Linshang Chemical
PRODUCTS
Benzene, 1-Chloro-4-Iodo-2-Methyl-
Linshang Chemical
|
HS Code |
843477 |
| Chemical Formula | C7H6ClI |
| Molar Mass | 252.48 g/mol |
| Appearance | Solid (predicted) |
| Solubility In Water | Insoluble (predicted) |
| Solubility In Organic Solvents | Soluble in common organic solvents (predicted) |
| Hazard Class | Irritant (predicted) |
As an accredited Benzene, 1-Chloro-4-Iodo-2-Methyl- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100g of 1 - chloro - 4 - iodo - 2 - methyl - benzene in a sealed, labeled chemical container. |
| Storage | Store “Benzene, 1 - chloro - 4 - iodo - 2 - methyl -” in a cool, well - ventilated area, away from heat, sparks, and open flames as it may be flammable. Keep it in a tightly sealed container, preferably made of corrosion - resistant materials. Separate it from oxidizing agents and incompatible substances. Label the storage clearly for easy identification and to ensure proper handling. |
| Shipping | 1 - Chloro - 4 - iodo - 2 - methyl benzene is a chemical. Shipments should be in properly labeled, corrosion - resistant containers. Follow hazardous materials regulations, ensuring secure packaging to prevent leakage during transit. |
Competitive Benzene, 1-Chloro-4-Iodo-2-Methyl- 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 Benzene, 1-Chloro-4-Iodo-2-Methyl- in China?
As a trusted Benzene, 1-Chloro-4-Iodo-2-Methyl- 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 Benzene, 1-Chloro-4-Iodo-2-Methyl- 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 Chinese name of this compound?
The Chinese chemical name of this compound needs to be determined according to the specific compound structure. Due to the lack of specific compound-related information, it is impossible to be clear for the time being.
However, if you imitate the classical Chinese style of "Tiangong Kaiwu" to answer, you can make the following assumptions. Everything in the world has its name, and chemical things are no exception. All compound naming follows a certain rule. Looking at its constituent elements, examining the number of atoms, observing the connection of its valence bonds, and synthesizing various factors, you can get a precise name.
If a compound is composed of metals and non-metals, it is often preceded by metals and followed by non-metals, with the suffix "chemical", such as sodium chloride, which is formed by the combination of sodium and chloride. If the valence state of the same element in the compound is different, it is a clear difference, and it is also specially called. As for compounds containing polyatomic groups, the name of the group is also incorporated into it, so that the name can express its properties and structure.
However, due to the unknown specific morphology and composition of this compound, it is difficult to determine its exact Chinese chemical name. It is necessary to know the details of its element composition, atomic connection method, spatial structure, etc., and to determine its precise Chinese chemical name according to the established chemical naming rules.
However, if you imitate the classical Chinese style of "Tiangong Kaiwu" to answer, you can make the following assumptions. Everything in the world has its name, and chemical things are no exception. All compound naming follows a certain rule. Looking at its constituent elements, examining the number of atoms, observing the connection of its valence bonds, and synthesizing various factors, you can get a precise name.
If a compound is composed of metals and non-metals, it is often preceded by metals and followed by non-metals, with the suffix "chemical", such as sodium chloride, which is formed by the combination of sodium and chloride. If the valence state of the same element in the compound is different, it is a clear difference, and it is also specially called. As for compounds containing polyatomic groups, the name of the group is also incorporated into it, so that the name can express its properties and structure.
However, due to the unknown specific morphology and composition of this compound, it is difficult to determine its exact Chinese chemical name. It is necessary to know the details of its element composition, atomic connection method, spatial structure, etc., and to determine its precise Chinese chemical name according to the established chemical naming rules.
What are the physical properties of this compound?
This compound has a variety of physical properties. Its color state may be a colorless and transparent liquid or a white crystalline solid, depending on the characteristics and conditions of the compound.
Looking at its odor, some compounds emit a weak, almost imperceptible odor, while others have a strong and unique odor, either pungent or fragrant. The difference in odor is due to its molecular structure.
When it comes to solubility, in water, some compounds exhibit good solubility and can be miscible with water in any ratio, due to the formation of hydrogen bonds and other interactions between molecules and water molecules; while others are insoluble in water, only slightly soluble in water, due to the mismatch between molecular polarity and water molecules, such as compounds containing a large number of non-polar groups. In organic solvents, the solubility varies depending on the polarity of the organic solvent and the polarity of the compound. For example, some non-polar compounds are easily soluble in non-polar organic solvents such as carbon tetrachloride, benzene, etc., while polar compounds are more soluble in polar organic solvents such as ethanol and acetone.
When it comes to melting points and boiling points, different compounds vary greatly. Those with higher melting points and boiling points tend to have strong intermolecular forces, such as compounds that form ionic bonds or strong hydrogen bonds; while those with lower melting points and boiling points have weaker intermolecular forces, and are mostly small molecule compounds containing only van der Waals forces. This property is affected by various factors such as the molecular weight of the compound, the type of intermolecular forces, and the crystal structure.
Density varies depending on the type of compound. Some are denser than water and will sink to the bottom when placed in water; some are less dense than water and will float to the surface. The size of the density is related to the molecular weight of the compound and the degree of molecular accumulation.
In addition, the conductivity of the compound is also an important physical property. If it is an electrolyte compound, it can conduct electricity in an aqueous solution or in a molten state, generating free-moving ions due to ionization; if it is not an electrolyte compound, it is usually not conductive because there are no free-moving charged particles inside.
Looking at its odor, some compounds emit a weak, almost imperceptible odor, while others have a strong and unique odor, either pungent or fragrant. The difference in odor is due to its molecular structure.
When it comes to solubility, in water, some compounds exhibit good solubility and can be miscible with water in any ratio, due to the formation of hydrogen bonds and other interactions between molecules and water molecules; while others are insoluble in water, only slightly soluble in water, due to the mismatch between molecular polarity and water molecules, such as compounds containing a large number of non-polar groups. In organic solvents, the solubility varies depending on the polarity of the organic solvent and the polarity of the compound. For example, some non-polar compounds are easily soluble in non-polar organic solvents such as carbon tetrachloride, benzene, etc., while polar compounds are more soluble in polar organic solvents such as ethanol and acetone.
When it comes to melting points and boiling points, different compounds vary greatly. Those with higher melting points and boiling points tend to have strong intermolecular forces, such as compounds that form ionic bonds or strong hydrogen bonds; while those with lower melting points and boiling points have weaker intermolecular forces, and are mostly small molecule compounds containing only van der Waals forces. This property is affected by various factors such as the molecular weight of the compound, the type of intermolecular forces, and the crystal structure.
Density varies depending on the type of compound. Some are denser than water and will sink to the bottom when placed in water; some are less dense than water and will float to the surface. The size of the density is related to the molecular weight of the compound and the degree of molecular accumulation.
In addition, the conductivity of the compound is also an important physical property. If it is an electrolyte compound, it can conduct electricity in an aqueous solution or in a molten state, generating free-moving ions due to ionization; if it is not an electrolyte compound, it is usually not conductive because there are no free-moving charged particles inside.
What are the chemical properties of this compound?
This compound is a miraculous substance with many unique chemical properties. Its primary property is stability. Under normal conditions, it can last for a long time without changing easily, as if time has little effect on it. This stability allows the compound to be properly preserved in a variety of environments, acting like a strong fortress against external factors.
Furthermore, the compound has good solubility. In a specific solvent, it can be quickly and uniformly dispersed and dissolved, just like a fish entering water, free and evenly distributed. This property facilitates its use in many chemical reactions and industrial processes, making related operations smoother.
At the same time, the compound also exhibits significant reactivity. When confronted with specific reagents or conditions, it will actively participate in chemical reactions, just like a warrior who meets challenges and moves forward bravely. This activity makes it a key raw material for the synthesis of many other important compounds, playing a crucial role in the field of chemical synthesis.
In addition, the compound also has special resistance to heat. At higher temperatures, it can still maintain the stability of its own structure and properties, like a rock holding fast in a fire. This property makes it widely used in industrial production in high temperature environments or in specific experimental scenarios.
Finally, the compound also exhibits certain electrical conductivity. Although the electrical conductivity is not as excellent as that of metals, it is enough to play a unique role in some electronic fields, providing new possibilities for the application of electronic materials.
In summary, this compound has broad application prospects and research value in chemistry and related fields due to its various chemical properties such as stability, solubility, reactivity, heat resistance and electrical conductivity.
Furthermore, the compound has good solubility. In a specific solvent, it can be quickly and uniformly dispersed and dissolved, just like a fish entering water, free and evenly distributed. This property facilitates its use in many chemical reactions and industrial processes, making related operations smoother.
At the same time, the compound also exhibits significant reactivity. When confronted with specific reagents or conditions, it will actively participate in chemical reactions, just like a warrior who meets challenges and moves forward bravely. This activity makes it a key raw material for the synthesis of many other important compounds, playing a crucial role in the field of chemical synthesis.
In addition, the compound also has special resistance to heat. At higher temperatures, it can still maintain the stability of its own structure and properties, like a rock holding fast in a fire. This property makes it widely used in industrial production in high temperature environments or in specific experimental scenarios.
Finally, the compound also exhibits certain electrical conductivity. Although the electrical conductivity is not as excellent as that of metals, it is enough to play a unique role in some electronic fields, providing new possibilities for the application of electronic materials.
In summary, this compound has broad application prospects and research value in chemistry and related fields due to its various chemical properties such as stability, solubility, reactivity, heat resistance and electrical conductivity.
What fields is this compound used in?
This compound has a wide range of applications. In the matter of soldiers and soldiers, it can be used as a sharp weapon. Such as the arrow of a strong crossbow, with its strength, it can break the armor of the enemy, and injure the enemy from a distance, so that the enemy cannot come forward. It can also cast blades, and the edge of the blade is invincible, and it can help soldiers to kill the enemy bravely on the battlefield and defeat the enemy.
In the industry of civil construction, it is also of great use. With its solid quality, it can build a strong city. The city is strong, and it is difficult for foreign enemies to attack, to ensure the peace of the people, and to defend the territory of the state. And when building houses, it can be used as a material for beams and pillars, and to support the weight of the house, so that the house can stand for a long time without fear of wind and rain.
In farming, it is also indispensable. It can be used to make agricultural tools, such as ploughshares, which enter the soil smoothly and break the soil powerfully. It helps farmers to plow deeply and work hard, the fields can be cultivated, the grain can be plentiful, and the people can eat without worry. It can also be used as a sickle, and it is convenient to cut the ears of the harvest. When harvesting in autumn, it can help farmers with half the manpower and double the efficiency, and the warehouse is full.
In the art of craftsmen, it can also greatly display its ability. When making utensils, it can be used as key components to make utensils exquisite and durable. Such as the craftsman's machine, with its precision, utensils can operate freely, and all kinds of exquisite utensils can be invented for people's daily needs, which also shows the superb skills of craftsmen.
In short, this compound has great applications in the fields of military, industry, agriculture, and construction. It is actually an indispensable thing in the world. It is related to people's livelihood and national plans, and its role is extraordinary.
In the industry of civil construction, it is also of great use. With its solid quality, it can build a strong city. The city is strong, and it is difficult for foreign enemies to attack, to ensure the peace of the people, and to defend the territory of the state. And when building houses, it can be used as a material for beams and pillars, and to support the weight of the house, so that the house can stand for a long time without fear of wind and rain.
In farming, it is also indispensable. It can be used to make agricultural tools, such as ploughshares, which enter the soil smoothly and break the soil powerfully. It helps farmers to plow deeply and work hard, the fields can be cultivated, the grain can be plentiful, and the people can eat without worry. It can also be used as a sickle, and it is convenient to cut the ears of the harvest. When harvesting in autumn, it can help farmers with half the manpower and double the efficiency, and the warehouse is full.
In the art of craftsmen, it can also greatly display its ability. When making utensils, it can be used as key components to make utensils exquisite and durable. Such as the craftsman's machine, with its precision, utensils can operate freely, and all kinds of exquisite utensils can be invented for people's daily needs, which also shows the superb skills of craftsmen.
In short, this compound has great applications in the fields of military, industry, agriculture, and construction. It is actually an indispensable thing in the world. It is related to people's livelihood and national plans, and its role is extraordinary.
What are the methods for synthesizing this compound?
There are many kinds of synthetic methods for certain chemical compounds, each of which varies according to its properties and requirements. The following are several common methods:
One is an addition reaction. This is a method of combining unsaturated compounds with other molecules to form new compounds. For example, alkenes and halogens are added, the double bond is broken, and the halogen atom is connected to the carbon atom at both ends of the original double bond to obtain halogenated hydrocarbons. The reaction process is relatively direct, and only suitable reaction conditions and catalysts can be effectively achieved.
The second is a substitution reaction. This is a reaction in which an atom or group of atoms is substituted for another atom or group of atoms in a compound. Like the nucleophilic substitution reaction of halogenated hydrocarbons, halogen atoms can be replaced by nucleophilic reagents to form new organic compounds. This reaction requires precise control of the reaction process and product selectivity according to the activity and reaction conditions of the reactants.
The third is the condensation reaction. Two or multi-molecule compounds interact with each other and remove small molecules (such as water, ammonia, etc.) to form compounds with larger molecules. Such as esterification reaction, alcohol and carboxylic acid are condensed under acid catalysis to form esters and water, which is a common method for preparing ester compounds in organic synthesis.
The fourth is the redox reaction. By changing the oxidation state of the elements in the compound, the conversion of the compound is realized. Oxidation reactions can cause compounds to add oxygen atoms or lose hydrogen atoms, while reduction reactions are the other way around. For example, the oxidation of alcohols can generate aldodes or ketones, and the further oxidation of aldodes can give carboxylic acids; while carbonyl compounds can be reduced to alcohols under the action of reducing agents.
To synthesize a specific compound, a suitable synthesis method must be carefully selected according to its structural characteristics, required raw materials and reaction conditions. Sometimes a single method is difficult to achieve the goal, and it is necessary to combine multiple reactions and carefully design the synthesis route in order to successfully obtain the desired compound.
One is an addition reaction. This is a method of combining unsaturated compounds with other molecules to form new compounds. For example, alkenes and halogens are added, the double bond is broken, and the halogen atom is connected to the carbon atom at both ends of the original double bond to obtain halogenated hydrocarbons. The reaction process is relatively direct, and only suitable reaction conditions and catalysts can be effectively achieved.
The second is a substitution reaction. This is a reaction in which an atom or group of atoms is substituted for another atom or group of atoms in a compound. Like the nucleophilic substitution reaction of halogenated hydrocarbons, halogen atoms can be replaced by nucleophilic reagents to form new organic compounds. This reaction requires precise control of the reaction process and product selectivity according to the activity and reaction conditions of the reactants.
The third is the condensation reaction. Two or multi-molecule compounds interact with each other and remove small molecules (such as water, ammonia, etc.) to form compounds with larger molecules. Such as esterification reaction, alcohol and carboxylic acid are condensed under acid catalysis to form esters and water, which is a common method for preparing ester compounds in organic synthesis.
The fourth is the redox reaction. By changing the oxidation state of the elements in the compound, the conversion of the compound is realized. Oxidation reactions can cause compounds to add oxygen atoms or lose hydrogen atoms, while reduction reactions are the other way around. For example, the oxidation of alcohols can generate aldodes or ketones, and the further oxidation of aldodes can give carboxylic acids; while carbonyl compounds can be reduced to alcohols under the action of reducing agents.
To synthesize a specific compound, a suitable synthesis method must be carefully selected according to its structural characteristics, required raw materials and reaction conditions. Sometimes a single method is difficult to achieve the goal, and it is necessary to combine multiple reactions and carefully design the synthesis route in order to successfully obtain the desired compound.
Scan to WhatsApp
