5 Iodo 3 Methyl Isothiazole

5-iodo-3-methyl-isothiazole, Chinese name 5-iodine-3-methylisothiazole, this is a class of organic compounds. It has a wide range of uses and has shown important value in many fields.
In the field of medicinal chemistry, such compounds are often used as key intermediates. Because of its unique chemical structure, it can participate in a variety of chemical reactions, and then construct more complex drug molecular structures. By chemically modifying and modifying it, new drugs with specific biological activities can be developed, or used for the treatment of diseases, or for the optimization of drug lead compounds, opening up new directions for pharmaceutical research and development.
In the field of materials science, 5-iodine-3-methylisothiazole can be used as a synthetic raw material for functional materials. Due to its special chemical properties, it can be rationally designed and synthesized to endow materials with unique properties, such as photoelectric properties, antibacterial properties, etc. For example, it can be introduced into polymer materials, or materials with special photoelectric response can be prepared, which can show application potential in the field of optoelectronic devices; with its antibacterial properties, it can also be used to prepare antibacterial materials for use in medical, food packaging and other scenes with strict hygiene requirements.
In addition, in organic synthetic chemistry, 5-iodine-3-methyl isothiazole can be used as an excellent reaction substrate due to its active iodine atom and isothiazole ring structure, participating in many organic reactions, such as coupling reactions, substitution reactions, etc. Chemists can use this to construct organic molecules with specific structures and functions, enrich the variety of organic compounds, and promote the development of organic synthetic chemistry.

5-Iodo-3-methyl-isothiazole is an organic compound whose physical properties are particularly important. Let me describe them in detail for you.
The morphology of this compound is mostly solid at room temperature and pressure, but it may vary depending on the specific environmental conditions. Its color is often white to light yellow powder, fine and uniform.
As for the melting point, it is known from many experimental investigations that it is about a specific temperature range. This melting point is of great significance for the identification and purity judgment of the compound. When the temperature gradually rises to the melting point, the compound slowly melts from a solid state to a liquid state. This process requires precise temperature control to observe its changes in detail.
In terms of solubility, 5-iodo-3-methyl-isothiazole has a certain solubility in common organic solvents, such as ethanol and dichloromethane. In ethanol, with moderate stirring, it can be seen that it partially dissolves to form a uniform solution. However, in water, its solubility is very small. Due to the characteristics of molecular structure, the force between water molecules and water molecules is weak, so it is difficult to dissolve.
Density is also one of the important physical properties of this compound. After precise measurement and calculation, its density value can be obtained. This value is crucial in chemical production and related research, related to the ratio of materials, the design of reaction systems, etc.
In addition, the compound has low volatility. Under normal environmental conditions, it is more difficult to volatilize into the air. This property makes it relatively stable during storage and use, which can reduce losses and dangers due to volatilization.
In summary, the physical properties of 5-iodo-3-methyl-isothiazole, such as morphology, color, melting point, solubility, density and volatility, have their own characteristics, and are of great value in chemical research, industrial production and other fields. It helps researchers and producers to deeply understand and rationally use this compound.

5-Iodo-3-methyl-isothiazole is one of the organic compounds. Its chemical properties are still stable under normal conditions. In this compound, the iodine atom is connected to the isothiazole ring and methyl group. The iodine atom has a high electronegativity, so it has a significant impact on the electron cloud distribution of the molecule, which in turn affects its chemical activity.
From the perspective of reactivity, the iodine atom has good departure properties, and can undergo nucleophilic substitution under the action of appropriate nucleophiles. The isothiazole ring has certain aromaticity due to the sulfur and nitrogen heteroatoms, which makes it able to participate in many typical aromatic reactions, such as electrophilic substitution reactions. The methyl group is the power supply, which can increase the electron cloud density on the ring and affect the selectivity of the reaction check point.
However, its stability is also restricted by external conditions. In case of high temperature, strong oxidant or specific catalyst, its structure may change. Under high temperature, the vibration of chemical bonds in the molecule intensifies, or the bond breaks and rearranges. Strong oxidants can oxidize heteroatoms such as sulfur and nitrogen in the molecule, changing the structure of the compound.
In general storage environment, if it can be stored in a cool and dry place away from light, 5-iodo-3-methyl-isothiazole can maintain a relatively stable state, and the chemical properties change little. However, when it comes to its participation in chemical reactions, it is necessary to carefully control the temperature, the proportion of reagents, and the reaction time in order to achieve the expected reaction effect and ensure that its chemical properties change in the established direction during the reaction process.

The synthesis of 5-iodine-3-methylisothiazole relies on a lot of skills in the past. First, the specific sulfur, nitrogen and halide are used as the starting materials, and they are finely prepared in a suitable solvent, assisted by a catalyst, so that the molecules interact. This reaction requires strict control of temperature and reaction time. If the temperature is too high or side reactions occur, if it is too light, the reaction will be slow and it is difficult to achieve the expected yield.
And isothiazole derivatives are used as the base, and iodine atoms are added to specific positions by halogenation reaction. The choice of halogenating agent is very important, such as the compatibility of iodine elemental substance with appropriate oxidant, which can effectively realize the iodine substitution reaction. During the reaction, the polarity and pH of the solvent all affect the reaction process and the purity of the product.
In addition, organometallic reagents are also used in this synthesis. With the special activity of metal reagents, specific groups are precisely linked to construct the structure of 5-iodine-3-methylisothiazole. However, organometallic reagents are expensive and environmentally sensitive, and the operation should be cautious. They are applied in an anhydrous and anaerobic environment to ensure their activity and reaction accuracy.
Although there are various methods for synthesis, each has advantages and disadvantages. Either expensive raw materials are required, or the reaction conditions are harsh, or the post-processing is cumbersome. Chemists often need to carefully choose the appropriate synthesis path according to the actual situation, such as the availability of raw materials, cost considerations, and product purity requirements, in order to achieve the purpose of efficient, economical, and environmentally friendly synthesis.

5-Iodine-3-methylisothiazole, this product is on the market, its price is uncertain, due to a variety of reasons.
Looking at the past, the source of materials, the situation of supply and demand, and the complexity and simplicity of the manufacturing process all have a great impact on the price. If raw materials are easy to obtain, there are many producers, and the supply exceeds the demand, the price may be stabilized. However, raw materials are scarce, difficult to harvest, coupled with complicated manufacturing, time-consuming, and expensive materials are required, or when the market demand increases sharply, the supply exceeds the demand, and the price will rise.
According to past transactions, similar products, those with high quality, are often higher than those with ordinary prices. If it contains very little impurities and the purity exceeds 95%, it will be favored by the buyer, and the price will rise. And different places have different prices. In places with prosperous trade and convenient logistics, the cost may be slightly reduced due to smooth circulation, and the price may be relatively easy; while in remote places, due to the difficulty of transportation and the increase in cost, the price may be higher.
However, after searching the records of the past, it is difficult to determine the exact price. Today's market price may hover between tens of gold and hundreds of gold per gram. If you buy in bulk, the larger the quantity, the merchant may give a discount to promote sales, and the price will drop. To know the real-time price, you need to consult a merchant specializing in chemical raw materials, or visit a platform for chemical trading, in order to obtain the exact number.