1、Advanced chemical modification technology of inorganic oxide

In this comprehensive review, we explored advanced chemical modification techniques tailored for IONs incorporated into EP, providing a detailed examination of the mechanical characteristics of surface cm-ION/EP nanocomposites.

2、Development of nano–magnesium oxide modified hybrid resin

In the present study, we have synthesized a unique acrylic resin modified with nano MgO via sol-gel process. The synthesis involves polymerization of specially designed acrylic monomers to form acrylic resin followed by addition of nano MgO to acrylic resin under controlled temperature.

3、Novel nano magnesium oxide modified hybrid emulsion for

A novel hybrid emulsion polymer was synthesized by grafting of vinyl acetate (VAM), vinyl ester of versatic acid (VeoVa 10) monomers onto hyperbranched alkyd resin and incorporation of nano magnesium oxide (MgO) into the hybrid resin matrix during dispersion of resin in water.

4、Study on the toughening of epoxy resin modified by multi‐component

Abstract The present study investigates the effects of carbon nanofibers (CNF), nano-silica (SiO2) and short carbon fibers (SCF) on the tensile strength and fracture toughness of cured epoxy resins...

5、纳米TiO2改性环氧树脂的制备技术与性能研究进展

The preparation technology of nano-TiO2 modified epoxy resin is summarized, including mechanical stirring method, ultrasonic method, mechanical stirring and ultrasonic bonding method, bead milling method and chemical-physical bonding method.

Investigation of properties of nano

In this paper, modified epoxy resin films and composites were prepared by advanced liquid composite molding technology-resin film infusion (RFI) process.

Research on Nano

In this paper, phenolic resin was modified by nano-titanium using a physicochemical method. The nano-titanium-modified phenolic resin was used as a matrix to prepare the anticorrosive coating.

Nano

Nano-silica modified phenolic resin film is prepared using different mass fractions of nano-silica by liquid composites molding (LCM). The effects of nano-silica on the rheology and curing of phenolic resin are studied by rheometer and differential scanning calorimeter (DSC).

Epoxy resin/POSS/chitosan

The present research investigated the properties of epoxy resin nanocomposites containing POSS and silica nanoparticles modified by chitosan and the effect of type and weight percent of nanoparticles on properties nanocomposites.

Preparation of a nano

Put together, these results suggest that addition of dispersed nano-SiO2 has produced a modified MF resin with improved toughness and other favorable properties for potential use in wood composites and other applications.

In today's era of rapid advancements in modern science and technology, materials science has become one of the key forces driving social progress. As demand for high-performance products grows, traditional resin materials are increasingly unable to meet stringent application requirements. Against this backdrop, nano-modified resin technology has emerged, leveraging the unique properties of materials at the nanoscale to revolutionize conventional resins. This article explores the principles, applications, and development prospects of nano-modified resin technology.

I. Basic Principles of Nano-Modified Resin Technology

Nanotechnology is a science that studies interactions between substances at the atomic and molecular levels. Nano-modified resin technology involves incorporating nanoscale particles into resins to enhance their properties. These nanoparticles, which can be metallic, non-metallic, or organic, possess distinct physicochemical properties that interact with the resin matrix, improving mechanical strength, thermal stability, electrical insulation, and other characteristics.

II. Applications of Nano-Modified Resin Technology

1. Enhancing Mechanical Performance: Nanoparticles act as fillers in resins, forming composites that boost tensile strength, compressive strength, and impact toughness. For example, carbon nanotubes significantly improve the tensile and flexural strength of epoxy resins.

2. Improving Heat Resistance: Nanoparticles function as thermal stabilizers, raising the thermal decomposition temperature of resins and extending their service life. Boron nitride nanoparticles, for instance, enhance the thermal stability of polyimide resins.

3. Optimizing Electrical Properties: Nanoparticles enable the creation of conductive or semiconductor resins. Materials like nano-silver and graphene can impart excellent electrical and thermal conductivity to resins.

4. Boosting Corrosion Resistance: Nanoparticles serve as anticorrosion coatings, protecting resins in harsh environments. Nanozinc oxide, for example, is a key component in long-lasting rust-preventive coatings.

5. Developing Novel Materials: Nano-modified resin technology facilitates the creation of advanced functional materials, such as self-healing materials, photosensitive materials, and shape-memory materials.

III. Development Prospects of Nano-Modified Resin Technology

Nano-modified resin technology holds vast potential and market opportunities. With advances in nanotechnology, a broader range of nanoparticles will likely be integrated into resins to achieve superior performance. This technology is also expected to address challenges in applying traditional resins to specialized fields, such as aerospace, new energy, and biomedical industries.

IV. Challenges and Countermeasures

Despite its promise, nano-modified resin technology faces practical challenges. Key issues include precisely controlling the distribution and morphology of nanoparticles, ensuring compatibility between nanoparticles and resin matrices, and reducing production costs. Addressing these challenges requires further research and innovation.

As an emerging material modification technique, nano-modified resin technology has transformed conventional resins. By introducing nanoparticles, resins gain significantly enhanced properties and expanded applications across diverse fields. With ongoing technological progress and the discovery of new nanomaterials, nano-modified resin technology is poised for even broader development in the future.