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What is the chemical structure of 4- (3-methylphenyl) amino-3-pyridyl sulfonamide (SMPAP)?
The chemical structure of 4- (3-methylbenzyl) amino-3-tracer urea (SMPAP) to it is a rather complex organic compound structure. Its structure contains specific carbon, hydrogen, nitrogen, oxygen and other atoms connected to each other.
Looking at the whole, the benzene ring is an important structural basis. On the benzene ring, 3-methylbenzyl is attached to it as a substituent. This substituent contains a combination of methyl and benzyl, giving the molecule a specific spatial structure and chemical activity. The amino-3-tracer urea part is connected to the benzene ring through chemical bonds to form a more complex organic system. The urea moiety has a specific structural feature of carbonyl-amino connection, which plays an important role in the whole molecular structure, and its chemical properties have a profound impact on the activity and reactivity of the whole compound.
In this chemical structure, the bonding mode and spatial arrangement of atoms are constructed according to the bonding rules of organic chemistry and the principle of stereochemistry. The mutual influence of each group makes the compound have unique physical and chemical properties, which may have potential application value and research significance in the fields of organic synthesis, medicinal chemistry, etc. In this way, it is the approximate chemical structure and morphology of 4- (3-methylbenzyl) amino-3-tracer urea (SMPAP) to it.
What are the main uses of 4- (3-methylphenyl) amino-3-pyridyl sulfonamide (SMPAP)?
4- (3-methylbenzyl) amino-3-trace urea (SMPAP) to it, its main uses are many.
In agriculture, it can be used to promote the growth of grains, vegetables and fruits. After this, the stems of crops are tougher, the branches and leaves are more and more lush, and the fruits are full and large, thereby improving the yield and quality. And it can strengthen the resilience of crops, so that they can still grow well in harsh environments such as drought, flood, cold and heat.
In the field of horticulture, it can help flower seedlings thrive, make the flowers more colorful, and the flowering period can be extended. The branches of the seedlings are tall and straight, and the leaves are green, adding color to the garden landscape.
For scientific research, as a key bioactive substance, it can assist in the study of plant growth and development mechanisms, hormone regulation pathways, etc. Through its application and observation, it is helpful to gain a deeper understanding of the nature of plant life activities and provide support for the development of botanical theory.
At the industrial level, it can be used as a raw material to produce specific plant growth regulators, biofertilizers and other products. Through industrial production and application, it is widely used in agriculture, horticulture and other industries to promote the development of related industries.
From this point of view, 4- (3-methylbenzyl) amino-3-tracer urea (SMPAP) has important uses in many fields and is of great significance to production and scientific research.
What is the preparation method of 4- (3-methylphenyl) amino-3-pyridyl sulfonamide (SMPAP)?
To prepare 4- (3-methylbenzyl) amino-3-tracer urea (SMPAP), the preparation method is as follows:
First take an appropriate amount of starting materials and follow the conventional steps of organic synthesis. In the reaction vessel, put in the benzene compound containing the corresponding substituent, which is the basis for building the molecular skeleton. Then, the reaction conditions, such as temperature, pressure and reaction time, are carefully controlled to enable it to react delicately with suitable amino-containing reagents to introduce key amino groups. This step requires special attention to the selectivity and yield of the reaction to prevent the growth of side reactions.
Then, specific urea reagents are added, and with the help of ingenious reaction mechanisms, the urea group is precisely integrated into the molecular structure to achieve the structural construction of urea tracer to it. During the reaction process, the changes of the reaction should be closely monitored, and the degree of reaction and the purity of the product can be timely grasped by modern analytical methods such as thin layer chromatography and nuclear magnetic resonance.
After the reaction is roughly completed, careful post-processing steps are required. First, the product is initially precipitated from the reaction mixture system by separation methods such as extraction and filtration, and most of the impurities are removed. Then, purification techniques, such as recrystallization, column chromatography, etc., were performed to further improve the purity of the product, so that the obtained 4- (3-methylbenzyl) amino-3-tracer urea (SMPAP) reached the required quality standard. In this way, the target compound can be prepared.
What are the physical properties of 4- (3-methylphenyl) amino-3-pyridyl sulfonamide (SMPAP)?
The physical properties of 4- (3-methylbenzyl) amino-3-tracer amines (SMPAP) are related to the investigation of the properties of chemical substances. This SMPAP, in terms of its physical properties, is quite complex and unique.
Look at its appearance, or show a specific color and morphology. Or in the state of powder, fine and uniform, the color may vary slightly due to different purity and preparation process, or white as snow, or slightly yellow.
Its melting point and boiling point are also key physical properties. Determination of melting point requires precision instruments and rigorous operation, because melting point can reflect the strength of intermolecular forces. The boiling point is related to the temperature point at which a substance changes from a liquid state to a gaseous state under a specific pressure, both of which are of great significance in the separation, purification and application of substances.
The solubility cannot be ignored either. In common organic solvents, or exhibit different solubility characteristics. In polar solvents, such as ethanol and acetone, or with certain solubility, a uniform solution can be formed; in non-polar solvents, such as n-hexane and toluene, the solubility is poor, or only slightly soluble, or even insoluble, which is closely related to the polarity of the molecule.
In addition, density is also one of its physical properties. The size of the density can help provide a key reference in practical applications, such as the design of mixed systems and the separation of substances. And its refractive index can also reflect the characteristics of the internal structure and molecular arrangement of the substance. By accurately measuring the refractive index, the purity and structural characteristics of the substance can be further understood.
The physical properties of this 4 - (3-methylbenzyl) amino-3 - tracer amine (SMPAP) are indispensable basic information in chemical research, industrial production and related fields. It needs to be explored and analyzed by researchers with a rigorous attitude and precise methods.
What are the safety and toxicity of 4- (3-methylphenyl) amino-3-pyridyl sulfonamide (SMPAP)?
What are the safety and toxicity of 4 - (3 - methylbenzyl) amino - 3 - trace urea to it (SMPAP)?
Let me look at this substance, in order to understand its safety and toxicity, we should consider various factors in detail. First of all, safety, when this compound is used for a specific purpose, under suitable environment and dosage, it may be safe to a certain extent. However, in its chemical structure, the combination of methyl benzyl and amino groups may pose a latent risk. If it comes into contact with the human body, it is necessary to check whether it will cause allergies, irritation and other reactions.
As for toxicity, from the chemical essence theory, the nitrogen-containing amino and urea structures may produce toxic intermediates during metabolism. In living organisms, or interfere with normal biochemical reactions, such as affecting enzyme activities and cell metabolic pathways. And if it enters the environment, it also needs to consider the impact on the ecosystem, such as aquatic organisms, soil microorganisms, etc.
If used in industrial production, the conditions of the production process have a great impact on its safety and toxicity. If temperature, pressure, reaction time and other factors are inappropriate, or the product is impure and contains highly toxic impurities.
Although detailed experimental data are not available, it is speculated that the use of this 4- (3-methylbenzyl) amino-3-trace urea (SMPAP) should be used with caution, and its safety and toxicity should be carefully studied to prevent potential hazards.
