2,6-bis((S)-4-isopropyl-4,5-dihydrooxazol-2-yl)pyridine

2%2C6-bis%28%28S%29-4-isopropyl-4%2C5-dihydrooxazol-2-yl%29pyridine, this is an organic compound. Its main application field is quite wide.
In the field of organic synthesis, this compound often acts as a ligand. Due to its unique structure, it can form stable complexes with metal ions, and then play a key role in catalytic reactions. For example, in some transition metal catalyzed reactions, such as carbon-carbon bond formation reactions, carbon-heteroatomic bond formation reactions, etc., as a ligand, it can significantly improve the activity and selectivity of the catalyst. With precise regulation of reaction conditions, the reaction can be carried out efficiently to obtain the target product.
In the field of materials science, this compound also has applications. With its complex properties with metal ions, it can be used to prepare materials with specific properties. For example, the preparation of functional materials with optical and electrical properties provides the possibility for the development of new materials.
In pharmaceutical chemistry, it may be used as a lead compound. Because of its unique structure, or can interact with specific targets in organisms, it is expected to develop new drugs and contribute to human health.
In short, 2%2C6-bis%28%28S%29-4-isopropyl-4%2C5-dihydrooxazol-2-yl%29pyridine has shown important application value in many fields such as organic synthesis, materials science and pharmaceutical chemistry. With the continuous deepening of research, its potential application prospects may be broader.

2% 2C6 - bis% 28% 28S% 29 - 4 - isopropyl - 4% 2C5 - dihydrooxazol - 2 - yl% 29pyridine, this is an organic compound, and its synthesis method is particularly important. The summary of its synthesis method will be described below.
One method is to use pyridine as the starting material. First, a specific substitution reaction is carried out on pyridine, and a suitable functional group is introduced at the 2nd and 6th positions of pyridine to construct the chiral oxazoline structure. In this process, appropriate reaction conditions and reagents need to be selected to ensure that the reaction occurs precisely at the check point.
When chiral oxazoline structures are constructed, compounds with chiral origin are often used as the starting point. For example, starting from a specific chiral amino acid, it is converted into 4-isopropyl-4,5-dihydrooxazol-2-yl structural units through a series of reactions. Amino acids need to undergo esterification, cyclization and other reaction steps, and each step requires fine regulation of the reaction conditions to ensure the maintenance of the chiral central configuration and the formation of the target structure.
Then, the constructed chiral oxazoline structural units are combined with the substituted pyridine intermediates. This binding reaction requires a suitable catalyst and reaction environment to promote the efficient connection of the two to produce 2% 2C6 - bis% 28% 28S% 29 - 4 - isopropyl - 4% 2C5 - dihydrooxazol - 2 - yl% 29pyridine. In this process, the reaction temperature, time, and the proportion of reactants must be precisely controlled to improve the yield and purity of the product.
In addition, the optimization of the synthesis route is also key. The efficiency and selectivity of the reaction can be improved by adjusting the reaction sequence, changing reagents or catalysts. At the same time, the monitoring of the reaction process is also indispensable. The reaction process is monitored in real time by means such as thin layer chromatography and nuclear magnetic resonance to ensure that the reaction proceeds according to the expected path, so as to successfully synthesize the target compound 2% 2C6 - bis% 28% 28S% 29 - 4 - isopropyl - 4% 2C5 - dihydrooxazol - 2 - yl% 29pyridine.

2% 2C6 - bis% 28% 28S% 29 - 4 - isopropyl - 4% 2C5 - dihydrooxazol - 2 - yl% 29pyridine, this is an organic compound. Its physicochemical properties are quite important and are related to applications in many fields.
Looking at its physical properties, it may be a solid under normal conditions. Due to the orderly arrangement of atoms in the molecular structure, a stable lattice is formed, resulting in a certain melting point. However, the exact melting point needs to be accurately determined by experiments, because different purity and crystallization conditions will affect it.
Its solubility is also a key physical property. This compound contains polar groups, such as pyridine ring and oxazoline ring, so it may have a certain solubility in polar solvents, such as alcohols and ketone solvents. However, its molecule also contains non-polar parts such as isopropyl, which makes it soluble in non-polar solvents or limited.
As for the chemical properties, the pyridine ring has aromatic properties, and the electron cloud distribution is unique, which is prone to electrophilic substitution reactions. The nitrogen and oxygen atoms of the oxazoline ring have lone pairs of electrons, which can be used as coordination atoms to form complexes with metal ions. This property may be useful in the field of catalysis. The existence of chiral centers in the molecule makes it play an important role in asymmetric synthesis, which can induce the selective generation of specific configuration products in the reaction.
In conclusion, 2% 2C6 - bis% 28% 28S% 29 - 4 - isopropyl - 4% 2C5 - dihydrooxazol - 2 - yl% 29pyridine has diverse physical and chemical properties and may have broad application prospects in organic synthesis, catalysis and other fields. It is a compound worthy of further investigation.

I don't know the price range of 2,6-bis ((S) -4-isopropyl-4,5-dihydrooxazole-2-yl) pyridine on the market. This compound is not widely known and common, and its price is susceptible to many factors.
First, the purity has a great impact. For high purity, the preparation is difficult, and the fine process and complicated process are required, and the price will be high; for low purity, the preparation is relatively simple and the price may be low.
Second, the preparation scale is related. During large-scale production, due to the scale effect, the unit cost may be reduced, and the price will also decrease; for small-scale preparation, the cost is high, and the price is difficult to reduce.
Third, the key relationship between supply and demand in the market. If the demand is strong and the supply is limited, merchants may raise prices to obtain more profits; if the demand is low and the supply is sufficient, the price may be reduced for promotional sales.
Fourth, the cost of raw materials is important. If the raw materials required for the synthesis of this compound are not easy to obtain or the price is high, the price of the finished product will be implicated and increase.
To know the exact price range, you can consult chemical product suppliers, chemical reagent sales platforms, or professional chemical trading websites to obtain more accurate price information.

2% 2C6 - bis% 28% 28S% 29 - 4 - isopropyl - 4% 2C5 - dihydrooxazol - 2 - yl% 29pyridine, this is the name of the chemical substance. Its storage conditions are very important. According to the text of "Tiangong Kaiwu", when it is as follows:
When this substance is stored, it should be placed in a cool and dry place. Avoid direct sunlight, its quality may be damaged due to light or its properties may change. And it needs to be kept away from fire and heat sources to prevent the risk of accidents. This substance may have a certain chemical activity, and under high temperature, it may react and cause it to deteriorate.
Furthermore, the storage place should be well ventilated to prevent the accumulation of harmful gases. As for the container, choose the one that is resistant to corrosion and well sealed. Glass containers, if they can ensure that the seal is leak-free, are also good choices, because the internal condition is visible and easy to observe.
When storing, you should also pay attention to placing it at a distance from other chemical substances to avoid contact with each other and cause reactions. Do not coexist in a room with oxidizing and reducing substances to avoid changes. In this way, careful storage can ensure that the substance maintains its inherent properties for a long time for subsequent use.