Diethyl(phenylacetyl)malonate, also recognized as CAS ID 20320-59-6, is a synthesized compound. It is a white crystalline solid with a pungent smell. This chemical reagent is widely used in various industrial applications for its ability to serve as a precursor.
The structure of diethyl(phenylacetyl)malonate consists of a phenylacetyl moiety attached to a diethyl malonate. This molecular design allows it to engage in chemical synthesis.
Chemical Synthesis of Diethyl(phenylacetyl)malonate
The preparation of diethyl(phenylacetyl)malonate is a fundamental reaction in organic chemistry. This compound serves as a valuable building block for the preparation of various complex molecules, particularly in the field of pharmaceuticals and agrochemicals. The synthesis typically involves a two-step process. In the primary step, phenylacetic acid reacts with ethanol in the cas 69673-92-3 2-Chloro-1-(4-methylphenyl)-(9ci)-1-propanone presence of an acidic catalyst, such as sulfuric acid. This reaction yields phenyl acetate ester, which is then treated to malonic ester. The final product, diethyl(phenylacetyl)malonate, is obtained after a series of chemical transformations involving reaction.
- The reaction conditions play a crucial role in determining the yield and purity of the final product.
- Various purification techniques, such as recrystallization or column chromatography, can be employed to isolate the desired compound.
- Safety precautions must be taken during the synthesis process, as some reagents involved may be hazardous.
Analysis of Diethyl(phenylacetyl)malonate
Diethyl(phenylacetyl)malonate is a substance with the chemical formula C15H18O4. This derivative can be produced through several methods, often involving the transformation of phenylacetic acid with diethyl malonate. It exhibits unique physical characteristics, such as a color that ranges from colorless to light yellow and a temperature of around 270°C.
- Significant structural features include the presence of two ethyl ester groups and a phenylacetyl group.
- Diethyl(phenylacetyl)malonate has found purposes in various synthetic processes.
- Further research continues to explore its potential in the creation of innovative compounds.
Physicochemical Properties of Diethyl(phenylacetyl)malonate
Diethyl(phenylacetyl)malonate exhibits a distinct set of physicochemical properties that influence its reactivity and applications. Its structural formula, C16H18O4, reflects the presence of multiple ethyl ester groups and one phenylacetyl moiety. The substance's molar mass is roughly 274.31 g/mol, indicating its substantial weight. At room temperature, diethyl(phenylacetyl)malonate preserves as a viscous state with a distinctive odor. Its dissolvability in common organic solvents is to be limited. The compound's solidus point shifts depending on purity and factors. Its boiling point, on the other hand, lies within a determined range. The presence of functional groups within its structure impacts its intramolecular interactions.
Applications of Diethyl(phenylacetyl)malonate in Organic Chemistry
Diethyl(phenylacetyl)malonate acts a crucial role in organic reactions due to its versatile structure. This compound can be readily transformed through various chemical transformations to yield a wide array of valuable substances. For example, diethyl(phenylacetyl)malonate can be utilized in the synthesis of pharmaceuticals, herbicides, and various chemical products.
One notable application is its role in the creation of alcohols with an ester group, which are frequently employed as precursors in the construction of complex structures.
Furthermore, diethyl(phenylacetyl)malonate can be employed in the synthesis of heterocyclic compounds, which are essential components of many natural products and pharmaceuticals.
Diethyl(phenylacetyl)malonate (C15H18O5): A Versatile Building Block
Diethyl(phenylacetyl)malonate (C15H18O5), a compound containing a distinctive structure, has emerged as a powerful building block in organic synthesis. Its remarkable reactivity profile allows for the fabrication of diverse molecular architectures across diverse chemical domains. This adaptable molecule serves as a valuable precursor for the development of new pharmaceuticals, agrochemicals, and materials.