1、Multi

In recent years, thermal management technology based on phase change materials (PCMs) has provided a new solution for the development of wearable thermal management systems.

2、Lauric acid modified epoxy acrylate, preparation method and application

The lauric acid modified epoxy acrylate is prepared by carrying out an esterification reaction among epoxy resin, lauric acid and crylic acid at certain temperature in presence of a catalyst and a polymerization inhibitor.

3、Lauric Acid Modified Short Oil Alkyd Resin for High Gloss Finish

Lauric acid modified short oil Alkyd resin for yellowing resistant high gloss finish. Ideal for appliance, building, furniture, and car paint. Transparent mucus, 70% solid content.| Alibaba.com

4、Multi

Multi-mode triggered bio-based epoxy resin/lauric acid/graphene paper flexible phase change materials with high enthalpy value, multi-functionality, and personal thermal management ability

A facile dip

Immersing the cotton fabric (CF) into the γ-Fe2O3/epoxy resin/lauric acid (FEL) suspension for several minutes, followed by heat curing at 80 °C for 2 h, the superhydrophobic fabric (CF-FEL) was obtained.

A facile dip

In this contribution, we reported a facile dip-coating approach to prepare γ-Fe 2 O 3 /epoxy resin/lauric acid modified superhydrophobic cotton fabric (CF-FEL), which exhibited high adhesive ability towards water, excellent mechanical durability, oil/water separation property, and outstanding flame retardancy. γ-Fe 2 O 3 and lauric acid ...

Effect of Lauric Acid Modifier on the Hydrolysis Resistance of Aluminum

In this work, a dual-agent modification strategy utilizing polyethylene glycol (PEG) and lauric acid (LA) was implemented through a straightforward wet ball-milling protocol, successfully forming a chemically bonded encapsulation layer on AlN particles.

A facile dip

In this contribution, we reported a facile dip-coating approach to prepare γ-Fe 2 O 3 /epoxy resin/lauric acid modified superhydrophobic cotton fabric (CF-FEL), which exhibited high adhesive ability towards water, excellent mechanical durability, oil/water separation property, and outstanding flame retardancy. γ-Fe 2 O 3 and lauric acid ...

Synthesis and Properties of Epoxy Resin Modified with Novel Reactive

In this work, the influence of the new epoxy-containing liquid rubber-based modifiers on the thermal and mechanical properties of the cured epoxy resins was investigated.

Multi

Multi-mode triggered bio-based epoxy resin/lauric acid/graphene paper flexible phase change materials with high enthalpy value, multi-functionality, and personal thermal management ability

In numerous fields of modern high-performance materials science, epoxy resins are highly favored due to their unique physical and chemical properties. Among them, lauric acid-modified epoxy resins, as a新兴 class of advanced materials, have gradually garnered widespread attention from researchers and the industrial sector due to their excellent mechanical properties, thermal stability, and electrical insulation characteristics. This article provides an in-depth exploration of lauric acid-modified epoxy resins, analyzing their fundamental concepts, modification principles, practical applications, and future development prospects.

Lauric Acid-Modified Epoxy Resin: Concept and Principles Lauric acid-modified epoxy resin is a polymer composite material whose performance is enhanced by introducing lauric acid molecular chains into the epoxy resin matrix. As a long-chain fatty acid, lauric acid exhibits strong polarity and good compatibility, enabling stable interfacial interactions with epoxy resin. This modification not only improves the material’s thermal stability and mechanical properties but also expands its potential for application under extreme conditions.

The modification process involves two primary approaches:

1. Chemical Grafting: Lauric acid is covalently bonded to the epoxy resin molecular chain through chemical reactions.
2. Physical Dispersion: Methods such as melt intercalation or solution mixing are used to uniformly disperse lauric acid within the epoxy matrix. Both strategies effectively alter the microstructure of the epoxy resin, resulting in higher thermal stability and reduced water absorption.

Performance Advantages Lauric acid-modified epoxy resins demonstrate significant advantages:

• Thermal Stability: The incorporation of lauric acid chains increases the glass transition temperature (Tg), allowing the material to maintain structural integrity at lower temperatures—a critical feature for aerospace applications.
• Mechanical Properties: Enhanced tensile strength, hardness, and overall mechanical performance compared to unmodified epoxy resins.
• Oil Resistance and Corrosion Resistance: The hydrophobic nature of lauric acid improves durability in oily or corrosive environments.
• Processability: The modified resin retains versatility in shaping processes, enabling diverse manufacturing techniques.

Applications and Prospects The material shows broad application potential:

• Construction: Used for high-strength, durable concrete forms and bridge bearings.
• Electronics: Suitable for high-performance circuit boards and encapsulation materials.
• Aerospace: Leveraged for structural components in aircraft and satellites due to its superior heat resistance.

Challenges and Future Directions Despite its benefits, challenges remain, such as potential impacts on processability (e.g., reduced fluidity or curing speed). Research focuses on optimizing modification processes, developing cost-effective additives, and expanding applications. Additionally, aligning with green manufacturing and sustainability trends, eco-friendly and recyclable formulations of lauric acid-modified epoxy resins represent a key growth area.

As a novel high-performance material, lauric acid-modified epoxy resin is emerging as a research热点 in materials science. By advancing modification techniques and exploring innovative applications, this material is poised to drive significant progress in materials engineering and industrial technology.