1,4-Di(Dichloromethyl)Benzene
Linshang Chemical
HS Code |
927850 |
Name | 1,4-Di(Dichloromethyl)Benzene |
Molecular Formula | C8H6Cl4 |
Molar Mass | 245.94 g/mol |
Appearance | White to off - white solid |
Odor | Characteristic |
Melting Point | 99 - 101 °C |
Boiling Point | 318 - 320 °C |
Density | 1.48 g/cm³ |
Solubility In Water | Insoluble |
Solubility In Organic Solvents | Soluble in many organic solvents like benzene, toluene |
As an accredited 1,4-Di(Dichloromethyl)Benzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
Packing | 1,4 - di(dichloromethyl)benzene: Packed in 50 - kg drums for secure storage and transport. |
Storage | 1,4 - Di(dichloromethyl)benzene should be stored in a cool, dry, well - ventilated area. Keep it away from sources of heat, ignition, and incompatible substances like oxidizing agents. Store in a tightly - sealed container, preferably made of corrosion - resistant materials, to prevent leakage and exposure to air or moisture, which could potentially lead to chemical reactions. |
Shipping | 1,4 - Di(dichloromethyl)benzene is a chemical. Shipping requires proper containment in approved vessels, following strict regulations for hazardous chemicals to ensure safe transport and prevent environmental and safety risks. |
Competitive 1,4-Di(Dichloromethyl)Benzene 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


As a leading 1,4-Di(Dichloromethyl)Benzene supplier, we deliver high-quality products across diverse grades to meet evolving needs, empowering global customers with safe, efficient, and compliant chemical solutions.
The first is in the field of organic synthesis. It can be used as a key intermediary for the preparation of various fine chemicals. For example, in the field of pharmaceutical synthesis, it can be used as a starting material to undergo a series of chemical reactions and be converted into drug intermediates with specific structures, laying the foundation for the creation of new drugs. Because of the specific functional groups contained in its structure, it can participate in a variety of organic reactions, such as nucleophilic substitution, condensation and other reactions. By rationally designing the reaction route, complex organic molecular structures can be precisely constructed.
Furthermore, it also plays an important role in the field of materials science. 1,4-di (diethoxymethyl) benzene can be used to synthesize polymer materials with special properties. By copolymerizing with other monomers, polymer materials can be endowed with unique properties, such as improving the solubility and processability of the material, or endowing the material with specific optical and electrical properties. For example, when preparing some high-performance coatings and adhesives, adding this substance can optimize the performance of the product, making it have better adhesion and weather resistance.
In the fragrance industry, 1,4-di (diethoxymethyl) benzene is also useful. Due to its unique odor, after blending and processing, it can be applied to fragrance formulations, adding a unique flavor to fragrances, enriching the layering of fragrances, and may play a finishing touch when blending certain floral and fruity fragrances.
In addition, in the field of chemical research, it is often used as a model compound to help researchers delve deeper into the mechanisms and laws of organic reactions. Because of its relatively clear and representative structure, studying the chemical reactions it participates in helps to understand more complex organic reaction processes, providing an important basis for the development of organic chemistry theory.
From the perspective of boiling point, it is in a specific temperature range. Under certain conditions, it will gradually transform from liquid to gaseous when heated. This boiling point characteristic determines its phase change in a specific temperature environment, just like the transition of phenology when solar terms alternate.
Furthermore, the melting point is also one of its important physical properties. At a specific low temperature, it will solidify from liquid to solid state, just like water freezes in cold winter, showing a different form.
Its density also has a unique value. Compared with common substances, either light or heavy, it shows its own ups and downs in various media, as if following a unique law.
In terms of solubility, it can be better dissolved in some organic solvents, like salt in water, but it is difficult to miscible in other solvents, like oil and water. This difference in solubility provides the basis for its application in different fields.
In addition, the volatility of this substance has a certain degree at room temperature, and it will gradually spread to the surrounding environment, emitting a unique smell. Although this smell is not pungent, it is also unique, as if it leaves its own unique mark in the air. These physical properties are interrelated and constitute the unique physical properties of 1% 2C4-% E4% BA% 8C (%E4%BA%8C%E6%B0%AF%E7%94%B2%E5%9F%BA) % E8% 8B% AF, which lays the foundation for its application in many fields such as chemical industry and materials.
From the perspective of reactivity, its electrophilic substitution reactivity may be slightly higher than that of benzene, and the electron-giving effect of the edge diethylamino group can increase the density of the o-and para-electron cloud of the benzene ring even more, which is conducive to the However, compared with many active organic compounds, this substance still requires specific reaction conditions to react. For example, halogenation reactions may require suitable catalysts and reaction temperatures to replace the hydrogen atoms on the benzene ring with halogen atoms.
In the oxidation reaction, if there is no special strong oxidant and severe conditions, the benzene ring itself is difficult to be oxidized and broken. Although the diethylamino group may be oxidized under specific strong oxidation conditions, it does not occur easily. In the general environment, if there is no strong external chemical action, the chemical structure of this compound can maintain a relatively stable state, and the chemical properties will not change drastically.
The quality of the first raw material is very important. The raw material of diethoxymethyl used must be pure and free of impurities. If impurities exist, the reaction will be biased and the product will be impure. Therefore, before the raw materials are put into the kettle, they should be tested in detail to ensure high quality.
Times and the temperature of the reaction. This reaction is smooth at a suitable temperature. If the temperature is too low, the reaction is slow and time-consuming; if the temperature is too high, it may cause a cluster of side reactions, and the rate and quality of the product will be harmed. Therefore, when the reaction is carried out, the method of exquisite temperature control should be used to keep the temperature stable in the appropriate range.
Furthermore, the choice of solvent. Solvent, in the reaction, can adjust the solubility of the reactants and help the reaction proceed. The selected solvent must be in harmony with the reactants, and the boiling point is appropriate, which is convenient for subsequent separation. If the solvent is improper, or the reaction is blocked, the product is difficult to separate.
And the reaction time is long. When the reaction is not sufficient, the formation of the product is not completed; the reaction is delayed, or the product is decomposed. Therefore, when the experiment is carried out in detail, it is clear that the optimal time is enough to make the reaction just right.
The step of separation and purification should not be ignored. After the reaction is completed, the product may be mixed with unsuitable raw materials, by-products, etc. It is necessary to use suitable methods, such as distillation, extraction, recrystallization, etc., to finely separate to obtain pure products.
During operation, safety regulations must be strictly observed. The raw materials, solvents, etc. used may be toxic, flammable, and explosive. Therefore, the experimental site should be well ventilated, fully protected, and the operator is familiar with safety procedures to prevent accidents.
Preparation of 1% 2C4-bis (diethoxy methyl) benzene should be handled with caution in terms of raw materials, temperature, solvent, duration, separation, and safety.
If it is first mentioned in the atmosphere, if it escapes in the air, it may disperse with the airflow. However, it has a certain volatility and can interact with other substances in the atmosphere. Or involved in photochemical reactions, under sunlight, in contact with free radicals, or new pollutants, or photochemical smog, etc., disturb the purity of the atmosphere, hinder people's breathing, damage the function of the lungs and organs, and also hinder plants, causing their photosynthesis and other physiological effects to be trapped.
As for the water environment, if this substance enters the water body, it has a certain solubility, or dissolves in the water. Aquatic organisms bear the brunt, or cause their physiological disorders. For example, fish may hinder their respiration and feeding, damage their nervous and reproductive systems, and cause population decline. And it may be transmitted and enriched through the food chain, reaching high organisms, tiring the human body and harmful to health.
In the soil, it can exist among soil particles, hindering the physical and chemical properties of the soil. Or cause soil pore blockage, affect ventilation and water permeability, damage the survival and activity of soil microorganisms, disrupt soil ecological balance, and then affect the growth and nutrient absorption of plant roots, resulting in reduced crop yield and quality.
In short, 1% 2C4-bis (dioxyethyl) benzene has a wide and deep impact on the environment, and it must be handled with caution to prevent its wanton spread, so as to protect the ecological safety and environmental beauty.

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