1、Recent progress and multifunctional applications of fire

In this perspective, we classified fire-retardant epoxy resins into three groups: (1) intrinsic, (2) blends, and (3) composites. A closer investigation of the performance-enhanced material compositions based on multifunctional fire-retardant epoxy resins was undertaken.

2、Multifunctionality in Epoxy Resins

These aspects, when considered in the synthesis and formu-lation of epoxy resins will be a radical advance for thermosetting poly-mers, with a lot of applications. Therefore, we present an overview of the recent finding as to pave the way for varied approaches towards multifunctional epoxy resins.

3、Multifunctional Epoxy Resins: Self

This book consolidates information about multifunctional epoxy as a frontier material, its composites, engineering and applications in a very detailed manner that encompasses the entire spectrum of up-to-date literature citations, current market trends and patents.

New Progress in the Application of Flame

In this review, the flame-retardant mechanism and method of flame-retardant epoxy resins are briefly analyzed. The research progress of the flame-retardant modification of epoxy resin by physical addition and chemical reaction is summarized and discussed.

Optimizing dielectric, mechanical, and thermal properties of epoxy

Epoxy resins are widely used as dielectric materials in electrical and electronic systems.

High performance epoxy resin composites modified with multifunctional

In this work, a reactive flame-retardant (BDO) was synthesized from DOPO, 3,5-diamino-triazolz and thiophene-2-formaldehyde, and taken to prepare EP/BDO composites.

Recent Advances in Epoxy Resin Applications

To paper, the existing epoxy resin systems were reviewed overcome latest epoxy flame-retardant the shortcomings resin technologies, of the existing Currently, bio-based resources, resins, being derived from BPA.

(PDF) Multifunctionality in Epoxy Resins

These aspects, when considered in the synthesis and formulation of epoxy resins will be a radical advance for thermosetting polymers, with a lot of applications. Therefore, we present an overview of the recent finding as to pave the way for varied approaches towards multifunctional epoxy resins.

Multifunctional epoxy nanocomposites reinforced by two

Abstract Epoxy resins are thermosetting polymers with an extensive set of applications such as anticorrosive coatings, adhesives, matrices for fibre reinforced composites and elements of electronic systems for automotive, aerospace and construction industries. Τhe use of epoxy resins in many high-performance

Multi

For example, the cure behavior and reaction mechanism, as well as the properties of a multifunctional epoxy resin modified with polyhedral oligomeric silsesquioxane (POSS) nanoparticles were investigated by Li et al. [1].

With the advancement of technology, new materials and innovations continue to emerge in the field of materials science. Among these, modified epoxy resins, as a novel high-performance material, have garnered significant attention due to their unique properties and broad application prospects. Not only do they exhibit excellent mechanical strength, electrical insulation, chemical resistance, and dimensional stability, but they also offer superior processability. These characteristics enable modified epoxy resins to play critical roles in aerospace, automotive manufacturing, electronics, construction, and other industries. This article explores their applications across various fields and the underlying principles driving their utility.

I. Applications in Aerospace

The aerospace industry demands materials that are lightweight, high-strength, corrosion-resistant, and capable of withstanding extreme conditions. By integrating nanoparticles or fiber reinforcements, modified epoxy resins achieve enhanced mechanical performance and thermal resistance, making them ideal for aerospace structural components. For example, they are used in aircraft wings, fuselages, and landing gear, where they endure harsh environments—such as high temperatures, pressures, and friction—while maintaining structural integrity. Additionally, surface treatments like coatings or plating can further improve corrosion resistance and wear resistance, extending the lifespan of aircraft.

II. Applications in Automotive Manufacturing

The automotive industry prioritizes lightweight, high-strength, and wear-resistant materials. Modified epoxy resins meet these requirements through molecular structure adjustments or functional group additions, delivering superior hardness, rigidity, and thermal stability. They are employed in engine parts, chassis structures, and body panels to reduce wear, fatigue, and maintenance costs, while boosting vehicle performance and safety.

III. Applications in Electronics and Electrical Engineering

Electronic devices require materials with strong electrical insulation, thermal conductivity, and signal transmission capabilities. By incorporating thermal conductive fillers or conductive polymers, modified epoxy resins improve their electrical and thermal properties. In circuit boards, cables, and connectors, they ensure reliable electrical performance and mechanical stability, essential for the consistent operation of electronics.

IV. Applications in Construction

Urbanization has driven higher standards for construction materials. Modified epoxy resins excel in adhesion, impact resistance, and durability, making them suitable for exterior wall decoration, waterproof sealing, and flooring. In high-rise buildings, epoxy coatings provide long-lasting color protection and weather resistance. Their exceptional bonding capabilities also enable structural repairs and reinforcements, enhancing building safety.

modified epoxy resins, as a high-performance material, have found versatile applications in aerospace, automotive, electronics, and construction. Through optimized molecular design and precise functional tuning, they address specific needs across diverse industries, demonstrating immense market potential. Looking ahead, ongoing technological advancements will likely expand their use into emerging fields, enabling greater contributions to human progress.