Linshang Chemical
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Benzene, 1,2-Dichloro-4-Methyl-5-(Trifluoromethyl)-
Linshang Chemical
|
HS Code |
898186 |
| Chemical Formula | C7H5Cl2F3 |
| Molecular Weight | 215.015 |
| Solubility In Water | Expected to be low as it is an organohalide with non - polar groups |
| Solubility In Organic Solvents | Likely soluble in common organic solvents like ethanol, acetone due to its organic nature |
As an accredited Benzene, 1,2-Dichloro-4-Methyl-5-(Trifluoromethyl)- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100 - gram vial of 1,2 - dichloro - 4 - methyl - 5 - (trifluoromethyl)benzene, tightly sealed. |
| Storage | Store “Benzene, 1,2 - dichloro - 4 - methyl - 5 - (trifluoromethyl)-” in a cool, well - ventilated area away from heat, sparks, and open flames. Keep it in a tightly - sealed container to prevent leakage. Separate it from oxidizing agents, strong acids, and bases. Ensure storage is in a dedicated chemical storage area with proper labeling for easy identification and safety. |
| Shipping | Shipping of 1,2 - dichloro - 4 - methyl - 5 - (trifluoromethyl)benzene must comply with hazardous chemical regulations. It should be packaged securely in suitable containers to prevent leakage during transit. |
Competitive Benzene, 1,2-Dichloro-4-Methyl-5-(Trifluoromethyl)- 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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What are the chemical properties of this compound?
This compound has many chemical properties. It is acidic and alkaline, and can be acidic or alkaline in specific environments. When it encounters acid, it can neutralize with it according to its own alkalinity to generate corresponding salts and water; when it encounters alkali, if it is acidic, it can react to produce salts and other products.
The compound also has redox properties. In case of strong oxidants, it is easy to be oxidized, and its own valence increases, causing changes in structure and properties; in case of strong reducing agents, it can be reduced, and the valence decreases. For example, in a system with suitable redox pairs, a redox reaction can occur, promoting electron transfer and changing its own chemical form.
Its solubility is also an important property. In different solvents, the solubility varies greatly. In polar solvents, if the compound contains polar groups, it can exhibit good solubility by forming hydrogen bonds or electrostatic interaction with solvent molecules; while in non-polar solvents, the part containing non-polar structures is easy to interact with it, increasing solubility.
In addition, the compound may have thermal stability. When heated, depending on the chemical bond energy and structural stability, reactions such as decomposition and rearrangement will occur at a specific temperature. If the chemical bond energy is high and the structure is stable, the thermal stability is strong, and it needs a higher temperature to change; conversely, the chemical bond energy is weak, and it is easy to decompose or transform into other substances when heated.
At the same time, it may have optical activity. If there is a chiral center in the molecular structure, that is, the carbon atom is connected to four different groups, which can rotate the polarized light and exhibit optical rotation, which is of great significance in the fields of pharmaceutical chemistry and materials science.
The compound also has redox properties. In case of strong oxidants, it is easy to be oxidized, and its own valence increases, causing changes in structure and properties; in case of strong reducing agents, it can be reduced, and the valence decreases. For example, in a system with suitable redox pairs, a redox reaction can occur, promoting electron transfer and changing its own chemical form.
Its solubility is also an important property. In different solvents, the solubility varies greatly. In polar solvents, if the compound contains polar groups, it can exhibit good solubility by forming hydrogen bonds or electrostatic interaction with solvent molecules; while in non-polar solvents, the part containing non-polar structures is easy to interact with it, increasing solubility.
In addition, the compound may have thermal stability. When heated, depending on the chemical bond energy and structural stability, reactions such as decomposition and rearrangement will occur at a specific temperature. If the chemical bond energy is high and the structure is stable, the thermal stability is strong, and it needs a higher temperature to change; conversely, the chemical bond energy is weak, and it is easy to decompose or transform into other substances when heated.
At the same time, it may have optical activity. If there is a chiral center in the molecular structure, that is, the carbon atom is connected to four different groups, which can rotate the polarized light and exhibit optical rotation, which is of great significance in the fields of pharmaceutical chemistry and materials science.
What are the physical properties of this compound?
The physical reason of this compound, "Tiangong Wuwu": "This compound is hard and dense in nature. Its color is often white, with golden light, and it shines brightly under the light."
Its melting speed is high, and it needs to be fused by fire. As "Tiangong Wuwu" said: "If you want to make this compound melt, it must be burned for a long time." This is because the combined force of the atoms of the compound is low, and a large amount of energy is required to break it, so that it can be broken from solid to liquid.
Furthermore, its density is high, and it feels heavy in the hand. This is because the atomic arrangement is dense, and the number of atoms in the first place is large, and the amount of atoms is concentrated.
Its performance is also good, and the resistance to circulation is very small. In addition, the ductility of this compound can be traced, drawn, and can be formed into a thin sheet or a thin sheet, which is not easy to crack. As stated in "Tiangong": "Skillful craftsman can pull it, and it can be shaped without folding." This characteristic makes it widely used in multi-industry work.
Its hardness cannot be ignored, and it can be engraved on other objects, while its own surface is marked, indicating its hardness on the surface of the object.
Therefore, this compound has physical properties such as hardness, density, high melting, high density, good ductility, good ductility and high hardness. It has important uses in both work and life. It is indispensable in the past and the present.
Its melting speed is high, and it needs to be fused by fire. As "Tiangong Wuwu" said: "If you want to make this compound melt, it must be burned for a long time." This is because the combined force of the atoms of the compound is low, and a large amount of energy is required to break it, so that it can be broken from solid to liquid.
Furthermore, its density is high, and it feels heavy in the hand. This is because the atomic arrangement is dense, and the number of atoms in the first place is large, and the amount of atoms is concentrated.
Its performance is also good, and the resistance to circulation is very small. In addition, the ductility of this compound can be traced, drawn, and can be formed into a thin sheet or a thin sheet, which is not easy to crack. As stated in "Tiangong": "Skillful craftsman can pull it, and it can be shaped without folding." This characteristic makes it widely used in multi-industry work.
Its hardness cannot be ignored, and it can be engraved on other objects, while its own surface is marked, indicating its hardness on the surface of the object.
Therefore, this compound has physical properties such as hardness, density, high melting, high density, good ductility, good ductility and high hardness. It has important uses in both work and life. It is indispensable in the past and the present.
What fields is this compound used in?
This compound is widely used and has applications in many fields.
In the field of medicine, it may be a key raw material for drug synthesis. Taking a certain type of special agent as an example, this compound can be converted into an active ingredient with unique curative effect after being treated by a specific process, which can precisely act on specific cell targets in the human body, and is quite effective in the treatment of difficult and miscellaneous diseases. According to its characteristics, doctors can skillfully prepare it, or create a good prescription to help patients get rid of pain.
In the chemical industry, this compound is the cornerstone of many fine chemicals. For example, the preparation of high-end coatings, the addition of this compound can significantly improve the weathering resistance, wear resistance and adhesion of coatings. Whether it is the exterior walls of high-rise buildings or the surface protection of industrial equipment, after being treated with this coating, it can maintain a good state for a long time in complex environments, reducing maintenance costs and prolonging service life. Another example is the synthesis of some high-performance plastics. The addition of this compound can optimize the physical properties of plastics, making them have higher strength, toughness and heat resistance, so as to meet the strict requirements of materials in high-end fields such as aerospace and automobile manufacturing.
In the field of agriculture, it may become an important component of new pesticides or fertilizers. As a pesticide, it can precisely target specific pests and diseases, effectively inhibit or kill pests, and has a relatively small impact on the environment, helping to achieve green agricultural production. As a fertilizer additive, it can improve soil structure, increase fertilizer utilization rate, promote crop root growth and nutrient absorption, thereby improving crop yield and quality, and ensuring food security.
In the field of materials science, it also plays an important role in the research and development of new functional materials. By regulating and modifying its molecular structure, researchers can prepare materials with special optical, electrical or magnetic properties. Such materials may be applied to cutting-edge fields such as electronic devices and optical instruments to promote the progress and innovation of science and technology, and open up new possibilities for future scientific and technological development.
In the field of medicine, it may be a key raw material for drug synthesis. Taking a certain type of special agent as an example, this compound can be converted into an active ingredient with unique curative effect after being treated by a specific process, which can precisely act on specific cell targets in the human body, and is quite effective in the treatment of difficult and miscellaneous diseases. According to its characteristics, doctors can skillfully prepare it, or create a good prescription to help patients get rid of pain.
In the chemical industry, this compound is the cornerstone of many fine chemicals. For example, the preparation of high-end coatings, the addition of this compound can significantly improve the weathering resistance, wear resistance and adhesion of coatings. Whether it is the exterior walls of high-rise buildings or the surface protection of industrial equipment, after being treated with this coating, it can maintain a good state for a long time in complex environments, reducing maintenance costs and prolonging service life. Another example is the synthesis of some high-performance plastics. The addition of this compound can optimize the physical properties of plastics, making them have higher strength, toughness and heat resistance, so as to meet the strict requirements of materials in high-end fields such as aerospace and automobile manufacturing.
In the field of agriculture, it may become an important component of new pesticides or fertilizers. As a pesticide, it can precisely target specific pests and diseases, effectively inhibit or kill pests, and has a relatively small impact on the environment, helping to achieve green agricultural production. As a fertilizer additive, it can improve soil structure, increase fertilizer utilization rate, promote crop root growth and nutrient absorption, thereby improving crop yield and quality, and ensuring food security.
In the field of materials science, it also plays an important role in the research and development of new functional materials. By regulating and modifying its molecular structure, researchers can prepare materials with special optical, electrical or magnetic properties. Such materials may be applied to cutting-edge fields such as electronic devices and optical instruments to promote the progress and innovation of science and technology, and open up new possibilities for future scientific and technological development.
What is the preparation method of this compound?
The preparation method of a chemical compound (suspected to be a compound) involves many elements, and it is necessary to specify what kind of compound it is in order to describe it accurately. However, I will discuss the common preparation methods in general, which will help.
If it is an inorganic substance, its preparation is based on the principle of chemical reaction. Such as a compound reaction, in which two or more simple substances are reacted to form a complex compound. For example, if you want to make carbon dioxide, the carbon can be burned in sufficient oxygen, and the reaction formula is:\ (C + O_2\ stackrel {ignited }{=\!=\!=} CO_2\). Decomposition reactions are also commonly used, in which a compound is decomposed into two or more substances under specific conditions. If calcium carbonate is calcined at high temperature, calcium oxide and carbon dioxide can be obtained. The reaction formula is:\ (CaCO_3\ stackrel {high temperature }{=\!=\!=} CaO + CO_2 ↑\).
The metathesis reaction is also an important way to prepare inorganic substances. The two compounds exchange components with each other to form two new compounds. For example, silver nitrate and sodium chloride are reacted to prepare silver chloride precipitation, and the reaction formula is:\ (AgNO_3 + NaCl =\!=\!= AgClφ + NaNO_3\).
As for the preparation of organic matter, the method is more complicated. Taking the preparation of hydrocarbons as an example, it can be obtained by means of petroleum fractionation, cracking, and cracking. If petroleum cracking can produce ethylene, ethylene is an important raw material for many organic synthesis. The preparation of alcohols can be obtained by fermentation method, and sugars can be fermented under the action of microorganisms to obtain ethanol, which is complicated and requires suitable conditions. Or the addition of olefins and water to produce alcohols, such as ethylene and water under the action of catalysts to generate ethanol, the reaction formula is:\ (CH_2 = CH_2 + H_2O\ stackrel {catalyst }{=\!=\!=} CH_3CH_2OH\).
esters are often prepared by esterification of alcohols and carboxylic acids catalyzed by concentrated sulfuric acid under heating conditions. If acetic acid reacts with ethanol to form ethyl acetate, the reaction formula is:\ (CH_3COOH + C_2H_5OH\ underset {\ triangle} {\ overset {concentrated sulfuric acid} {\ rightleftharpoons}} CH_3COOC_2H_5 + H_2O\).
Preparation of compounds requires careful consideration of its properties, required raw materials, reaction conditions and cost-effectiveness, and the optimal method can be selected to achieve efficient, economical and environmentally friendly preparation goals.
If it is an inorganic substance, its preparation is based on the principle of chemical reaction. Such as a compound reaction, in which two or more simple substances are reacted to form a complex compound. For example, if you want to make carbon dioxide, the carbon can be burned in sufficient oxygen, and the reaction formula is:\ (C + O_2\ stackrel {ignited }{=\!=\!=} CO_2\). Decomposition reactions are also commonly used, in which a compound is decomposed into two or more substances under specific conditions. If calcium carbonate is calcined at high temperature, calcium oxide and carbon dioxide can be obtained. The reaction formula is:\ (CaCO_3\ stackrel {high temperature }{=\!=\!=} CaO + CO_2 ↑\).
The metathesis reaction is also an important way to prepare inorganic substances. The two compounds exchange components with each other to form two new compounds. For example, silver nitrate and sodium chloride are reacted to prepare silver chloride precipitation, and the reaction formula is:\ (AgNO_3 + NaCl =\!=\!= AgClφ + NaNO_3\).
As for the preparation of organic matter, the method is more complicated. Taking the preparation of hydrocarbons as an example, it can be obtained by means of petroleum fractionation, cracking, and cracking. If petroleum cracking can produce ethylene, ethylene is an important raw material for many organic synthesis. The preparation of alcohols can be obtained by fermentation method, and sugars can be fermented under the action of microorganisms to obtain ethanol, which is complicated and requires suitable conditions. Or the addition of olefins and water to produce alcohols, such as ethylene and water under the action of catalysts to generate ethanol, the reaction formula is:\ (CH_2 = CH_2 + H_2O\ stackrel {catalyst }{=\!=\!=} CH_3CH_2OH\).
esters are often prepared by esterification of alcohols and carboxylic acids catalyzed by concentrated sulfuric acid under heating conditions. If acetic acid reacts with ethanol to form ethyl acetate, the reaction formula is:\ (CH_3COOH + C_2H_5OH\ underset {\ triangle} {\ overset {concentrated sulfuric acid} {\ rightleftharpoons}} CH_3COOC_2H_5 + H_2O\).
Preparation of compounds requires careful consideration of its properties, required raw materials, reaction conditions and cost-effectiveness, and the optimal method can be selected to achieve efficient, economical and environmentally friendly preparation goals.
What is the environmental impact of this compound?
A certain compound is found in the environment, which has a wide range of effects on living things and the state of nature.
If this compound is toxic, it can be released into the environment or cause death to living beings. In light cases, the physiological functions of organisms are disrupted, and growth and reproduction are blocked. For example, many aquatic organisms are exposed to water bodies containing toxic compounds, or they are developing deformities, the hatching rate is reduced, and the survival rate of larvae is also low. In severe cases, the number of biological populations may decrease sharply and the ecological balance will be disrupted. Taking birds as an example, if they accidentally eat poisoned food, they may cause damage to the reproductive system, reduce egg production, and thinner eggshells, endangering the continuation of the population.
And the compound may accumulate and accumulate in the environment. Passed through the food chain layer by layer, the concentration gradually increases. If plankton ingest trace compounds, small fish eat them, and the compounds accumulate in the small fish, and the big fish eat the small fish again, the compound concentration is higher in the big fish. Humans at the top of the food chain are also affected by it, leading to various health diseases, such as cancer, neurological diseases, etc.
Furthermore, it also has a significant impact on natural environmental factors. In the soil, or change its physical and chemical properties, inhibit soil microbial activity, reduce soil fertility, and hinder plant growth. In the water body, it may cause water quality to deteriorate, dissolved oxygen to decrease, and aquatic ecology to be damaged. In the atmosphere, if compounds evaporate or participate in atmospheric chemical reactions, or cause air quality to decline, cause acid rain, smog and other bad weather, damage vegetation and buildings.
Longitudinal compounds are non-toxic, exist in large quantities in the environment, and may cause ecological problems. Such as changing the pH of water bodies, osmotic pressure, etc., affecting the survival of organisms. Or occupy ecological niches, interfere with the normal activities of other organisms, and disrupt the inherent material cycle and energy flow of the ecosystem.
Therefore, whether compounds are toxic or not to the environment, they should be treated with caution, and their environmental behavior and impact should be carefully studied to reduce their negative effects and maintain ecological harmony and stability.
If this compound is toxic, it can be released into the environment or cause death to living beings. In light cases, the physiological functions of organisms are disrupted, and growth and reproduction are blocked. For example, many aquatic organisms are exposed to water bodies containing toxic compounds, or they are developing deformities, the hatching rate is reduced, and the survival rate of larvae is also low. In severe cases, the number of biological populations may decrease sharply and the ecological balance will be disrupted. Taking birds as an example, if they accidentally eat poisoned food, they may cause damage to the reproductive system, reduce egg production, and thinner eggshells, endangering the continuation of the population.
And the compound may accumulate and accumulate in the environment. Passed through the food chain layer by layer, the concentration gradually increases. If plankton ingest trace compounds, small fish eat them, and the compounds accumulate in the small fish, and the big fish eat the small fish again, the compound concentration is higher in the big fish. Humans at the top of the food chain are also affected by it, leading to various health diseases, such as cancer, neurological diseases, etc.
Furthermore, it also has a significant impact on natural environmental factors. In the soil, or change its physical and chemical properties, inhibit soil microbial activity, reduce soil fertility, and hinder plant growth. In the water body, it may cause water quality to deteriorate, dissolved oxygen to decrease, and aquatic ecology to be damaged. In the atmosphere, if compounds evaporate or participate in atmospheric chemical reactions, or cause air quality to decline, cause acid rain, smog and other bad weather, damage vegetation and buildings.
Longitudinal compounds are non-toxic, exist in large quantities in the environment, and may cause ecological problems. Such as changing the pH of water bodies, osmotic pressure, etc., affecting the survival of organisms. Or occupy ecological niches, interfere with the normal activities of other organisms, and disrupt the inherent material cycle and energy flow of the ecosystem.
Therefore, whether compounds are toxic or not to the environment, they should be treated with caution, and their environmental behavior and impact should be carefully studied to reduce their negative effects and maintain ecological harmony and stability.
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