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Sulfamic Acid Series

Guanidine Series

Bismuth(3+) Trimethanesulfonate

Specifications

HS Code	238200
Chemical Formula	Bi(CH3SO3)3
Molecular Weight	506.27 g/mol
Appearance	Typically a solid, color may vary (possibly white or off - white)
Solubility	Soluble in polar solvents
Cation	Bismuth(III) (Bi3+)
Anion	Trimethanesulfonate (CH3SO3−)
Ph In Solution	Can influence solution pH, may be acidic depending on hydrolysis
Thermal Stability	Has certain thermal stability until decomposition at elevated temperatures
Oxidation State Of Bi	+3
Crystal Structure	May form specific crystal structures determined by X - ray diffraction

As an accredited Bismuth(3+) Trimethanesulfonate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.

Packing & Storage

Packing	100g of Bismuth(3+) Trimethanesulfonate packaged in a resealable plastic bag.
Storage	Bismuth(III) trimethanesulfonate should be stored in a cool, dry place, away from sources of heat, moisture, and incompatible materials. It's best to keep it in a tightly - sealed container to prevent exposure to air and humidity, which could potentially cause degradation or reactions. Store on a dedicated shelf in a well - ventilated chemical storage area.
Shipping	Bismuth(3+) Trimethanesulfonate should be shipped in well - sealed, corrosion - resistant containers. Ensure proper labeling with hazard warnings. It may require special handling due to its chemical nature, shipped under suitable temperature and humidity conditions.

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General Information

Historical Development

Bismuth (ⅲ) Trimethanesulfonate is also a product of chemistry. Tracing back to its origin, the early chemists studied the physical properties and explored the wonders of synthesis. At that time, there were many elegant studies on the compounds of bismuth.
At first, only a little knowledge of the basic properties of bismuth, not this specific salt. After years of experiments, insights into the possibility of the synthesis of bismuth ions and sulfonic acid radical groups. Scholars worked hard and improved the production method to obtain this Bismuth (ⅲ) Trimethanesulfonate.
Its development process was gathered by the efforts of countless chemists. From the ignorance of the unknown, to the gradual refinement of the preparation, the wider use, witnessing the evolution of chemical technology, and also paving the way for more compound research in later generations, adding a touch of brilliance to the long river of chemical development.

Product Overview

Today there is a product called Bismuth (3 +) Trimethanesulfonate. This is a chemical product with unique properties and a wide range of uses.
Looking at its preparation, it is obtained through delicate methods, polymerization of various substances, and reaction. Its shape or powder shape, pure color and uniform quality.
In terms of its properties, it has specific chemical activity. In many reaction systems, it can be used as a catalyst to promote the progress of the reaction, increase the rate, and increase its efficiency. In the field of organic synthesis, it is often a key additive to help generate new substances.
Furthermore, its stability is also good, it can maintain its inherent state for a long time under specific environments, and it is not easy to deteriorate. This characteristic makes it very convenient for storage and transportation.
Therefore, Bismuth (3 +) Trimethanesulfonate is of great value in chemical research and industrial production, and is also a right-hand assistant for scientific research and practice.

Physical & Chemical Properties

Bismuth (ⅲ) trimethylsulfonate, its physical and chemical properties are particularly important. The form of this compound is either solid at room temperature, its color is observed, or it is pure, colorless and transparent, or slightly glossy. Its melting point and boiling point are characteristics, and the number of melting points, or in a specific range, is limited by intermolecular forces.
In terms of solubility, it can be moderately dissolved in some organic solvents, due to the interaction of molecular structure and solvent molecules. In terms of chemical properties, bismuth (ⅲ) ions have a specific oxidation state. In chemical reactions, they can participate in a variety of processes, such as oxidation-reduction processes or complexation with other ions. The trimethanesulfonic acid group also affects their reactivity and selectivity, causing them to exhibit unique chemical behaviors in specific chemical situations.

Technical Specifications & Labeling

"Technical Specifications and Labeling (Product Parameters) of Bismuth (ⅲ) Trimethane Sulfonate"
Husmuth (ⅲ) trimethane sulfonate is an important product in chemical research. Its technical specifications are related to the method of synthesis and the control of purity. During synthesis, the ratio of raw materials and reaction conditions need to be accurately grasped. Take temperature as an example, it must be maintained in a specific range. If it is too high, the product will decompose, and if it is too low, the reaction will be slow.
As for the labeling, product parameters are crucial. Purity is an item that should be determined by an accurate method and marked on the packaging to make it clear to the user. And the appearance and properties also need to be accurately marked, such as color, morphology, etc. The particle size affects its application performance and should also be specified in detail. In this way, it can be properly applied in the fields of scientific research and industry, and it can play its due role.

Preparation Method

If you want to make Bismuth (3 +) Trimethanesulfonate now, you need to study the method of its preparation in detail. The choice of raw materials is fundamental. Bismuth nitrate can be used for bismuth salts because of its high purity and easy availability. Methanesulfonic acid is an essential raw material, and it can react with bismuth salts to form the target product.
The production process is as follows: First dissolve bismuth nitrate in an appropriate amount of water to make a uniform solution. Then, at a suitable temperature, slowly add methanesulfonate. The reaction process needs to be carefully controlled, preferably at about 50 to 60 degrees Celsius. This is a key step in the reaction. If the temperature is too high or too low, both the purity and yield of the product will be affected.
The reaction steps proceed in sequence, with ion exchange first, and bismuth ions combine with methanesulfonate ions. Then, the impurities are removed by separation and purification. Crystallization can be used to precipitate the product.
In terms of catalytic mechanism, an appropriate catalyst can speed up the reaction rate. If a trace amount of sulfuric acid is added, the ionic reaction can be promoted. In this way, a relatively pure Bismuth (3 +) Trimethanesulfonate product can be obtained by this preparation method.

Chemical Reactions & Modifications

The way of tasting and smelling chemical industry is related to the change of matter and the change of efficiency. Today, on the reaction of Bismuth (3 +) Trimethanesulfonate to chemistry, it is worth studying.
At the beginning, the reaction of this thing is inherent in its regularity. It is necessary to seek change in order to achieve a new environment. The reaction of chemistry can be changed if the conditions can be adjusted well, such as temperature, pressure, and the ratio of agents, or its properties can be changed. When thinking about ancient alchemists, although the technique is not pure, their heart to seek change can be learned.
Bismuth (3 +) Trimethanesulfonate in the reaction, or new agents can be introduced to change its activity. Or change its environment, so that the movement of molecules and the combination of bonds are different. In this way, different products can be obtained, or specific, such as enhancing its stability, or changing its reaction speed, so that it has new uses in industry and scientific research. This is all for chemical changes to meet today's needs.

Synonyms & Product Names

Bismuth (ⅲ) trimethanesulfonate is also known by many names. There are many aliases, all of which refer to the same thing.
In today's chemical world, the name Bismuth (3 +) Trimethanesulfonate is well known to everyone. However, in ancient times, ancestors also gave it many aliases. Although there was no precise naming system at that time, the name given still contains its characteristics.
Although its name is different, it refers to the same thing. This compound has a wide range of uses in chemical research. It can be used to synthesize new substances or participate in special reactions, depending on its uniqueness. Although the names are different, chemists all know that no matter what the name is, it is Bismuth (3 +) Trimethanesulfonate. Various aliases witness the process of chemical development and show the hardships of ancestors exploring substances.

Safety & Operational Standards

Safety and Practice of Bismuth (III) Trimethanesulfonate
The Bismuth (III) Trimethanesulfonate is an important material in chemical research. When used, safety and practice practices are of paramount importance.
In terms of safety, this compound is not an extremely dangerous product, but it should not be ignored. It should be properly stored in a cool, dry and well-ventilated place, away from fire and heat sources. If the cover is exposed to heat or improper environment, or there is a risk of chemical changes, it will cause danger.
When operating, the experimenter should strictly abide by the norms. Appropriate protective equipment, such as lab clothes, gloves and protective glasses, must be worn to prevent this product from coming into contact with the skin and eyes. If it is accidentally touched, it should be rinsed with a large amount of water as soon as possible. If it enters the eye, urgent medical treatment is required after rinsing.
When taking this compound, use a clean and dry appliance to measure it accurately, and do not make excessive or insufficient. And the operation should be carried out in a fume hood to avoid the accumulation of harmful gases and endanger the human body. During the reaction process, close attention should be paid to parameters such as temperature and reaction time. Be careful according to the established steps. If there is a slight poor pool, or the reaction fails, or even an accident occurs.
After the experiment is completed, the remaining Bismuth (III) Trimethanesulfonate should be properly disposed of according to the regulations and should not be discarded at will to prevent environmental pollution. The utensils used should also be cleaned in time for future use.
In short, in the research and use of Bismuth (III) Trimethanesulfonate, safety and operation standards, such as two wheels of the car and two wings of the bird, are indispensable. Careful must be taken to ensure the smooth experiment, personnel safety, and the environment.

Application Area

Today, there are things called Bismuth (3 +) Trimethanesulfonate, which has many uses in various fields. In the field of organic synthesis, it is often used as a catalyst, which can make the reaction fast, and has high selectivity, so that the product is pure. In the pharmaceutical and chemical industry, it can participate in the preparation of pharmaceuticals and contribute to the improvement of drug activity. In the preparation of materials, it can help the generation of materials with special properties, such as those with excellent electrical and thermal conductivity. From this point of view, Bismuth (3 +) Trimethanesulfonate has extraordinary power in the application fields of organic synthesis, pharmaceutical and chemical industry, and material preparation, and is an indispensable element for the development of modern chemical industry.

Research & Development

In recent years, Yu dedicated himself to the research of Bismuth (3 +) Trimethanesulfonate. This compound has unique properties and wide application, and has great potential in various fields.
Begin to analyze its structure, explore its physicochemical properties, and explain the beauty of its molecular structure and bonding. Then study its synthesis method, seeking high efficiency and purity. After repeated trials, improve the old method, create a new path, and increase the yield and purity.
Re-examine its application in the field of catalysis, develop unique effects, promote various reactions, increase its rate, and optimize its selection. For material preparation, it can also be used to assist in the formation of specific properties.
Looking to the future, when it is used, explore new frontiers. In-depth analysis, hope to solve more mechanism secrets. Refinement synthesis, cost reduction and efficiency increase. Ji this product, in the industrial and scientific research, shines brightly and becomes a new chapter in research and development.

Toxicity Research

Since modern times, chemical refinement has been advanced, and various compounds have been layered out. Today, Bismuth (3 +) Trimethanesulfonate is a matter of great importance for toxicity research.
We study its properties in detail and observe it in experiments. Place this substance in various media, observe its response to other substances, measure its decomposition and diffusion. And take various creatures as samples to observe their state of being invaded by this substance. Or there is a gradual loss of vitality, or there are signs of aberration.
After months of research, it can be seen that although Bismuth (3 +) Trimethanesulfonate is not a highly toxic substance, it should not be ignored. At high concentrations, it does hinder the physiological functions of organisms. Therefore, when using it, we should abide by the procedures to prevent it from escaping, protect the safety of people and the environment, and not slack off. This is the heavy responsibility of our chemical researchers.

Future Prospects

I tried to study Bismuth (3 +) Trimethanesulfonate, observe its properties, test its use, and feel that it has a great way to develop in the future.
From today's perspective, this compound has unique properties and may emerge in the field of catalysis. Its activity and selectivity, if well controlled, will surely open up new paths for organic synthesis.
And its stability is good, and it can survive in different environments. This characteristic also adds to its future application. In pharmaceutical research and development, its characteristics may be used to create new drugs and solve the world's diseases.
Furthermore, from the perspective of materials science, it is expected to participate in the production of new materials, giving materials specific properties.
I am convinced that with time, and with the hard work of many researchers, Bismuth (3 +) Trimethanesulfonate will surely shine, paving the way for future science and technology and people's well-being.

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Frequently Asked Questions

As a leading Bismuth(3+) Trimethanesulfonate supplier, we deliver high-quality products across diverse grades to meet evolving needs, empowering global customers with safe, efficient, and compliant chemical solutions.

What is the chemical structure of Bismuth (3 +) Trimethanesulfonate?

Bismuth (ⅲ) trimethanesulfonate, its chemical structure is composed of bismuth ion (Bi ³ 🥰) and trimethanesulfonate ion (CH 🥰 SO 🥰).
In trimethanesulfonate ion, the sulfur atom is connected to three methyl groups (-CH 🥰) by covalent bonds, and there are also specific chemical bonds between the sulfur atom and the three oxygen atoms. This structure endows trimethanesulfonate ion with certain stability and reactivity.
Bismuth ion (Bi ³ 🥰) has a specific charge and electron cloud distribution, which can be combined with trimethanesulfonate ion by electrostatic attractive force. Specifically, Bi ³ has three positive charges and trimethanesulfonate ions have one negative charge, forming bismuth (ⅲ) trimethanesulfonate through ionic bonding.
In the structure of this compound, the arrangement and interaction between atoms and ions determine its physical and chemical properties. Properties such as solubility and stability are closely related to this structure. In different chemical reaction environments, the structure of bismuth (ⅲ) trimethanesulfonate affects the way and degree of its participation in the reaction, and then plays a unique role in organic synthesis and other fields.

What are the main uses of Bismuth (3 +) Trimethanesulfonate?

Bismuth (ⅲ) trimethylsulfonate has a wide range of uses. In the field of organic synthesis, it is often used as a catalyst. Because of its unique chemical activity, it can effectively promote the progress of many chemical reactions. For example, in a specific esterification reaction, it can increase the reaction rate and make the reaction conditions milder, just like paving the way for the smooth development of the reaction.
In the field of materials science, it also has important applications. It can participate in the preparation of materials with specific properties, such as some materials with special electrical or optical properties. With the clever use of bismuth (ⅲ) trimethylsulfonate, the microstructure of the material can be precisely regulated, thus giving the material unique properties, just like a skilled craftsman carefully crafted works of art.
In the field of medicinal chemistry, it may have potential value. Although it has not been widely used in clinical practice, studies have shown that it can be used as a key intermediate in drug synthesis to help synthesize compounds with specific pharmacological activities, providing a new way and possibility for the development of new drugs, just like lighting a beacon in the journey of drug exploration.
Furthermore, in the production of some fine chemical products, bismuth (ⅲ) trimethyl sulfonate also plays a role that cannot be ignored. It can optimize the quality of products, improve the performance of products, and make fine chemical products more competitive in the market, which seems to inject a strong vitality into the fine chemical industry.

What is the preparation method of Bismuth (3 +) Trimethanesulfonate?

The preparation of bismuth (ⅲ) trimethanesulfonate requires specific steps and procedures.
First, prepare the required raw materials. Trimethanesulfonic acid (CH, SO, H) and bismuth sources (such as bismuth oxide (Bi, O)) are both critical. The bismuth source needs to be pure and free of impurities to maintain the purity of the product. Trimethanesulfonic acid also needs to meet the corresponding Quality Standards to ensure a smooth reaction.
Second, place an appropriate amount of bismuth source in an appropriate reaction vessel. If taking bismuth oxide as an example, pour it carefully into a clean flask. Then, slowly add trimethanesulfonic acid. This process needs to be done with caution, because the reaction may be violent to a certain extent, beware of liquid splashing.
Furthermore, the conditions of the reaction are quite important. Generally speaking, heating is required to promote the reaction. The heating temperature should be controlled within a certain range, about a moderate temperature, usually between hundreds and tens of degrees Celsius. When heating, it should be heated at a mild rate and stirred continuously, so that the reactants are fully contacted and the reaction can proceed uniformly. The stirring rate should also be appropriate. If it is too fast or causes the reactants to overflow, if it is too slow, the reaction rate will be slow.
Repeat, and pay close attention to the process of the reaction during the reaction. The change of color and the escape of gas can be observed to judge the degree of reaction. When the reaction reaches the desired stage, that is, the formation of the product has stabilized and there is no significant change, the reaction can be terminated.
At the end, the separation and purification of the product. After the reaction is completed, the reaction mixture is separated by appropriate means, such as filtration, distillation, etc., to obtain the crude bismuth (ⅲ) trimethanesulfonate. After further purification by recrystallization, high-purity bismuth (ⅲ) trimethanesulfonate can be obtained. The whole preparation process requires attention to all details to obtain the ideal product.

How Solubility of Bismuth (3 +) Trimethanesulfonate in Different Solvents

Bismuth (3 +) trimethanesulfonate has different solubility in different solvents. Water is a common polar solvent, and this compound may exhibit good solubility in water. Because trimethanesulfonate is hydrophilic, it can interact with water molecules through hydrogen bonds, etc., which promotes the uniform dispersion of bismuth (ⅲ) trimethanesulfonate in water to form a stable solution. Alcohol solvents such as methanol and ethanol, which are also polar, are similar to water and can interact with trimethanesulfonate. However, the hydrocarbon group of alcohols will affect the solubility. Usually, lower alcohols have strong polarity and small hydrocarbon groups, and the solubility of bismuth (ⅲ) trimethanesulfonate in them is acceptable; with the increase of hydrocarbon groups in alcohol molecules, the polarity decreases, and its solubility may decrease.
Acetonitrile is a polar organic solvent, but its interaction with trimethanesulfonate and bismuth ions may be different from that of water and alcohols. The solubility of bismuth (ⅲ) trimethanesulfonate in acetonitrile is slightly inferior to that in water, but it still has a certain solubility, which depends on the effect of the dipole moment and molecular structure of acetonitrile on the solute-solvent interaction.
In non-polar solvents, such as n-hexane and toluene, the solubility of bismuth (ⅲ) trimethanesulfonate is very poor. The non-polar solvent molecules lack effective interaction with polar trimethanesulfonate and bismuth ions, making it difficult to overcome the force between solute molecules, making it impossible to disperse and dissolve. Most of them exist in non-polar solvents in solid form.
Halogenated hydrocarbon solvents, such as dichloromethane, are moderately polar. The solubility of bismuth (ⅲ) trimethylsulfonate in dichloromethane or between polar and non-polar solvents depends on the regulation of solvent polarity by halogen atoms and the degree of interaction with the solute.

How is the stability of Bismuth (3 +) Trimethanesulfonate?

Bismuth (ⅲ) trimethanesulfonate, known as Bismuth (3 +) Trimethanesulfonate, has considerable stability. In this compound, bismuth ions are in the + 3 valence state, and trimethanesulfonate is coordinated with it. The material has a unique structure. The outer electrons of bismuth ions are arranged in a specific orbit, and trimethanesulfonate interacts with bismuth ions by virtue of its own structural characteristics to form a stable chemical structure.
From the perspective of chemical environment, bismuth (ⅲ) trimethanesulfonate can maintain a relatively stable state in common organic solvents, and is not easily dissociated due to solvent action or other side reactions. Under normal temperature and pressure, the compound has a stable lattice structure in the solid state, and the interaction force between ions in the lattice is balanced, which is not prone to structural changes.
When under moderate heating conditions, if the temperature does not exceed its thermal decomposition threshold, the compound can still remain stable. However, if the temperature is too high, beyond the tolerance range, and the chemical bond energy is not enough to maintain structural stability, decomposition reactions will occur. In common chemical reaction systems, bismuth (ⅲ) trimethyl sulfonate often exhibits good stability, and can be used as a stable catalyst or reaction intermediate to participate in many reactions. It is not easily deactivated or structurally changed due to subtle changes in reaction conditions, providing a stable and efficient catalytic environment for many organic synthesis reactions. It is a chemical with good stability.