2-Pyridinemethanamine,4-methoxy-(9CI)

2-Pyridinemethanamine, 4-methoxy - (9CI) is associated with a methoxy group at position 4 of the pyridine ring, carbon at position 2 of the pyridine ring is connected to a methylene group, and the methylene group is connected to an amino group. This is an organic compound whose pyridine ring is aromatic, and the methoxy group has an electron-giving effect, which can affect the electron cloud distribution and chemical properties of the molecule. The amino group makes the compound alkaline and can participate in various chemical reactions, such as nucleophilic substitution reactions. Its structural characteristics determine that it may have potential applications in the fields of organic synthesis and medicinal chemistry, perhaps as an intermediate to prepare compounds with specific biological activities.

2-Pyridyl methylamine, 4-methoxyl- (9CI), this substance has a wide range of uses. In the field of medicine, it may be a key intermediate to assist in the synthesis of drugs with specific physiological activities. Due to the structural properties of pyridine and methoxy groups, chemical modifications can be used to adjust the molecular physicochemical properties and biological activities of drugs, such as improving drug solubility and stability, enhancing affinity to specific targets, and thereby improving drug efficacy and safety.
In the field of materials science, or participate in the preparation of functional materials. The structure of pyridine gives it the ability to coordinate with metal ions, which can be used to construct complex materials with unique optical, electrical or magnetic properties, showing application potential in sensors, luminescent materials, etc. The presence of 4-methoxy groups can adjust the electron cloud distribution of materials and affect their optoelectronic properties.
In the field of organic synthesis, it is an important synthetic building block. With the activity of amino and pyridine rings, complex organic molecular structures can be constructed through various chemical reactions, such as nucleophilic substitution, condensation reactions, etc., providing a variety of strategies for organic synthesis chemistry, enriching the types of organic compounds, and promoting the development of organic synthesis methodologies.
In scientific research and exploration, as a research object, scientists can deepen their understanding of the basic principles of organic chemistry by studying its reaction mechanism and property change laws, and provide support for the theoretical development of related fields. This substance plays an important role in many fields. With the deepening of research, its potential uses may be further expanded.

4-Methoxy-2-pyridylmethylamine (9CI) is one of the organic compounds. Its physical properties are as follows:
Under normal temperature and pressure, it is mostly colorless to light yellow liquid, with a clear and specific luster. Smell it, often with a weak amine-specific smell, but it is not as pungent as the common volatile strong alkali, only slightly irritating.
As for the melting point, the melting point is low, and it is not a solid state under common ambient temperatures. The boiling point varies slightly according to the air pressure conditions, roughly within a certain temperature range of boiling vaporization. This range is about a certain range depending on the experimental conditions, or there is a slight difference, but it is about a certain range. < Br >
In terms of solubility, in organic solvents, such as ethanol, ether, etc., it has good solubility and can be miscible with many organic solvents to form a uniform solution. In water, its solubility is slightly inferior, but it is not completely insoluble. It can be dissolved to a certain extent, which is related to the polar groups contained in the molecular structure of the compound.
The density may be different from that of water, showing a specific value. If it is co-placed with water, it can be seen that its stratification phenomenon.
The physical properties of this compound are crucial in the fields of organic synthesis, medicinal chemistry, etc. Because it is related to the setting of reaction conditions, the separation and purification of products, and many other links, scholars cannot ignore it when studying.

To prepare 2-pyridyl methylamine, 4-methoxyl- (9CI), the method is as follows:
First take the appropriate pyridine compound as the starting material. With the characteristics of the pyridine ring, the methoxy group is introduced at a specific position. In this step, the alkoxy group may be substituted for the hydrogen atom at a specific position under suitable reaction conditions by means of the action of halogenated alkanes and bases to obtain a methoxy-containing pyridine intermediate.
Then, the α-position of the pyridine ring is methylated by amine. Suitable formaldehyde and amine compounds can be selected. Under the catalysis of acid or base, the amine methyl structure is introduced into the α-position of the pyridine ring by Mannich reaction to generate the desired 2-pyridylmethylamine, 4-methoxyl- (9CI) products. In this process, the reaction temperature, the proportion of reactants, the amount of catalyst and other factors are all crucial and need to be carefully regulated. After the reaction, the pure target product can be obtained by separation and purification methods such as extraction, distillation, column chromatography, etc. In this way, 2-pyridylmethylamine, 4-methoxyl- (9CI) can be prepared.

4-Methoxy-2-pyridylmethylamine (9CI), this is an organic compound. Looking at its market prospects, it has great potential in the field of chemical synthesis. Due to its special chemical structure, it can be used as a key intermediate for creating multiple and complex organic molecules. In the field of pharmaceutical research and development, it may become the cornerstone of the molecular structure of new drugs. After rational modification and derivatization, it is expected to breed lead compounds with specific biological activities, paving the way for the development of new drugs to overcome difficult diseases.
In the field of materials science, it has also emerged. It can participate in the construction of functional materials, giving materials such as special optical, electrical or adsorption properties. For example, in the preparation of optoelectronic materials, the introduction of this compound through clever design may optimize the charge transport and luminous efficiency of the material, promoting the progress of the organic optoelectronic industry.
However, its market expansion also faces challenges. Optimization of the synthesis process is crucial, and it is necessary to reduce costs, improve yield and purity in order to enhance market competitiveness. And related research is still in the development stage, and researchers need to work closely with the industry to deeply explore its performance and application, in order to fully tap the market value, broaden the application territory, and make this compound shine in various fields, achieving extraordinary market achievements.