirement, chlorine or water can be added to the amount, and the ratio can be adjusted to the correct ratio. In this way, the acid (1:1) can be obtained.
4 - Potassium chlorobenzenesulfonate (1:1) What are the precautions in storage and transportation?
Mercury bromide red solution (1:1) requires attention to many key matters during storage and transportation.
Its properties are unstable. When storing, be sure to keep it in a cool and dry place, and beware of heat and light. Heat can easily cause changes in components, and light will also promote its decomposition, resulting in reduced efficacy.
Mercury bromide red solution contains mercury and is toxic to a certain extent. When storing, it should be separated from food and medicine to avoid contact with children and pets to prevent accidental ingestion and cause mercury poisoning. When transporting, also ensure that the packaging is tight and does not leak. If it leaks, mercury pollution is difficult to remove, and it is harmful to the environment and people.
Furthermore, the storage period of mercury bromide red solution is limited, so pay attention to the valid period. If it is about to expire, it should not be reused to avoid poor curative effect or adverse reactions. When transporting, control the time to avoid product deterioration caused by too long transportation.
In addition, it is corrosive to metals. Storage containers should be made of suitable materials, and metal containers should not be used. During transportation, contact with metal items should be avoided to prevent corrosion of the container and cause leakage.
During the storage and transportation of mercury bromide red solution (1:1), care should be taken in terms of environmental conditions, toxicity prevention, valid period management, and container selection to ensure its quality and safety.
Its properties are unstable. When storing, be sure to keep it in a cool and dry place, and beware of heat and light. Heat can easily cause changes in components, and light will also promote its decomposition, resulting in reduced efficacy.
Mercury bromide red solution contains mercury and is toxic to a certain extent. When storing, it should be separated from food and medicine to avoid contact with children and pets to prevent accidental ingestion and cause mercury poisoning. When transporting, also ensure that the packaging is tight and does not leak. If it leaks, mercury pollution is difficult to remove, and it is harmful to the environment and people.
Furthermore, the storage period of mercury bromide red solution is limited, so pay attention to the valid period. If it is about to expire, it should not be reused to avoid poor curative effect or adverse reactions. When transporting, control the time to avoid product deterioration caused by too long transportation.
In addition, it is corrosive to metals. Storage containers should be made of suitable materials, and metal containers should not be used. During transportation, contact with metal items should be avoided to prevent corrosion of the container and cause leakage.
During the storage and transportation of mercury bromide red solution (1:1), care should be taken in terms of environmental conditions, toxicity prevention, valid period management, and container selection to ensure its quality and safety.
What are the environmental effects of potassium 4-chlorobenzenesulfonate (1:1)?
Mercury chloric acid chain (1:1), its impact on the environment is particularly important. Mercury, the most toxic heavy metal, is also present in the natural environment, but due to human measures, such as industrial emissions, mining mining, etc., its content in the environment gradually increases, and the harm is even greater.
Mercury chloric acid chain (1:1) If released in the environment, the first to bear the brunt is water. It can dissolve into water and migrate with water flow, causing extensive pollution. Mercury in water is enriched by the food chain, starting from plankton and gradually accumulating in high-trophic organisms. For example, small fish eat mercury-containing plankton, and big fish eat small fish, and the mercury concentration in large fish increases sharply. If people eat these contaminated fish, mercury will enter the human body, damage the nervous, immune, reproductive and other systems, causing serious diseases such as Minamata disease.
In the soil environment, mercury chloric acid chain (1:1) can cause soil mercury pollution. It affects the activity and community structure of soil microorganisms, hinders soil material circulation and energy conversion. And mercury stays in the soil for a long time, is difficult to degrade, and causes long-term pollution. If plant roots absorb mercury-containing substances, their growth and development will be hindered, and the quality of agricultural products will also decline, threatening food safety.
Atmospheric environment is also affected by it. Mercury chloric acid chain (1:1) enters the atmosphere through volatilization and other channels, and is widely distributed with atmospheric circulation. Part of the mercury re-settles on the ground and water bodies, causing secondary pollution. Atmospheric mercury is also a threat to human health, and human inhalation of mercury vapor can damage the respiratory system and nervous system.
Therefore, the mercury chloric acid chain (1:1) has a profound and huge impact on the environment. It is necessary to dispose of mercury-containing substances with caution, and strengthen monitoring and control to ensure the well-being of the environment and people.
Mercury chloric acid chain (1:1) If released in the environment, the first to bear the brunt is water. It can dissolve into water and migrate with water flow, causing extensive pollution. Mercury in water is enriched by the food chain, starting from plankton and gradually accumulating in high-trophic organisms. For example, small fish eat mercury-containing plankton, and big fish eat small fish, and the mercury concentration in large fish increases sharply. If people eat these contaminated fish, mercury will enter the human body, damage the nervous, immune, reproductive and other systems, causing serious diseases such as Minamata disease.
In the soil environment, mercury chloric acid chain (1:1) can cause soil mercury pollution. It affects the activity and community structure of soil microorganisms, hinders soil material circulation and energy conversion. And mercury stays in the soil for a long time, is difficult to degrade, and causes long-term pollution. If plant roots absorb mercury-containing substances, their growth and development will be hindered, and the quality of agricultural products will also decline, threatening food safety.
Atmospheric environment is also affected by it. Mercury chloric acid chain (1:1) enters the atmosphere through volatilization and other channels, and is widely distributed with atmospheric circulation. Part of the mercury re-settles on the ground and water bodies, causing secondary pollution. Atmospheric mercury is also a threat to human health, and human inhalation of mercury vapor can damage the respiratory system and nervous system.
Therefore, the mercury chloric acid chain (1:1) has a profound and huge impact on the environment. It is necessary to dispose of mercury-containing substances with caution, and strengthen monitoring and control to ensure the well-being of the environment and people.
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