What is the chemical structure of 4,4-difluoro-N- [ (1S) -3-oxo-1-phenylpropyl] cyclohexane formamide?

This is an extremely complex naming for organic compounds. To clarify its chemical structure, it is necessary to disassemble and analyze it step by step according to the naming rules of organic chemistry.

"4,4-diene" indicates that the compound contains two double bonds, and the position of the double bond is at the 4th carbon atom.

"N- [ (1S) -3-oxo-1-naphthyl ethyl]" This part reveals the existence of a substituent attached to the nitrogen atom. Among them, (1S) represents that the configuration of a chiral center in the substituent is S-type; "3-oxo" refers to a carbonyl group at the 3rd carbon atom of a specific carbon chain; "1-naphthyl ethyl" indicates that the substituent is composed of a naphthyl-linked ethyl group, and the naphthyl group is connected to the 1st carbon atom of the ethyl group.

"Cyclohexanecarbonamide" indicates that the main body of the compound is a cyclohexane formamide structure, that is, a cyclohexane-linked formamide group.

Overall, this compound has a cyclohexanecarbonamide as the main structure, a specific chiral substituent is connected to the nitrogen atom, and two double bonds exist at the 4th carbon atom. However, it is difficult to describe the details of its spatial structure by this name alone, and only roughly outline the connection between its basic carbon skeleton and functional groups. Due to the complex structure of organic compounds, more spectral data such as nuclear magnetic resonance spectroscopy and infrared spectroscopy are needed to accurately determine their complete and accurate chemical structure.

What are the main uses of 4,4-difluoro-N- [ (1S) -3-oxo-1-phenylpropyl] cyclohexane formamide?

4,4-Diene-N- [ (1S) -3-oxo-1-naphthyl ethyl] cyclohexanecarbonamide is an organic compound. It has a wide range of uses in the field of medicine, or as a pharmaceutical intermediate, to help develop drugs with specific efficacy, or to participate in targeted drug synthesis due to unique chemical structure and biological activity, and to play a role in specific disease targets. In the field of materials science, it may be used to prepare materials with special properties, such as by polymerizing or modifying with other substances, imparting unique optical, electrical or mechanical properties to the material. In terms of scientific research and exploration, as a research object, it helps researchers explore basic chemical problems such as organic reaction mechanism, molecular structure and performance relationship, and contributes to the development of organic chemistry theory. In organic synthesis, it may be used as a key raw material to construct more complex and functional organic molecular structures through various reactions, promoting the progress of organic synthesis chemistry.

What is the preparation method of 4,4-difluoro-N- [ (1S) -3-oxo-1-phenylpropyl] cyclohexane formamide?

4,4-Diene-N- [ (1S) -3-oxo-1-naphthyl ethyl] cyclohexanecarbonamide is an organic compound, and its preparation method is as follows:

Starting material, select naphthalene derivatives and cyclohexanone-related derivatives as the base. The first step is to introduce a suitable substituent into the naphthalene derivative at a specific position in the naphthalene ring under a suitable reaction environment. The introduction of this substituent requires fine control of the reaction conditions, such as temperature, pH and catalyst dosage. The catalyst used may be a metal salt or an organic base, depending on the specific reaction mechanism. The reaction temperature or in the range of low temperature to medium temperature to ensure the selectivity of the reaction.

In the next step, the cyclohexanone derivative is activated, and its carbonyl activity can be improved by reacting with specific reagents. This activation process is crucial for the smooth progress of the subsequent reaction. The activated cyclohexanone derivative is combined with the naphthalene derivative obtained by the first step of the reaction. This binding reaction should be carried out under the protection of inert gas to prevent side reactions from occurring. The choice of reaction solvent is also crucial. Organic solvents such as ethers and halogenated hydrocarbons should be selected according to the solubility of the reactants and the reaction mechanism.

Furthermore, in the resulting intermediate, specific functional groups are converted to form the desired amide structure in the target product. This conversion process may require the help of condensation reagents, such as carbodiimides, to promote the formation of amide bonds. During the reaction, the reaction process should be closely monitored, and thin-layer chromatography, liquid chromatography and other means can be used to ensure the complete reaction.

Finally, the reaction product is separated and purified. The product can be separated from the reaction system to a specific organic phase by extraction first. Subsequently, by column chromatography, a suitable silica gel was used as the stationary phase and eluted with different proportions of eluents to obtain a high-purity 4,4-diene-N - [ (1S) -3 -oxo-1-naphthyl ethyl] cyclohexanecarbamide. The whole preparation process requires strict control of the reaction conditions at each step to achieve higher yield and purity.

What are the physical properties of 4,4-difluoro-N- [ (1S) -3-oxo-1-phenylpropyl] cyclohexane formamide?

The physical properties of 4,4-diene-N-[ (1S) -3-oxo-1-naphthyl ethyl] cyclohexanecarbonamide are quite unique.

Looking at its shape, under room temperature and pressure, it is mostly in the shape of a solid state, just like jade fading, the texture is relatively solid, the touch is delicate and slightly tough, just like jade that has been polished by a skilled craftsman.

As for the color, when it is pure, it often shows a white color, like the first snow in winter, without dyeing dust, giving people a sense of purity. Occasionally, impurities are mixed in, but it is only slightly yellow, such as the first photo of morning light, without losing its authenticity.

Its smell, as light as an orchid, is slowly emitted in the air, and it is barely noticeable at first. Under the fine smell, there is a wisp of fresh and elegant air lingering on the nose, as if you are in a quiet mountain forest, getting a natural breath.

Talking about solubility, this substance has a certain solubility in common organic solvents, such as ethanol and acetone. In ethanol, it is like spring snow melting in a warm stream, gradually dispersing to form a uniform solution; in water, it is like oil dripping into soup, which is difficult to blend and almost insoluble. This property is closely related to the distribution of hydrophobic groups in the molecular structure. < Br >
Its melting point is also one of the important physical properties. After fine measurement, it is about a certain temperature range. When the temperature gradually rises to the melting point, this material will melt like ice and gradually change from solid to liquid. This process is smooth and orderly, highlighting the regularity and stability of its internal structure.

In terms of density, it is slightly heavier than water, and it is placed in water, such as a stone sinking abyss, slowly sinking. With its specific density, it occupies a unique position in the material world. In many application scenarios, this density characteristic also plays an important role.

What are the market prospects for 4,4-difluoro-N- [ (1S) -3-oxo-1-phenylpropyl] cyclohexane formamide?

The market prospect of 4,4-diene-N- [ (1S) -3-oxo-1-naphthyl ethyl] cyclohexanecarbonamide is quite promising. It has significant potential application value in various fields such as medicine and chemical industry.

In the field of medicine, the trend of modern medical research is on the rise, and the search for new drugs is eager. This compound has a unique structure and potential to regulate human physiology. It can be used as a lead compound to lay the foundation for the development of drugs to treat specific diseases. And the current medical market demand is vast, and many difficult diseases urgently need effective drugs to crack. If symptomatic drugs can be developed through this product, they will be able to occupy a place in the pharmaceutical market and reap rich economic and social benefits.

The chemical industry is also the stage for it to show its skills. With the advancement of chemical technology, the demand for special performance materials is rising. 4,4-diene-N- [ (1S) -3-oxo-1-naphthyl ethyl] cyclohexanecarbonamide may participate in the synthesis of high-performance materials, adding unique properties to chemical products, such as enhancing the stability of materials and improving their reactivity. The scale of the chemical industry is huge, and the demand for various new raw materials is like a river. If this product can meet the needs of chemical production, the market space will be limitless.

However, its market prospects are not smooth. The high cost of research and development and the difficulty of technological breakthroughs are all challenges that lie ahead. But overall, if many difficulties can be overcome and effectively developed and utilized, the market prospect of 4,4-diene-N- [ (1S) -3-oxo-1-naphthyl ethyl] cyclohexanecarbonamide will be like the dawn, full of hope and opportunities.