3 Pyridinecarboxylic Acid 6 Formyl Methyl Ester
pyridine pyrrole pyrazine piperidine piperazine

3-Pyridinecarboxylic acid, 6-formyl-, methyl ester

    Specifications

    HS Code

    176022

    Chemical Formula C7H7NO3
    Molar Mass 153.14 g/mol
    Appearance Solid (usually)
    Melting Point Data may vary
    Boiling Point Data may vary
    Solubility Solubility characteristics depend on solvents
    Density Data may vary
    Pka Data may vary
    Flash Point Data may vary
    Vapor Pressure Data may vary

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    General Information
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    Frequently Asked Questions

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    What is the chemical structure of 3-Pyridinecarboxylic acid, 6-formyl-, methyl ester
    3-Pyridinecarboxylic acid, 6-formyl-, methyl ester, this is a kind of organic compound. Looking at its naming, its structure can be deduced according to the naming rules of organic chemistry. "3-pyridinecarboxylic acid" indicates that there is a formic acid group at the 3rd position of the pyridine ring. "6-formyl-" means that the 6-position formyl group of the pyridine ring is added (-CHO). "Methyl ester" indicates that the formic acid group forms an ester with methanol, that is, the carboxyl group of the formic acid group (-COOH) is dehydrated and condensed with the hydroxyl group of methanol (-OH) to form an ester group (-COOCH).
    In summary, the core structure of the compound is a pyridine ring, with -COOCH at the 3rd position and -CHO at the 6th position. Its structure is based on a pyridine ring as a skeleton, and different functional groups are connected at specific positions. This structure endows the compound with specific chemical properties and reactivity, and may have important uses in the fields of organic synthesis and medicinal chemistry.
    What are the main uses of 3-Pyridinecarboxylic acid, 6-formyl-, methyl ester
    3-Pyridinecarboxylic acid, 6-formyl-, methyl ester, this substance has a wide range of uses and has its own impact in many fields.
    In the process of pharmaceutical development, it is often a key intermediate. Physicians want to make specific drugs, they need to use various compounds as bases and synthesize them through complex steps. This compound has a unique structure, which can add specific active groups to drug molecules or change the spatial configuration of compounds, thereby enhancing the ability of drugs to bind to targets and improve drug efficacy. And it can adjust the pharmacokinetic properties, making drugs easier to absorb, distribute, metabolize and excrete, achieving ideal therapeutic effects.
    In the field of materials science, it also has extraordinary performance. In order to develop new functional materials, materials scientists will use them to participate in material synthesis. Because of the functional groups it contains, it can react with other substances to build special structural materials, giving the materials unique electrical, optical or mechanical properties. For example, when preparing luminescent materials, it can adjust the material's luminescent properties and expand its applications in display, lighting and other fields.
    In the field of organic synthetic chemistry, it is an important tool for chemists. Chemists who want to build complex organic molecules often use it as a starting material. They use pyridine rings and formyl and methyl ester activities to gradually build the target molecular structure through various organic reactions, such as nucleophilic substitution, addition, condensation, etc. With it, they can synthesize organic compounds with diverse structures and functions, injecting vitality into the development of organic chemistry.
    In addition, in agricultural chemistry, it may be helpful for the development of new pesticides. It can be used as an intermediate for synthesizing pesticide active ingredients, imparting high efficiency, low toxicity, environmental protection and other characteristics to pesticides, contributing to the sustainable development of agriculture.
    What are the synthesis methods of 3-Pyridinecarboxylic acid, 6-formyl-, methyl ester
    The synthesis method of 3-pyridine carboxylic acid, 6-formyl-, methyl ester, is described in detail below.
    To obtain this compound, one method can be initiated by the corresponding pyridine derivative. First take the appropriate pyridine raw material and introduce the formyl group under specific reaction conditions. This step can be used such as the Vilsmeier-Haack reaction. In this reaction, the 6-position of the pyridine ring can be successfully attached to the formyl group with a suitable combination of reagents, such as phosphorus oxychloride and N, N-dimethylformamide, under the control of suitable temperature and time.
    Subsequently, the methylation operation is carried out for the carboxyl group of the 3-position of the pyridine ring. The common method is to use methanol as a solvent, add an appropriate amount of concentrated sulfuric acid or other acidic catalysts, and heat and reflux. Under these conditions, the carboxyl group undergoes an esterification reaction with methanol to form the target product 3-pyridinecarboxylic acid, 6-formyl-, methyl ester.
    Another way can be achieved by starting from the pyridine precursor containing suitable substituents through a multi-step reaction. For example, the pyridine ring is specially modified first, so that the 3-position band can be converted into a carboxyl group, and the 6-position band can be converted into a formyl group. After that, the functional group conversion reaction is carried out in sequence, first converting the 6-position group to a formyl group, and then converting the 3-position group to a carboxyl group and further methylation. < Br >
    During the reaction process, attention should be paid to the precise control of the reaction conditions at each step, such as temperature, reaction time, and the proportion of reactants. And after each step of the reaction, appropriate separation and purification operations should be carried out to ensure the purity of the product, which is conducive to subsequent reactions. Only in this way can the target 3-picolinecarboxylic acid, 6-formyl-, methyl ester be obtained.
    What are the physical properties of 3-Pyridinecarboxylic acid, 6-formyl-, methyl ester
    3-Pyridinecarboxylic acid, 6-formyl-, methyl ester, this is an organic compound. Its physical properties are crucial, and it is related to many chemical processes and practical applications.
    Looking at its appearance, under normal temperature and pressure, it often appears as a colorless to light yellow liquid, or a white to light yellow solid. This morphology varies depending on specific environmental conditions. Its color and morphology can help chemists preliminarily determine its purity and characteristics.
    When it comes to melting point, the melting point of this compound is within a specific range, and the exact value varies slightly according to experimental conditions. The melting point is the critical temperature at which a substance changes from a solid state to a liquid state, which is of great significance for the identification and purification of this compound. Knowing the melting point allows for precise temperature control during separation and purification to ensure the purity and quality of the substance.
    The boiling point is also one of the important physical properties. Under standard atmospheric pressure, its boiling point is in a certain range, and the determination of the boiling point helps to understand the volatility and stability of the substance. By controlling the temperature and pressure, the difference in boiling point can be used to effectively separate the compound from the mixture.
    In terms of solubility, this compound exhibits good solubility in specific organic solvents such as ethanol and dichloromethane, while its solubility in water is relatively limited. This property determines its solvent selection in chemical reactions and experimental operations. If the reaction needs to be carried out in a homogeneous system, selecting a suitable solvent to ensure that the compound is fully dissolved is essential for the smooth development of the reaction and the formation of the product.
    Density is also one of the characteristics of its physical properties. Its density value is a specific value. This parameter is related to the measurement of materials and the ratio of the reaction system in chemical production and experimental operations. Precise control of the density can effectively avoid abnormal reactions caused by deviations in the amount of materials.
    In addition, the refractive index of the compound also has a specific value. As a material characteristic constant, refractive index can be used for purity detection and qualitative analysis. Compounds of different purity have different refractive indices, so that their purity status can be quickly evaluated.
    The various physical properties of this compound are interrelated and influenced, and are indispensable basic data in many fields such as chemical research, chemical production, and drug development. Chemists can carry out related work more effectively by relying on their in-depth understanding and accurate grasp of these properties.
    3-Pyridinecarboxylic acid, 6-formyl-, methyl ester market prospects
    3-Pyridine carboxylic acid, 6-formyl -, methyl ester, this substance has market prospects, just as "Tiangong Kaiwu" said, and needs to be understood from many parties.
    It has great potential in the field of chemical synthesis. Because it contains the structure of pyridine and ester groups, it can be used as a key intermediate, and it has great potential in the creation of drugs and pesticides. Nowadays, there is a growing demand for novel structural compounds in pharmaceutical research and development. Its unique structure may open up new paths for new drug research and development, just like the cornerstone of drug synthesis, laying the foundation for innovation.
    In the field of materials science, it should not be underestimated. With its special chemical properties, it may be used to prepare materials with special properties, such as functional polymer materials. This is like a rare material in the hands of a skilled craftsman. After being carved, it can be turned into an extraordinary thing, adding to the material innovation.
    However, the road to its market is not smooth. The complexity of the production process and the control of the cost are all challenges. Just like walking on a rugged road, you need to break through the thorns and cut the thorns. And the market competition is fierce, with similar or alternative products. If you want to make a name for yourself, you need to work hard on technological innovation and cost optimization.
    Although there are challenges, there are also abundant opportunities. With the progress of science and technology, the demand for it in emerging fields may grow. As long as you grasp it well, optimize production, improve quality, and expand applications, you will be able to find a place in the market. If a pearl is dusty, it will bloom when wiped.