Linshang Chemical
PRODUCTS
3,6-Dichlorobenzene-1,2-Dithiol
Linshang Chemical
|
HS Code |
845068 |
| Chemical Formula | C6H2Cl2S2 |
| Molecular Weight | 211.12 |
| Appearance | Solid |
| Color | Typically white to off - white |
| Odor | Characteristic sulfur - containing odor |
| Melting Point | Data varies, around 100 - 120°C |
| Solubility In Water | Low solubility in water |
| Solubility In Organic Solvents | Soluble in some organic solvents like dichloromethane |
| Stability | Stable under normal conditions, may react with strong oxidants |
As an accredited 3,6-Dichlorobenzene-1,2-Dithiol factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100g of 3,6 - dichlorobenzene - 1,2 - dithiol packaged in an air - tight chemical - resistant container. |
| Storage | 3,6 - dichlorobenzene - 1,2 - dithiol should be stored in a cool, dry, well - ventilated area, away from heat, sparks, and open flames. Keep it in a tightly - sealed container, preferably made of corrosion - resistant materials. Store it separately from oxidizing agents and incompatible substances to prevent chemical reactions. |
| Shipping | 3,6 - dichlorobenzene - 1,2 - dithiol is shipped in sealed, corrosion - resistant containers. Compliance with hazardous chemical shipping regulations is ensured, with proper labeling indicating its nature to safeguard handlers and during transit. |
Competitive 3,6-Dichlorobenzene-1,2-Dithiol 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 3,6-Dichlorobenzene-1,2-Dithiol in China?
As a trusted 3,6-Dichlorobenzene-1,2-Dithiol 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 3,6-Dichlorobenzene-1,2-Dithiol 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 main use of 3,6-dichlorobenzene-1,2-dithiol?
3% 2C6 - silica - 1% 2C2 - molybdenum disulfide is the main user, which is multi-terminal, and plays an important role in the general field.
First of all, silica, which is used in industrial technology and daily use, is widely used. For building materials, it is an essential material for glass. Glass, transparent and solid, can be used as windows and windows, so that the room can pass light and rain; it can also be used as utensils, like liquid. This is the property of silica, high melting and chemical properties, and can be highly molten and have the required shape. In the chemical industry, the foundation of silicon. Silicone is a water-absorbing material, which is often used in dry air, and can protect the material from the damage of moisture. In addition, because of its toxicity and good biocompatibility, it can be used as a filling material and so on. Furthermore, in terms of sub-work, it is an important bottom material for semi-manufacturing, which is essential for the development of the integrated road. With its performance, it determines the physical properties and ensures the normal operation of sub-components.
secondary disulfide, which is effective in the sliding area. Disulfide has low friction, so the friction is low, which can effectively reduce the friction of mechanical components. For mechanical manufacturing, it can be used in various high-load, high-load and chemical-corrosion environments, such as steam engines, industrial boxes, etc., which can reduce energy consumption and extend the service life of components. In the aerospace industry, surface-to-end components and the slip characteristics of disulfide can also ensure the safe operation of equipment. In addition, in the new research on rice technology, the disulfide-to-meter material is expected to open up new horizons in photonic devices, catalysis, etc., such as high-efficiency optical devices, to improve energy efficiency.
First of all, silica, which is used in industrial technology and daily use, is widely used. For building materials, it is an essential material for glass. Glass, transparent and solid, can be used as windows and windows, so that the room can pass light and rain; it can also be used as utensils, like liquid. This is the property of silica, high melting and chemical properties, and can be highly molten and have the required shape. In the chemical industry, the foundation of silicon. Silicone is a water-absorbing material, which is often used in dry air, and can protect the material from the damage of moisture. In addition, because of its toxicity and good biocompatibility, it can be used as a filling material and so on. Furthermore, in terms of sub-work, it is an important bottom material for semi-manufacturing, which is essential for the development of the integrated road. With its performance, it determines the physical properties and ensures the normal operation of sub-components.
secondary disulfide, which is effective in the sliding area. Disulfide has low friction, so the friction is low, which can effectively reduce the friction of mechanical components. For mechanical manufacturing, it can be used in various high-load, high-load and chemical-corrosion environments, such as steam engines, industrial boxes, etc., which can reduce energy consumption and extend the service life of components. In the aerospace industry, surface-to-end components and the slip characteristics of disulfide can also ensure the safe operation of equipment. In addition, in the new research on rice technology, the disulfide-to-meter material is expected to open up new horizons in photonic devices, catalysis, etc., such as high-efficiency optical devices, to improve energy efficiency.
What are the physical properties of 3,6-dichlorobenzene-1,2-dithiol
3% 2C6 - Carbon dioxide - 1% 2C2 - The physical properties of silica are as follows:
Carbon dioxide, under normal conditions, is often stinky. Its density is higher than that of the air, which is 1.5 times that of the air, so it is mostly low temperature. Melting temperature - 78.5 ° C, boiling temperature - 56.6 ° C, easy to rise, that is, directly from the solid. This property is often used to make dry ice, which rises rapidly under normal conditions, absorbs and decreases, and can be used for refrigeration, stage effects, etc. Carbon dioxide is slightly soluble in water, and water can generate carbonic acid. Its chemical properties are determined, generally do not support combustion, and are not flammable. This characteristic makes it often used in fire.
When it comes to silicon dioxide, it is often solidified, and its outer surface is mostly crystalline or amorphous. Quartz is a typical crystalline shape of silicon dioxide, which is hard to the ground and has a Mohs hardness of 7. The melting temperature is high, 1713 ° C, and the boiling temperature is 2230 ° C. Because silicon dioxide has a large total temperature, it requires a lot of energy to break this. Silica is insoluble in water, and it is not biochemically reactive in water. Its chemistability is determined. In addition to fluoric acid, it is generally not reactive to acid, and fluoric acid is reactive to produce silicon tetrafluoride water. In the context of environmental resistance, silicon dioxide can be slowly reactive to generate silicic acid water.
Carbon dioxide, under normal conditions, is often stinky. Its density is higher than that of the air, which is 1.5 times that of the air, so it is mostly low temperature. Melting temperature - 78.5 ° C, boiling temperature - 56.6 ° C, easy to rise, that is, directly from the solid. This property is often used to make dry ice, which rises rapidly under normal conditions, absorbs and decreases, and can be used for refrigeration, stage effects, etc. Carbon dioxide is slightly soluble in water, and water can generate carbonic acid. Its chemical properties are determined, generally do not support combustion, and are not flammable. This characteristic makes it often used in fire.
When it comes to silicon dioxide, it is often solidified, and its outer surface is mostly crystalline or amorphous. Quartz is a typical crystalline shape of silicon dioxide, which is hard to the ground and has a Mohs hardness of 7. The melting temperature is high, 1713 ° C, and the boiling temperature is 2230 ° C. Because silicon dioxide has a large total temperature, it requires a lot of energy to break this. Silica is insoluble in water, and it is not biochemically reactive in water. Its chemistability is determined. In addition to fluoric acid, it is generally not reactive to acid, and fluoric acid is reactive to produce silicon tetrafluoride water. In the context of environmental resistance, silicon dioxide can be slowly reactive to generate silicic acid water.
What are the chemical properties of 3,6-dichlorobenzene-1,2-dithiol
3% 2C6 - Nitrogen dioxide - 1% 2C2 - Carbon dioxide, both of which are common chemicals, each with unique chemical properties.
Nitrogen dioxide, its red-brown color, pungent odor, and toxic. At room temperature and pressure, nitrogen dioxide coexists with nitrous oxide and converts into each other. It is a strong oxidant and can oxidize with many substances. For example, it can dissociate with water to form nitric acid and nitric oxide. The chemical equation for this reaction is:\ (3NO_ {2} + H_ {2} O = 2HNO_ {3} + NO\). At the same time, it will participate in complex photochemical reactions in the atmosphere under light conditions, which has a great impact on the environment and is an important factor in the formation of acid rain, photochemical smog and other environmental problems.
Carbon dioxide is colorless and odorless, and is generally non-flammable and does not support combustion. Its chemical properties are relatively stable. It is an acidic oxide and can react with alkali solutions to form salts and water. For example, when introduced into clear lime water, the lime water will become turbid. The chemical equation for this reaction is:\ (CO_ {2} + Ca (OH) _ {2} = CaCO_ {3}\ downarrow + H_ {2} O\). Under high temperature conditions, carbon dioxide can react with carbon to form carbon monoxide. In addition, carbon dioxide is a key raw material for plant photosynthesis and plays an important role in the natural carbon cycle. However, in recent years, human activities have caused a sharp increase in carbon dioxide content in the atmosphere, causing many environmental problems such as global warming.
Nitrogen dioxide, its red-brown color, pungent odor, and toxic. At room temperature and pressure, nitrogen dioxide coexists with nitrous oxide and converts into each other. It is a strong oxidant and can oxidize with many substances. For example, it can dissociate with water to form nitric acid and nitric oxide. The chemical equation for this reaction is:\ (3NO_ {2} + H_ {2} O = 2HNO_ {3} + NO\). At the same time, it will participate in complex photochemical reactions in the atmosphere under light conditions, which has a great impact on the environment and is an important factor in the formation of acid rain, photochemical smog and other environmental problems.
Carbon dioxide is colorless and odorless, and is generally non-flammable and does not support combustion. Its chemical properties are relatively stable. It is an acidic oxide and can react with alkali solutions to form salts and water. For example, when introduced into clear lime water, the lime water will become turbid. The chemical equation for this reaction is:\ (CO_ {2} + Ca (OH) _ {2} = CaCO_ {3}\ downarrow + H_ {2} O\). Under high temperature conditions, carbon dioxide can react with carbon to form carbon monoxide. In addition, carbon dioxide is a key raw material for plant photosynthesis and plays an important role in the natural carbon cycle. However, in recent years, human activities have caused a sharp increase in carbon dioxide content in the atmosphere, causing many environmental problems such as global warming.
What are the synthesis methods of 3,6-dichlorobenzene-1,2-dithiol?
This is the synthesis method of Ruyan dioxy rhenium ($ReO_2 $) and tellurium dioxide ($TeO_2 $).
Synthesis of dioxy rhenium
To make dioxy rhenium, the common method is to start with rhenium oxide and obtain it through the process of reduction. If rhenium heptaoxide ($Re_2O_7 $) is used as the raw material, hydrogen ($H_2 $) can be used as the reducing agent. The chemical equation of the reaction is as follows: $Re_2O_7 + 5H_2\ stackrel {\ Delta }{=\!=\!=} 2ReO_2 + 5H_2O $. Under high temperature conditions, hydrogen is added to rhenium heptaoxide, and hydrogen captures the oxygen in rhenium heptaoxide, and then forms rhenium dioxide and water.
Or use metal rhenium to react directly with oxygen, but the reaction conditions need to be controlled, because rhenium reacts with oxygen to form high-valent oxides. When the temperature and the amount of oxygen are appropriate, rhenium dioxide can be obtained, and the reaction is roughly: $2Re + 2O_2\ stackrel {\ text {specific conditions }}{=\!=\!=} 2ReO_2 $.
Synthesis of tellurium dioxide
First, tellurium powder can be directly combined with oxygen. The tellurium powder is placed in a suitable reactor, introduced with oxygen, and heated. Tellurium reacts with oxygen, namely: $Te + O_2\ stackrel {\ Delta }{=\!=\!=} $TeO_2. This process requires attention to temperature control. If the temperature is too high or too low, it may affect the purity and yield of the product.
Second, tellurite is used as the raw material, and tellurium dioxide can be obtained by oxidation. For example, sodium tellurite ($Na_2TeO_3 $) can be added with an oxidizing agent such as hydrogen peroxide ($H_2O_2 $). The reaction formula is: $Na_2TeO_3 + H_2O_2\ stackrel {}{=\!=\!=} TeO_2 + Na_2O + H_2O $. In the reaction, hydrogen peroxide oxidizes tellurium in sodium tellurite to form tellurium dioxide.
Telluric acid ($H_6TeO_6 $) can be decomposed by heat. When telluric acid is heated, it decomposes as follows: $H_6TeO_6\ stackrel {\ Delta }{=\!=\!=} TeO_2 + 2H_2O + O_2\ uparrow $. Controlling the temperature and time of heating can decompose telluric acid to obtain tellurium dioxide.
Synthesis of dioxy rhenium
To make dioxy rhenium, the common method is to start with rhenium oxide and obtain it through the process of reduction. If rhenium heptaoxide ($Re_2O_7 $) is used as the raw material, hydrogen ($H_2 $) can be used as the reducing agent. The chemical equation of the reaction is as follows: $Re_2O_7 + 5H_2\ stackrel {\ Delta }{=\!=\!=} 2ReO_2 + 5H_2O $. Under high temperature conditions, hydrogen is added to rhenium heptaoxide, and hydrogen captures the oxygen in rhenium heptaoxide, and then forms rhenium dioxide and water.
Or use metal rhenium to react directly with oxygen, but the reaction conditions need to be controlled, because rhenium reacts with oxygen to form high-valent oxides. When the temperature and the amount of oxygen are appropriate, rhenium dioxide can be obtained, and the reaction is roughly: $2Re + 2O_2\ stackrel {\ text {specific conditions }}{=\!=\!=} 2ReO_2 $.
Synthesis of tellurium dioxide
First, tellurium powder can be directly combined with oxygen. The tellurium powder is placed in a suitable reactor, introduced with oxygen, and heated. Tellurium reacts with oxygen, namely: $Te + O_2\ stackrel {\ Delta }{=\!=\!=} $TeO_2. This process requires attention to temperature control. If the temperature is too high or too low, it may affect the purity and yield of the product.
Second, tellurite is used as the raw material, and tellurium dioxide can be obtained by oxidation. For example, sodium tellurite ($Na_2TeO_3 $) can be added with an oxidizing agent such as hydrogen peroxide ($H_2O_2 $). The reaction formula is: $Na_2TeO_3 + H_2O_2\ stackrel {}{=\!=\!=} TeO_2 + Na_2O + H_2O $. In the reaction, hydrogen peroxide oxidizes tellurium in sodium tellurite to form tellurium dioxide.
Telluric acid ($H_6TeO_6 $) can be decomposed by heat. When telluric acid is heated, it decomposes as follows: $H_6TeO_6\ stackrel {\ Delta }{=\!=\!=} TeO_2 + 2H_2O + O_2\ uparrow $. Controlling the temperature and time of heating can decompose telluric acid to obtain tellurium dioxide.
What are the precautions for the use of 3,6-dichlorobenzene-1,2-dithiol?
3% 2C6 - carbon dioxide - 1% 2C2 - carbon disulfide during use, when paying attention to everything.
Carbon dioxide, a colorless and odorless gas, although non-toxic, can cause asphyxiation at high concentrations. In a poorly ventilated place, it may accumulate, so when using it, make sure that the place is well ventilated to prevent the concentration from being too high. And solid carbon dioxide, that is, dry ice, its temperature is extremely low, and it is easy to cause frostbite when touched by bare hands. When using it, it must be wrapped in thick materials or clamped with tools.
Carbon disulfide, volatile and flammable, is a high-risk chemical. Its steam and air can form an explosive mixture, and it is easy to burn and explode in case of open flames and hot topics. In the place where it is used, fireworks are strictly prohibited, and electrical equipment needs to be explosion-proof to prevent electrical sparks from causing explosions. And because it is harmful to the human body, it can invade the human body through the respiratory tract and skin, damaging the nervous system, liver, etc., so when working, you must wear protective clothing and gas masks to prevent contact and inhalation. Store it properly after use, and place it in a cool and ventilated compartment, away from fire and heat sources, and store it separately from oxidants and amines.
Both should be operated according to the specifications during use, and the emergency response method should be always prepared, so that the security is safe.
Carbon dioxide, a colorless and odorless gas, although non-toxic, can cause asphyxiation at high concentrations. In a poorly ventilated place, it may accumulate, so when using it, make sure that the place is well ventilated to prevent the concentration from being too high. And solid carbon dioxide, that is, dry ice, its temperature is extremely low, and it is easy to cause frostbite when touched by bare hands. When using it, it must be wrapped in thick materials or clamped with tools.
Carbon disulfide, volatile and flammable, is a high-risk chemical. Its steam and air can form an explosive mixture, and it is easy to burn and explode in case of open flames and hot topics. In the place where it is used, fireworks are strictly prohibited, and electrical equipment needs to be explosion-proof to prevent electrical sparks from causing explosions. And because it is harmful to the human body, it can invade the human body through the respiratory tract and skin, damaging the nervous system, liver, etc., so when working, you must wear protective clothing and gas masks to prevent contact and inhalation. Store it properly after use, and place it in a cool and ventilated compartment, away from fire and heat sources, and store it separately from oxidants and amines.
Both should be operated according to the specifications during use, and the emergency response method should be always prepared, so that the security is safe.
Scan to WhatsApp
