1、Enhancing corrosion and abrasion resistances simultaneously of epoxy

Amino-polysiloxane/epoxy resin coatings can be cured at low temperature. Hyperbranched resin coatings display better comprehensive performances than the linear resin coating. Fluorine-containing resin coating shows the better corrosion resistance.

2、Study on epoxy resin modified by hyperbranched

A novel phosphorous/silicon hybrid containing active amino was synthesized by bisphenol F epoxy resin modified by 0- (2,5-Dihydroxyphenyl)−10-hydro-9-oxa-10-phosphaphenanthrene-10-oxide (ODOPB) and hyperbranched polysiloxane (APTMS-HPSi).

3、Using thermokinetic methods to enhance properties of epoxy resins with

Using biomolecules instead of synthetic curing agents can significantly reduce composites' toxicity and petrol-based carbon content. This study considerably exceeds the thermo-mechanical properties...

Molecular Simulations of Thermomechanical Properties of Epoxy

All-atom molecular dynamics (MD) simulations were performed with the CHARMM force field to characterize various epoxy resins, such as aliphatic and bisphenol-based resins.

Silicone Modified Epoxy Resins with Enhanced Chemical Resistance

Modification with Organic Side Groups: Typically modified with methyl, phenyl, vinyl, epoxy, or amino functional groups.

Advances in Toughening Modification Methods for Epoxy Resins: A

This work provides a comprehensive review of the recent advancements in the toughening modification methods for epoxy resins.

Phase morphology modulation of silicone

In this study, phase control of silicones in modified epoxy resins was achieved by modulating the curing process, and a series of silicone-modified epoxy resins with different phase sizes were prepared.

Off

To gain better insight into the aggregation states and physical properties at the adhesive interface, we examined the cross-linking structure and physical properties of the cured epoxy resins...

Amino

These findings suggest that APES-modified epoxy resin effectively enhances the overall mechanical performance of CF/EP composites, offering new insights and potential applications for the development of high-performance composite materials.

Double modified amino phenolic resin particles: A novel modifier to

We proposed a method to prepare double modified amino phenolic resin (D-APS) particles, which includes a hydrothermal synthesis and subsequent two-step modification. The prepared D-APS particle has a uniform spherical morphology. There were abundant and evenly dispersed amino hydrogen and phosphaphenanthrene groups on its surface.

In the realm of modern material science, epoxy resins and amino resins stand as two of the most critical高分子材料 (high-molecular-weight materials). They not only play pivotal roles in industrial applications but also demonstrate immense potential in scientific research and the development of new materials. This article aims to explore the fundamental properties, application fields, and environmental impacts of these two resins, providing readers with a comprehensive and in-depth perspective.

Epoxy Resins, as thermosetting plastics, are renowned for their excellent mechanical performance, chemical resistance, and electrical insulation properties. Their molecular structure contains epoxy groups, which can react chemically with other substances to form stable network structures, endowing them with superior physical characteristics. The application range of epoxy resins is extraordinarily broad, spanning from high-performance composites and precision electronic components to waterproof coatings in the construction industry. They are ubiquitous in fields requiring high strength and wear resistance.

In contrast, amino resins attract attention due to their unique thermoplasticity and exceptional adhesive properties. Their primary component,氨基甲酸酯 (carbamate), allows them to soften and flow upon heating, enabling bonding with other materials. Amino resins are widely used in automotive manufacturing, furniture production, and electronic packaging. They offer good electrical insulation while maintaining sufficient flexibility to meet complex application demands.

From an environmental standpoint, both epoxy and amino resins—as synthetic materials—may pose challenges. For instance, epoxy resins can release volatile organic compounds (VOCs) during curing, which, if uncontrolled, could harm air quality. Additionally, burning epoxy resins may release toxic gases like formaldehyde and phenol, posing health risks. Thus, developing low-VOC and non-toxic or low-toxic epoxy products, along with enhancing eco-friendly production processes, has become a focus in the industry.

To address these challenges, researchers and enterprises are actively exploring innovative solutions. Examples include reformulating to reduce harmful ingredients, adopting solvent-free or low-solvent production technologies to minimize VOC emissions, and developing recyclable composite materials. These efforts not only improve environmental outcomes but also chart new directions for the sustainable development of epoxy and amino resins.

Looking ahead, with technological advancements and growing environmental awareness, the application prospects of epoxy and amino resins will expand further. We have reason to believe that through continuous innovation and eco-practices, these two polymers will play even greater roles in advancing society while safeguarding our planet.

as pillars of modern material science, the capabilities and applications of epoxy and amino resins continue to evolve. Through deeper research and technological progress, we can anticipate their increased significance in future materials science and industrial production. Simultaneously, proactively addressing their environmental implications will drive the growth of green chemistry and sustainable technologies.