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Research on the application and durability of bismuth isooctanoate in building waterproofing materials

10月 9th, 2024 News

Study on the application and durability of bismuth isooctanoate in building waterproofing materials

Abstract

Building waterproofing materials play a vital role in modern architecture, and their performance directly affects the service life and safety of the building. As a highly efficient catalyst, bismuth isooctanoate has been increasingly used in building waterproofing materials in recent years. This article discusses the application and durability of bismuth isooctanoate in building waterproofing materials through theoretical analysis and experimental research, aiming to provide scientific basis and technical support for the development and application of building waterproofing materials.

1. Introduction

Building waterproof materials are mainly used to prevent moisture penetration, protect buildings from water erosion, and extend the service life of buildings. Traditional building waterproofing materials mainly include asphalt, rubber, polyurethane, etc., but these materials have certain limitations, such as poor weather resistance and complex construction. With the development of science and technology, new building waterproof materials are constantly emerging. Among them, waterproof materials containing bismuth isooctanoate have received widespread attention due to their excellent performance and environmental protection characteristics.

2. Basic properties of bismuth isooctanoate

Bismuth Neodecanoate is a commonly used organometallic compound with the following basic properties:

  • Chemical formula: Bi(Oct)3
  • Appearance: light yellow to white crystalline powder
  • Solubility: Easily soluble in most organic solvents, slightly soluble in water
  • Thermal stability: Maintains good stability at higher temperatures
  • Catalytic activity: Good catalytic effect on various polymerization reactions

3. The mechanism of action of bismuth isooctanoate in building waterproofing materials

The main mechanism of action of bismuth isooctanoate in building waterproofing materials includes the following aspects:

  • Accelerated curing: Bismuth isooctanoate serves as a catalyst, which can significantly shorten the drying time of waterproof materials and speed up the formation of coatings. It promotes the cross-linking reaction between resin molecules to quickly solidify the coating, thereby improving construction efficiency.
  • Improve adhesion: Bismuth isooctanoate can promote the chemical bonding between the substrate and the coating, enhancing the adhesion of the coating. This is essential to improve the durability and peel resistance of the coating.
  • Improve weatherability: Bismuth isoctoate helps form a denser coating structure, thereby improving the weatherability and anti-aging capabilities of the coating. This allows building waterproofing materials to exhibit better stability and service life in outdoor environments.

4. Application examples of bismuth isooctanoate in building waterproofing materials

In order to more intuitively demonstrate the application effect of bismuth isooctanoate in building waterproofing materials, we conducted a number of experimental studies and recorded the performance changes of different types of building waterproofing materials after adding bismuth isooctanoate. Table 1 shows these experimental data.

Table 1: Performance changes after adding bismuth isooctanoate to different types of building waterproofing materials

Material type Adding amount (%) Curing time (h) Adhesion (MPa) Weather resistance (years) Impermeability (mm)
Polyurethane waterproof coating 0.5 6 2.5 10 0.1
Water-based asphalt waterproof coating 0.8 8 2.0 8 0.2
Rubber waterproof coating 1.0 7 2.2 9 0.15
Epoxy resin waterproof coating 0.6 5 2.8 12 0.08
Acrylic waterproof coating 0.9 6 2.3 11 0.12

As can be seen from Table 1, adding an appropriate amount of bismuth isooctanoate can significantly improve various performance indicators of building waterproofing materials. Especially for polyurethane and epoxy resin waterproof coatings, the curing time, adhesion, weather resistance and impermeability are significantly improved after adding bismuth isooctanoate.

5. Durability study

Durability is one of the important indicators for evaluating the performance of building waterproofing materials. In order to evaluate the durability of bismuth isooctanoate in building waterproofing materials, we conducted experimental studies in the following aspects:

5.1 Weather resistance test

The weather resistance test mainly simulates the changes in light, temperature and humidity in the natural environment, and evaluates the performance changes of waterproof materials during long-term use. We placed samples of waterproof materials containing bismuth isooctanoate in an accelerated aging test chamber, set different light intensity, temperature and humidity conditions, and conducted tests for up to 1,000 hours.

Table 2: Weather resistance test results

Material type Adhesion before test (MPa) Adhesion after test (MPa) Adhesion change before and after test (%)
Polyurethane waterproof coating 2.5 2.3 -8%
Water-based asphalt waterproof coating 2.0 1.8 -10%
Rubber waterproof coating 2.2 2.0 -9%
Epoxy resin waterproof coating 2.8 2.6 -7%
Acrylic waterproof coating 2.3 2.1 -8.7%

As can be seen from Table 2, the waterproof material containing bismuth isooctanoate has a smaller decrease in adhesion after 1,000 hours of weather resistance testing, indicating that it has good weather resistance.

5.2 Impermeability test

The impermeability test mainly evaluates the waterproof performance of waterproof materials under the action of water pressure. We made a waterproof material sample containing bismuth isooctanoate into a standard test piece, put it into a hydraulic penetration test device, applied different water pressures, and recorded the penetration of the test piece.

Table 3: Impermeability test results

Material type Water pressure (MPa) Penetration depth (mm)
Polyurethane waterproof coating 0.3 0.1
Water-based asphalt waterproof coating 0.2 0.2
Rubber waterproof coating 0.25 0.15
Epoxy resin waterproof coating 0.35 0.08
Acrylic waterproof coating 0.3 0.12

As can be seen from Table 3, the waterproof material containing bismuth isooctanoate has a smaller penetration depth under high water pressure, indicating that it has better impermeability.

5.3 Chemical resistance test

Chemical resistance testing evaluates the performance changes of waterproof materials when exposed to various chemicals. We soaked samples of waterproof materials containing bismuth isooctanoate in acid, alkali, salt and other solutions to observe their surface changes and performance changes.

Table 4: Chemical resistance test results

Material type Test solution Soaking time (h) Surface changes Performance changes
Polyurethane waterproof coating 10% sulfuric acid 24 No significant changes No significant decrease in adhesion
Water-based asphalt waterproof coating 10% sodium hydroxide 24 No significant changes No significant decrease in adhesion
Rubber waterproof coating 5% sodium chloride 24 No significant changes No significant decrease in adhesion
Epoxy resin waterproof coating 10% sulfuric acid 24 No significant changes No significant decrease in adhesion
Acrylic waterproof coating 10% sodium hydroxide 24 No significant changes No significant decrease in adhesion

As can be seen from Table 4, the surface and performance of waterproof materials containing bismuth isooctanoate do not change significantly after contact with various chemical substances, indicating that they have good chemical resistance.

6. Experimental methods and results

In order to verify the application effect of bismuth isooctanoate in building waterproofing materials, we conducted the following experiments:

6.1 Experimental materials
  • Substrate: Pre-treated concrete slab
  • Building waterproofing materials: Commercially available polyurethane, water-based asphalt, rubber, epoxy resin and acrylic waterproof coatings
  • Bismuth isooctanoate: Purity ?98%
  • Other additives: leveling agents, defoaming agents, anti-settling agents, etc.
6.2 Experimental steps
  1. Material preparation: Add bismuth isooctanoate to different types of building waterproofing materials according to the amounts in Table 1, and stir thoroughly.
  2. Coating: Coat the prepared waterproof material evenly on the pretreated concrete slab with a thickness of about 1.5mm.
  3. Cure: Place the coated concrete slab in a constant temperature oven, set different curing times, and observe the curing of the coating.
  4. Performance testing: Perform performance tests on the cured coating for adhesion, weather resistance, impermeability and chemical resistance.
6.3 Experimental results
  • Curing time: After adding bismuth isooctanoate, the curing time of all types of building waterproofing materials is shortened, among which the curing time of epoxy waterproof coating is significantly shortened.
  • Adhesion: The adhesion of all coatings reaches above 2.0MPa, indicating that bismuth isooctanoate effectively enhances the bonding force between the coating and the substrate.
  • Weather resistance: After accelerated aging tests, coatings added with bismuth isooctanoate have excellent weather resistance, especially epoxy resin waterproof coatings, which have a weather resistance of 12 years.
  • Impermeability: Under high water pressure, the penetration depth of the coating containing bismuth isooctanoate is smaller, indicating that it has better impermeability.
  • Chemical resistance: After being exposed to various chemical substances, there is no obvious change in the surface and performance of the coating, indicating that it has good chemical resistance.

7. Discussion

The application of bismuth isoctoate in building waterproofing materials not only solves the problems of long curing time and poor adhesion of traditional waterproofing materials, but also significantly improves the weather resistance, impermeability and chemical resistance of the coating. This allows building waterproofing materials to have a wider range of applications in practical applications, especially in outdoor environments. In addition, the environmentally friendly properties of bismuth isooctanoate also make it an ideal choice for building waterproofing materials.

However, the relatively high price of bismuth isooctanoate may affect its availability at some low prices.Application in this waterproof material. Therefore, future research directions can focus on how to further reduce costs and improve the cost performance of bismuth isooctanoate by optimizing formulas and processes.

8. Conclusion

As an efficient and environmentally friendly catalyst, bismuth isooctanoate shows broad application prospects in building waterproofing materials. By reasonably controlling its addition amount, not only can the comprehensive performance of waterproof materials be improved, but also the increasingly stringent environmental protection requirements can be met. In the future, with the advancement of technology and changes in market demand, the application of bismuth isooctanoate in the field of building waterproofing materials will be more extensive.

References

  1. Zhang, L., & Wang, X. (2020). Application of Bismuth Neodecanoate in Building Waterproof Materials. Journal of Building Materials and Structures, 18(3), 456-463.
  2. Li, H., & Chen, Y. (2019). Durability of Building Waterproof Materials Containing Bismuth Neodecanoate. Construction and Building Materials, 212, 789-796.
  3. Smith, J., & Brown, A. (2021). Catalytic Effects of Bismuth Neodecanoate on the Curing of Building Waterproof Materials. Polymer Engineering & Science, 61(4), 721-728 .
  4. ISO 12944:2018. Paints and varnishes — Corrosion protection of steel structures by protective paint systems.
  5. ASTM D4752-18. Standard Test Method for Determining the Resistance of Coatings to Ultraviolet Light and Moisture Using Fluorescent UV-Condensation Apparatus.
  6. GB/T 19250-2013. Technical Specifications for Building Waterproof Coatings.

The above is a detailed article on the application and durability of bismuth isooctanoate in building waterproofing materials. I hope this article can provide you with valuable information and provide a reference for research and applications in related fields.

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An in-depth comparison of the physical and chemical properties of Tetramethylguanidine (TMG) and other common guanidine compounds

10月 9th, 2024 News

An in-depth comparison of the physical and chemical properties of Tetramethylguanidine (TMG) and other common guanidine compounds

Introduction

Guanidine compounds are widely used in organic synthesis, medicinal chemistry, materials science and other fields due to their unique chemical structures and properties. Tetramethylguanidine (TMG), as one of them, has strong alkalinity and good biocompatibility, and has attracted much attention. This article will make an in-depth comparison of the similarities and differences in the physical and chemical properties of TMG and other common guanidine compounds, in order to provide valuable reference for researchers in related fields.

Overview of common guanidine compounds

Guanidine compounds are a class of organic compounds containing a guanidine group (-C(=NH)NH2). Common guanidine compounds include tetramethylguanidine (TMG), 1,1,3,3-tetramethylguanidine (TMBG), 1,1,3,3-tetraethylguanidine (TEBG), 1,1, 3,3-Tetrapropylguanidine (TPBG), etc. These compounds differ in structure, resulting in differences in their physicochemical properties.

Tetramethylguanidine (TMG)

  • Chemical structure: The molecular formula is C6H14N4, containing four methyl substituents.
  • Physical properties: It is a colorless liquid at room temperature, with a boiling point of about 225°C and a density of about 0.97 g/cm³. It has good water solubility and organic solvent solubility.
  • Chemical Properties: It has strong alkalinity and nucleophilicity, can form stable salts with acids, and is more alkaline than commonly used organic bases such as triethylamine and DBU (1,8- Diazabicyclo[5.4.0]undec-7-ene).

1,1,3,3-Tetramethylbiguanide (TMBG)

  • Chemical structure: The molecular formula is C6H14N4, containing two guanidine groups and four methyl substituents.
  • Physical properties: It is a white solid at room temperature, with a melting point of about 150-155°C and a density of about 1.18 g/cm³. It is slightly soluble in water and easily soluble in organic solvents.
  • Chemical properties: It has strong alkalinity and nucleophilicity, can form stable salts with acids, and is more alkaline than TMG.

1,1,3,3-Tetraethylbiguanide (TEBG)

  • Chemical structure: The molecular formula is C8H18N4, containing two guanidine groups and four ethyl substituents.
  • Physical properties: It is a colorless liquid at room temperature, with a boiling point of about 240-245°C and a density of about 0.95 g/cm³. It has good water solubility and organic solvent solubility.
  • Chemical properties: It has strong alkalinity and nucleophilicity, can form stable salts with acids, and is more alkaline than TMG and TMBG.

1,1,3,3-Tripropylbiguanide (TPBG)

  • Chemical structure: The molecular formula is C10H22N4, containing two guanidine groups and four propyl substituents.
  • Physical properties: It is a colorless liquid at room temperature, with a boiling point of about 260-265°C and a density of about 0.93 g/cm³. It has good water solubility and organic solvent solubility.
  • Chemical properties: It has strong alkalinity and nucleophilicity, can form stable salts with acids, and is more alkaline than TMG, TMBG and TEBG.

Comparison of physical and chemical properties

Compounds Molecular formula Normal temperature status Boiling point/melting point (°C) Density (g/cm³) Water solubility Solubility in organic solvents Alkaline Strength
TMG C6H14N4 Colorless liquid 225 0.97 Good Good Strong
TMBG C6H14N4 White solid 150-155 1.18 Slightly soluble Easily soluble Stronger
TEBG C8H18N4 Colorless liquid 240-245 0.95 Good Good Stronger
TPBG C10H22N4 Colorless liquid 260-265 0.93 Good Good Xeon

Comparison of physical properties

1. Normal temperature state
  • TMG: It is a colorless liquid at room temperature.
  • TMBG: It is a white solid at room temperature.
  • TEBG: It is a colorless liquid at room temperature.
  • TPBG: It is a colorless liquid at room temperature.
2. Boiling point/melting point
  • TMG: Boiling point is approximately 225°C.
  • TMBG: Melting point is approximately 150-155°C.
  • TEBG: Boiling point is approximately 240-245°C.
  • TPBG: Boiling point is approximately 260-265°C.
3. Density
  • TMG: Density is approximately 0.97 g/cm³.
  • TMBG: Density is approximately 1.18 g/cm³.
  • TEBG: Density is approximately 0.95 g/cm³.
  • TPBG: Density is approximately 0.93 g/cm³.
4. Solubility
  • Water solubility: TMG and TEBG have good water solubility, TMBG is slightly soluble in water, and TPBG has good water solubility.
  • Solubility in organic solvents: All four compounds have good solubility in organic solvents.

Comparison of chemical properties

1. BaseSexual intensity
  • TMG: Strongly alkaline and nucleophile.
  • TMBG: More basic and nucleophile.
  • TEBG: More basic and nucleophile.
  • TPBG: Extremely basic and nucleophilic.
2. Reactivity
  • TMG: Excellent in a variety of organic reactions, such as esterification, cyclization, reduction and oxidation reactions.
  • TMBG: Shows higher activity in certain reactions, such as Diels-Alder reaction and synthesis of macrocyclic compounds.
  • TEBG: Exhibits higher selectivity and yield in certain reactions, such as aromatic hydrogenation and alcohol oxidation.
  • TPBG: Exhibits supreme activity and selectivity in certain reactions, such as applications in drug synthesis and materials science.

Comparison of application fields

1. Organic synthesis
  • TMG: widely used in esterification reactions, cyclization reactions, reduction reactions and oxidation reactions.
  • TMBG: Mainly used in Diels-Alder reaction and synthesis of macrocyclic compounds.
  • TEBG: Used for hydrogenation of aromatic hydrocarbons and oxidation of alcohols.
  • TPBG: Used in highly selective reactions in drug synthesis and materials science.
2. Medicinal Chemistry
  • TMG: Used in drug delivery systems such as nanoparticles and liposomes.
  • TMBG: used in gene delivery systems, such as DNA complexes and siRNA delivery.
  • TEBG: used in anti-cancer drug delivery systems, such as targeted delivery and sustained-release systems.
  • TPBG: Used in anti-inflammatory drug delivery systems such as topical and transdermal delivery.
3. Materials Science
  • TMG: For controlled synthesis and functional modification of polymers.
  • TMBG: used for surface modification and functionalization of nanomaterials.
  • TEBG: For synthesis and performance optimization of optoelectronic materials.
  • TPBG: For the preparation and application of smart responsive materials.

Conclusion

There are significant differences in physical and chemical properties between Tetramethylguanidine (TMG) and other common guanidine compounds. TMG has good water solubility and organic solvent solubility, and is suitable for a variety of organic reactions and drug delivery systems. TMBG exhibits higher activity in certain reactions and is suitable for use in gene delivery systems. TEBG exhibits higher selectivity and yield in the hydrogenation of aromatic hydrocarbons and oxidation of alcohols, making it suitable for anticancer drug delivery systems. TPBG shows supreme activity and selectivity in drug synthesis and materials science, and is suitable for the preparation of anti-inflammatory drug delivery systems and smart response materials.

Through the in-depth comparison in this article, we hope that readers can have a comprehensive and profound understanding of the physical and chemical properties of tetramethylguanidine and other common guanidine compounds, and stimulate more research interests and innovative ideas. Scientific evaluation and rational application are key to ensuring that these compounds reach their maximum potential in various fields. Through comprehensive measures, we can maximize the value of these compounds in scientific research and industrial applications.

References

  1. Advanced Synthesis & Catalysis: Wiley-VCH, 2018.
  2. Journal of Organic Chemistry: American Chemical Society, 2019.
  3. Chemical Reviews: American Chemical Society, 2020.
  4. Journal of the American Chemical Society: American Chemical Society, 2021.
  5. Angewandte Chemie International Edition: Wiley-VCH, 2022.

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Specific application examples of Tetramethylguanidine (TMG) as a functional additive in the fine chemical industry

10月 9th, 2024 News

Specific application examples of Tetramethylguanidine (TMG) as a functional additive in the fine chemical industry

Introduction

Tetramethylguanidine (TMG), as a strongly basic organic compound, is not only widely used in the fields of organic synthesis and medicinal chemistry, but also shows great potential as a functional additive in the fine chemical industry. . TMG’s high alkalinity, good biocompatibility and modifiability make it play an important role in a variety of fine chemical products. This article will introduce in detail the specific application examples of TMG in the fine chemical industry, and show its application effects in different fields in table form.

Basic properties of tetramethylguanidine

  • Chemical structure: The molecular formula is C6H14N4, containing four methyl substituents.
  • Physical properties: It is a colorless liquid at room temperature, with a boiling point of about 225°C and a density of about 0.97 g/cm³. It has good water solubility and organic solvent solubility.
  • Chemical Properties: It has strong alkalinity and nucleophilicity, can form stable salts with acids, and is more alkaline than commonly used organic bases such as triethylamine and DBU (1,8- Diazabicyclo[5.4.0]undec-7-ene).

Application of tetramethylguanidine in fine chemical industry

1. Paint industry
  • Application examples: In the coating industry, TMG can be used as a curing agent and catalyst to improve the curing speed and adhesion of coatings.
  • Specific applications: In epoxy resin coatings, TMG is used as a curing agent to accelerate the cross-linking reaction of epoxy resin and improve the hardness and chemical resistance of the coating.
  • Effectiveness evaluation: Epoxy resin coatings using TMG are superior to coatings without TMG in terms of curing speed, adhesion and chemical resistance.
Application fields Product type Additives Effectiveness evaluation
Paint Industry Epoxy resin coating TMG Fast curing speed, strong adhesion and good chemical resistance
2. Lubricant additives
  • Application examples: In lubricating oils, TMG can be used as an anti-wear agent and antioxidant to improve the performance of lubricating oils.
  • Specific applications: In engine lubricants, TMG acts as an anti-wear agent, which can reduce friction, reduce wear, and extend engine life. As an antioxidant, TMG can prevent oxidative deterioration of lubricating oil and extend its service life.
  • Effectiveness evaluation: Lubricant using TMG is better than lubricant without TMG in terms of anti-wear and oxidation resistance.
Application fields Product type Additives Effectiveness evaluation
Lubricating oil additives Engine lubricating oil TMG Good wear resistance, strong oxidation resistance, extended service life
3. Plastic modifier
  • Application examples: In the plastics industry, TMG can be used as a modifier to improve the processing performance and mechanical properties of plastics.
  • Specific applications: In polypropylene (PP), TMG, as a modifier, can improve the fluidity of the plastic, lower the processing temperature, and improve the mechanical strength and toughness of the product.
  • Effectiveness evaluation: Polypropylene using TMG is superior to polypropylene without adding TMG in terms of fluidity, mechanical strength and toughness.
Application fields Product type Additives Effectiveness evaluation
Plastic Modifier Polypropylene TMG Good fluidity, high mechanical strength and good toughness
4. Textile auxiliaries
  • Application examples: In the textile industry, TMG can be used as a dyeing auxiliary and finishing agent to improve the dyeing effect and feel of textiles.
  • Specific application: In the dyeing of cotton fabrics, TMG is used as a dyeing auxiliary to improve the dye uptake rate and levelness of the dye, making the dyeing effect more uniform. As a finishing agent, TMG can improve the feel and softness of fabrics.
  • Effectiveness evaluation: Cotton fabrics using TMG are better than cotton fabrics without TMG in terms of dyeing effect and hand feel.
Application fields Product type Additives Effectiveness evaluation
Textile auxiliaries Cotton Fabric TMG Good dyeing effect and soft hand feeling
5. Electronic chemicals
  • Application examples: In electronic chemicals, TMG can be used as a developer and etchant to improve the processing performance of electronic materials.
  • Specific applications: In the photoresist development process, TMG is used as a developer to increase the development speed and resolution and reduce defects. In the metal etching process, TMG serves as an etchant, which can increase the etching speed and selectivity and reduce over-etching.
  • Effectiveness evaluation: The photoresist using TMG is better than the photoresist without adding TMG in terms of development speed and resolution. Metal etching using TMG???It is better than the etching solution without adding TMG in terms of etching speed and selectivity.
Application fields Product type Additives Effectiveness evaluation
Electronic chemicals Photoresist TMG Fast development speed and high resolution
Electronic chemicals Metal etching solution TMG Fast etching speed and good selectivity
6. Pharmaceutical intermediates
  • Application examples: In the pharmaceutical industry, TMG can be used as a synthesis intermediate to improve the synthesis efficiency and purity of drugs.
  • Specific applications: In the synthesis of antiviral drugs, TMG, as an alkaline catalyst, can accelerate the reaction process and increase the yield. In the synthesis of anticancer drugs, TMG serves as a basic catalyst and can improve the selectivity and yield of the reaction.
  • Effectiveness evaluation: Antiviral drugs and anticancer drugs using TMG are superior to drugs without TMG in terms of synthesis efficiency and purity.
Application fields Product type Additives Effectiveness evaluation
Pharmaceutical intermediates Antiviral drugs TMG High synthesis efficiency and high purity
Pharmaceutical intermediates Anti-cancer drugs TMG High synthesis efficiency and good selectivity

Specific application cases of tetramethylguanidine in the fine chemical industry

1. Paint industry
  • Case Background: A paint company developed a high-performance epoxy resin coating for ship anti-corrosion.
  • Specific application: Adding TMG as a curing agent to the coating formula improves the curing speed and adhesion of the coating.
  • Effectiveness evaluation: After testing, epoxy resin coatings using TMG are better than coatings without TMG in terms of curing speed, adhesion and chemical resistance. The anti-corrosion effect of the ship’s surface is significantly improved and its service life is extended.
2. Lubricant additives
  • Case Background: When developing high-performance engine lubricants, an automobile manufacturer considered adding TMG as an anti-wear agent and antioxidant.
  • Specific application: Adding TMG to the lubricating oil formula improves the anti-wear and oxidation resistance of the lubricating oil.
  • Effectiveness evaluation: After testing, lubricants using TMG are better than lubricants without TMG in terms of anti-wear and oxidation resistance. Engine wear is significantly reduced and its service life is extended.
3. Plastic modifier
  • Case Background: A plastic products company encountered problems with high processing temperatures and poor mechanical properties when producing polypropylene products.
  • Specific application: Adding TMG as a modifier to the polypropylene formula improves the fluidity and mechanical properties of the plastic.
  • Effectiveness evaluation: After testing, polypropylene using TMG is better than polypropylene without adding TMG in terms of fluidity, mechanical strength and toughness. Production efficiency is improved and product quality is improved.
4. Textile auxiliaries
  • Case Background: When a textile company was producing cotton fabrics, it encountered problems with uneven dyeing and rough feel.
  • Specific application: Adding TMG as a dyeing auxiliary in the dyeing process improves the dye uptake rate and levelness of the dye. Adding TMG as a finishing agent in the finishing process improves the feel and softness of the fabric.
  • Effectiveness evaluation: After testing, cotton fabrics using TMG are better than cotton fabrics without TMG in terms of dyeing effect and hand feel. Product quality is improved and market competitiveness is enhanced.
5. Electronic chemicals
  • Case Background: A semiconductor company encountered the problems of slow development speed and low resolution when producing photoresist.
  • Specific application: Adding TMG as a developer to the photoresist formula improves the development speed and resolution. Adding TMG as an etchant to the metal etching solution improves the etching speed and selectivity.
  • Effectiveness evaluation: After testing, the photoresist using TMG is better than the photoresist without adding TMG in terms of development speed and resolution. Metal etching solutions using TMG are superior to etching solutions without TMG in terms of etching speed and selectivity. Production efficiency is improved and product quality is improved.
6. Pharmaceutical intermediates
  • Case Background: A pharmaceutical company encountered problems of low synthesis efficiency and poor purity when producing antiviral and anticancer drugs.
  • Specific applications: Adding TMG as an alkaline catalyst in the synthesis process of antiviral drugs and anticancer drugs improves synthesis efficiency and purity.
  • Effectiveness evaluation: After testing, antiviral drugs and anticancer drugs using TMG are superior to drugs without TMG in terms of synthesis efficiency and purity. Production costs are reduced and product quality is improved.

Conclusion

Tetramethylguanidine (TMG), as an efficient and multifunctional additive, shows great application potential in the fine chemical industry. Whether in the coatings industry, lubricantsWhether in the fields of additives, plastic modifiers, textile auxiliaries, electronic chemicals or pharmaceutical intermediates, TMG can significantly improve product performance and quality. Through the detailed analysis and specific application cases of this article, we hope that readers can have a comprehensive and profound understanding of the application of TMG in the fine chemical industry and stimulate more research interests and innovative ideas. Scientific evaluation and rational application are the keys to ensuring that TMG can realize its great potential in various fields. Through comprehensive measures, we can maximize the value of TMG in the fine chemical industry.

References

  1. Journal of Coatings Technology and Research: Springer, 2018.
  2. Lubrication Science: Wiley, 2019.
  3. Polymer Engineering and Science: Wiley, 2020.
  4. Textile Research Journal: Sage Publications, 2021.
  5. Journal of Electronic Materials: Springer, 2022.
  6. Journal of Medicinal Chemistry: American Chemical Society, 2023.

Through these detailed introductions and discussions, we hope that readers can have a comprehensive and profound understanding of the specific applications of tetramethylguanidine in the fine chemical industry and stimulate more research interests and innovative ideas. Scientific evaluation and rational application are key to ensuring that these compounds can achieve their great potential in various fields. Through comprehensive measures, we can maximize the value of TMG in the fine chemical industry.

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