(S)-2-Benzothiazolyl (Z)-2-(2-Aminothiazole-4-Yl)-2-Methoxycarbonylmethoxyiminothioacetate

The compound is called (2S) -2-benzothiazolyl (Z) -2- (2-aminothiazole-4-yl) -2-methoxycarbonyl methoxyiminothioacetate. Its chemical structure is described in the following ancient sayings:
This compound has a delicate and complex structure. First, there is a part of the (2S) configuration, which is a sign of a specific spatial orientation, such as the specific shape of the utensil. It contains 2-benzothiazolyl, which is a ring-like structure composed of a benzene ring and a thiazole ring. The benzene ring has a six-membered shape and is arranged in a stable conjugated system with carbon-carbon double bonds. The thiazole ring is a five-membered heterocyclic ring containing sulfur and nitrogen. Sulfur and nitrogen atoms occupy a specific position in the ring, and the two are conjugated, just like a double-bi connection, and the costructure is unique. The
(Z) configuration indicates the spatial arrangement of the groups at the double bond, showing a specific cis-layout. Furthermore, there are 2 - (2 - aminothiazole - 4 - group) parts, of which 2 - aminothiazole is also a five-membered heterocyclic ring, the nitrogen atom and the sulfur atom coexist in the ring, and the 2-position is connected with an amino group. This amino group has the property of a power supplier, which affects the reactivity of the compound, and the 4-position is connected to other places, such as a hub-like connection structure.
There is still a 2-methoxycarbonyl methoxyiminothioacetate part, methoxycarbonyl is a methoxy group connected to a carbonyl group, with electron-absorbing effect, methoxy is connected to the carbon atom of the carbonyl group with an oxygen atom, and the carbon of the carbonyl group is connected elsewhere; methoxycarbonyl methoxy is connected to a methylene group with a methoxy carbonyl group, and then connected to the oxygen atom to form an oxygen group; imino is connected by a double bond between nitrogen and another atom, and the thioacetate part replaces the carbonyl oxygen atom in the acetate with a sulfur atom. The groups in this part are interrelated to build the structure of this complex compound. Each part complements each other and gives the compound its unique chemical properties and reactivity.

(This compound) (2S) -2 -benzothiazolyl (Z) -2 - (2 -aminothiazole-4-yl) -2 -methoxycarbonyl methoxyiminothioacetate, its main use is particularly critical.
In the field of pharmaceutical and chemical industry, it is often an important pharmaceutical intermediate. The specific groups such as benzothiazolyl and aminothiazolyl contained in the Gain structure endow it with unique chemical activity and reaction characteristics. Through the technique of organic synthesis, it can cleverly react with various reagents to derive compounds with specific pharmacological activities, such as the preparation of certain antibacterial and antiviral drugs. This intermediate may be indispensable to assist in the synthesis of the molecular structure of the target drug, improve the efficacy of the drug, and optimize the pharmacological properties.
In the level of scientific research, this compound also plays an important role. Scientists use it as a starting material to explore new chemical reaction pathways and synthesis strategies, hoping to expand the boundaries of organic chemistry. Due to its complex and special structure, studying the reaction mechanism involved in it helps to deepen the understanding of the nature of organic reactions, lay the foundation for the creation of new synthesis methods, and provide ideas for the development of new functional materials. < Br >
In the field of fine chemical manufacturing, it can be used to prepare fine chemicals with special properties. Due to its special structure, it can give unique properties to products. For example, in the production of some special coatings and additives, adding ingredients derived from this compound can improve the stability, adhesion and other properties of products, and meet the special needs of different industries for fine chemicals.

The synthesis method of (2S) -2 -benzothiazolyl (Z) -2 - (2 -aminothiazole-4-yl) -2 -methoxycarbonyl methoxyiminothioacetate is a key issue in the field of organic synthesis. There are many common methods for preparing this substance.
First, it can be obtained by condensation reaction between thiazole compounds containing specific substituents and benzothiazole derivatives. First, the 2-aminothiazole-4-yl related precursor is reacted with a suitable halogen under basic conditions, the methoxycarbonyl methoxyimino moiety is introduced, and then it is condensed with the benzothiazole derivative in a suitable catalyst and reaction environment. In this process, factors such as reaction temperature, pH, and molar ratio of the reactants need to be precisely controlled. Too high or too low temperature may affect the reaction rate and product selectivity; unsuitable pH, or increase side reactions, and reduce product purity.
Second, the strategy of gradually building molecular structure can also be used. First, the fragments containing 2-aminothiazole-4-yl and benzothiazolyl are synthesized separately, and then the two are connected by a ligation reaction, and the structural unit of methoxycarbonyl methoxyiminothioacetate is introduced. This process requires careful design of each step of the reaction to ensure the purity and reactivity of each intermediate, so as to achieve high yield and high purity of the final product. For example, when constructing the fragment, selecting appropriate protecting groups and deprotection conditions is extremely important to prevent unnecessary reactions and improve the quality of the product.
Furthermore, the reaction path catalyzed by transition metals can also be used. Transition metals are used as catalysts to promote the coupling reaction of related substrates, thereby constructing the structure of the target molecule. Such methods can often show the advantages of high efficiency and good selectivity, but the selection of catalysts and the optimization of reaction conditions are very demanding. The activity, stability and matching of the catalyst with the substrate need to be considered, and the reaction solvent, ligand and other factors need to be deeply studied to achieve the ideal synthesis effect.

(S) - 2 -benzothiazolyl (Z) - 2 - (2 -aminothiazole-4-yl) - 2 -methoxycarbonyl methoxyiminothioacetate, the physical properties of this substance are very important, related to its application in many fields.
Its properties may be solid, which is based on the common physical morphology of such compounds containing heterocycles and specific functional groups. In terms of solubility, in view of the fact that it contains polar methoxycarbonyl, amino and other functional groups, it may have a certain solubility in polar solvents such as water and alcohols, but due to the existence of hydrophobic groups such as benzothiazolyl, the solubility in non-polar solvents such as alkanes may be limited.
Determination of the melting point can provide a key basis for the identification of this compound. Generally speaking, the melting point of complex organic compounds is determined by factors such as intermolecular forces and crystal structure. This substance contains multiple groups that can form hydrogen bonds, and the intermolecular force is strong, and the melting point may be relatively high.
In terms of boiling point, due to the complex molecular structure and large relative molecular mass, the intermolecular forces are complicated, resulting in its high boiling point. During the heating process, a higher temperature is required to overcome the intermolecular force and transform it from a liquid state to a gaseous state.
Density is also one of the important physical properties. According to its molecular structure and the relative atomic mass of the constituent elements, it can be inferred that its density is relatively large. This is because the atoms in the molecule are closely arranged, and the elements with relatively large atomic mass such as sulfur and nitrogen are contained.
In addition, the refractive index can reflect its optical properties and is closely related to the molecular structure and electron cloud distribution. Due to the heterocyclic structure of the conjugated system, the electron cloud has high fluidity, and the refractive index may exhibit specific values, which can be used for its purity identification and analysis.

Today there are (2S) -2-benzothiazolyl (Z) -2- (2-aminothiazole-4-yl) -2-methoxycarbonyl methoxyiminothioacetate, and its market prospects are many and important. This compound may have significant potential in the field of medicine. Due to its unique chemical structure, it may become a key raw material for the development of new antibacterial and antiviral drugs.
Looking at today's pharmaceutical market, there is a hunger for high-efficiency and low-toxicity anti-infective drugs. The special group combination of this compound may be able to precisely act on specific targets of pathogens to achieve good therapeutic effects. Taking the history of drug research and development as a mirror, many compounds with novel structures have been deeply researched and developed, and have eventually become commonly used drugs in clinical practice. If this compound follows this path and is carefully studied, it may fill the gap of specific drugs in the market, thus gaining a place in the pharmaceutical market.
In the chemical industry, it may be used as an intermediate in organic synthesis. With its structural characteristics, it can participate in a variety of chemical reactions and help synthesize complex organic compounds. The chemical industry is constantly pursuing new synthesis routes and raw materials to reduce costs and increase efficiency and improve product quality. If this compound can show excellent reactivity and selectivity, it will be favored by chemical companies and find development opportunities in the organic synthesis market.
However, its market prospects are not smooth. In the process of research and development, it is necessary to overcome technical difficulties, such as synthesis process optimization, to improve yield and reduce costs. And safety and Environmental Impact Assessment are also indispensable, and only by meeting relevant regulatory standards can we enter the market smoothly. In short, the market prospect of (2S) -2-benzothiazolyl (Z) 2- (2-aminothiazole-4-yl) -2-methoxycarbonylmethoxyiminothioacetate is promising, but it also needs to pass many tests. If properly dealt with, it is expected to shine in the pharmaceutical and chemical markets.