1、A comprehensive review on modified phenolic resin composites for

This review provides an in-depth examination of the progress in PR modification research from both physical and chemical perspectives, highlighting the improved performance post-modification.

2、Synthesis, characterization and modification of silicone resins: An

Abstract This article deals with the preparation and modification of resins, as found in patents and articles and exhaustively reported here, and their characterization and functionalization, complemented by our own experimental experience.

3、超高分子量聚乙烯纤维表面改性研究进展

Firstly, this review examines the recent research on the surface modification of UHMWPE fibers, and introduces the interfacial properties and mechanism of fiber reinforced polymers (FRP).

Modification of Synthetic Resins

With ongoing technological progress and evolving societal needs, research in synthetic resin modification will continue to advance, providing humanity with better material solutions.

Comprehensive Analysis of the Impact of Various Surface Modification

This study explores the impact of various surface modification techniques—vacuum ultraviolet (VUV) irradiation, oxygen plasma treatment, and atmospheric pressur

Advances in Toughening Modification Methods for Epoxy Resins: A

Following the systematic exposition of conventional experimental development and testing methodologies, this study provides a comprehensive synthesis of computational modeling techniques and machine learning applications in epoxy resin development and performance prediction.

Exploration and Practice of Synthetic Resin Modification

With advancements in science and technology, the demands for the performance of synthetic resins have continually risen, making research and application of resin modification increasingly critical.

A comprehensive review of synthesis, properties and modification of

Polyethylene (PE) has good chemical stability and corrosion resistance and is one of the top five synthetic resins, widely used in the manufacture of films and fibers.

Enabling phenolic resin toughening and heat resistant

To satisfy high-end and demanding application requirements, phenolic resin modification always stays the research focus in this field. This review involved two main characteristics of phenolic resins, toughness and heat resistance.

Research progress on modification of phenolic resin

In recent years, more and more researchers have focused on the discussion of the properties of modified phenolic resins and gradually ignored the research on the synthesis processes that can affect the molecular structure and properties of phenolic resins.

As the cornerstone of modern industry, the properties and functions of synthetic resins directly impact the performance and quality of downstream products. With advancements in technology, research into the comprehensive modification of synthetic resins has deepened, aiming to enhance their properties through various methods to meet increasingly stringent application demands. This paper explores the technologies and applications of integrated modification of synthetic resins.

The modification of synthetic resins typically involves physical, chemical, and bio-based approaches. Physical modification improves performance by altering the resin’s structure, such as adding fillers or incorporating fibers. Chemical modification focuses on molecular-level adjustments, including graft polymerization, crosslinking, and copolymerization. Bio-modification utilizes microorganisms or plant extracts to impart new functional characteristics.

In physical modification, adding fillers is a common method. For example, reinforcing plastics with glass fibers or carbon fibers significantly enhances strength and rigidity while reducing density. Though cost-effective and straightforward, this approach may compromise processability or aesthetics.

For chemical modification, grafting is a widely used technique. Introducing new monomers into polymer chains allows performance tuning without altering the base polymer structure. For instance, incorporating vinyl monomers into polypropylene creates antistatic materials. Crosslinking, another key method, forms three-dimensional networks to improve heat resistance, mechanical strength, and dimensional stability.

Bio-modification, an emerging field, has gained attention for its eco-friendly potential. Microbial enzymes or fermentation processes can produce functionalized polymers, such as polylactic acid (PLA), which is biodegradable and suitable for single-use tableware and biomedical materials.

Beyond these methods, other strategies are being explored. Surface coating technologies enhance corrosion and wear resistance, while nanotechnology introduces nanoparticles to improve mechanical, thermal, and electrical properties.

Integrated modification techniques have broad applications. In automotive industries, modified resins improve heat, oil, and chemical resistance of plastic components. In electronics, they enable lighter, higher-strength circuit boards and cables. In construction, modified plastics exhibit better pressure resistance and weatherproofing.

challenges remain. Modification processes may introduce impurities, affecting product quality. Synergistic effects between different methods require further study to optimize outcomes. Additionally, integrating novel materials into existing resin systems poses a future research direction.

the comprehensive modification of synthetic resins is a multidisciplinary and technologically intensive field. By combining physical, chemical, and bio-based approaches, resin performance can be substantially enhanced to meet modern demands. As technology advances, these modifications will mature further, driving progress and innovation across industries.