1、Constructing micro

In this work, a controlled-release boron-polyurethane antifouling coatings (DBIT) with a dynamic surface were synthesized by immobilizing the organic antifouling functional group PDB in the polyurethane resin. DBITx coatings realize a micro-dynamic surface and achieve environmentally friendly.

2、Terpolymer resin containing bioinspired borneol and controlled release

In order to prevent sea creatures from attaching to the surface, in this work, a new environmentally friendly antifouling coating by incorporating antibacterial polymers and natural antifouling...

3、Journal of Applied Polymer Science

From thermal stability and char yield studies, it can be concluded that boron modified resin system is superior to the phenolic resin making it a potential candidate for high temperature and ablative applications.

4、Constructing micro

Currently, it is highly desirable to develop a novel antifouling resin with a controllable hydrolysis rate and stable and effective antifouling performance for marine antifouling coatings.

Research Progress in Boron

In this review, the current state of development of BPF and its composites is presented and discussed. After introducing various methods to synthesize BPF, functionalization of BPF is briefly summarized.

Bioinspired rosin

This study presents the successful synthesis of an eco-friendly antifouling coating, denoted as PSBZ-X-Y, through the grafting of a hydrolysable borneol-modified zwitterionic precursor, DEA-IBOA, onto a bio- derived rosin resin.

Enhanced thermal and mechanical properties of boron

This study aims to investigate the properties of boron-modified phenolic resin (BPR) composites reinforced with glass fiber (GF) and mica, SiO 2, and glass powder (MSG) for potential aerospace applications.

Effect of Boron Modification on Characteristics of Phenolic

The thermal and ablative performance of phenolic resins can be further improved by incorporating inorganic elements like boron to the phenolic resin structure. These modifications can also affect the structure and properties of char which is formed during ablation.

Boron phenolic resin/silica sol coating gives rigid polyurethane foam

In this paper, a boron phenolic (BPR)/silica sol (Si-sol) coated flame retardant was prepared, and the flame retardant was coated on the surface of rigid polyurethane foam (RPUF) to make it have excellent flame-retardant effects.

Synergistically Improved Antifouling Efficiency of a Bioinspired Self

Herein, a polymer containing isoborneol and borane (PBABs), the borneol derivative structure and grafted pyridine-triphenylborane (PTPB) as antifouling groups were prepared by radical polymerization.

In modern industrial and marine engineering, the performance of materials directly affects their application outcomes and safety. With growing environmental awareness and the increasing scarcity of marine resources, developing new eco-friendly antifouling materials has become a critical research topic. As an innovative material, boron-modified antifouling organic resins have garnered widespread attention due to their unique properties. This paper explores the preparation methods, performance characteristics, and practical application potential of boron-modified antifouling organic resins.

1. Preparation Methods of Boron-Modified Antifouling Organic Resins

The synthesis of boron-modified antifouling organic resins involves multiple steps. First, appropriate monomers are selected for polymerization reactions to form prepolymers. Next, boron compounds such as boric acid or borate esters are chemically bonded into the polymer chains, resulting in boron-modified organic resins. Controlling polymerization conditions and incorporation methods is key to ensuring the final product’s performance. Additionally, the durability and stability of the material can be enhanced by adding other functional additives to optimize the resin’s properties.

2. Performance Characteristics of Boron-Modified Antifouling Organic Resins

Boron-modified antifouling organic resins exhibit several superior properties. For example, their low surface energy reduces oil adsorption, effectively preventing marine biofouling. The presence of boron compounds also provides excellent corrosion resistance, enabling the resin to maintain stability in harsh marine environments for extended periods. Furthermore, these resins demonstrate good mechanical and processing properties, making them suitable for integration into various composite materials.

3. Application Prospects of Boron-Modified Antifouling Organic Resins

Boron-modified antifouling organic resins hold broad application potential in marine conservation, shipbuilding, oil drilling, and other fields. In marine engineering, they can serve as protective coatings for submarine pipelines and ship hulls, reducing biofouling and corrosion. In shipbuilding, their use prolongs vessel lifespan and lowers maintenance costs. In oil drilling, these resins can act as anticorrosion materials for drilling platforms, improving efficiency while minimizing environmental pollution.

As an eco-friendly, high-performance material, boron-modified antifouling organic resins represent a promising direction in materials science due to their antifouling, corrosion-resistant, and anticorrosion properties. Further research and broader application of this material could significantly advance industrial and marine engineering, fostering harmonious coexistence between human activities and marine ecosystems.