1、Carborane hybrid epoxy resins with excellent thermal stability and

This work expanded and optimized the synthesis pathway of carborane derivatives, imparting multifunctionality to epoxy resin and enhancing its various properties, thereby ensuring the safety of epoxy resin in nuclear facilities.

2、Preparation of Structural Heat

In this study, 1,2-bis (hydroxymethyl)carborane (CBOH) was first synthesized in large quantities through water extraction and then introduced into an epoxy resin cross-linked network. The incorporation of a carborane structure significantly improved the heat resistance of epoxy.

3、Carborane

Four types of carborane-containing polymers discussed in this review. In this review, the main focus will be on the synthesis of each class of carborane-containing polymers, including their properties and applications.

4、Curing behaviour and thermal properties of epoxy resin cured

The compatibility, thermal curing behaviour and thermal properties of HPPA/epoxy resin E51 system were investigated. HPPA exhibited good compatibility with E51.

5、High heat resistance and neutron shielding performance epoxy with

In this work, we report a novel efficient and environmentally friendly method for the large-scale production of hydroxylated carborane.

Carborane hybrid epoxy resins with excellent thermal

Polyazomethine and polyphenylene based on 1,2-bis (4-acetylbenzyl)-o-carborane Synthesis of chloro (organo)silylmethyl-o-carboranes from organochlorosilanes and bromomagnesiummethy...

Carborane

In this review, the main focus will be on the synthesis of each class of carborane-containing polymers, including their proper-ties and applications.

Carborane

A novel carborane-containing epoxy resin was prepared via the curing reaction between epoxy resin (E51) and 1,2-bis (4-aminophthalimide)dimethyl-1,2-dicarba-closododecaborane (4-AP CBR).

Preparation of Structural Heat

In this study, 1,2-bis (hydroxymethyl)carborane (CBOH) was first synthesized in large quantities through water extraction and then introduced into an epoxy resin cross-linked network. The incorporation of a carborane structure significantly improved the heat resistance of epoxy.

Study on thermal degradation mechanism of heat

To explore the role of carborane in the thermal degradation of epoxy resin, the thermal degradation mechanism of epoxy resin was studied by XPS and TG-IR-MS. Under high temperature, the epoxy resin undergone thermal oxidative degradation reaction.

In today's era of rapid technological development, the development and application of new materials are the key to promoting scientific and technological progress and industrial development. Carborane-modified epoxy resin, as an emerging material, has attracted much attention due to its unique properties. This article will explore the preparation methods, characteristics, and applications in various fields of carborane-modified epoxy resin.

I. Preparation Methods of Carborane-Modified Epoxy Resin

The preparation process of carborane-modified epoxy resin includes several key steps:

1. Selecting the appropriate resin matrix: Epoxy resin is a commonly used resin matrix with good chemical stability and mechanical properties. During the preparation process, it is necessary to select the appropriate epoxy resin as the matrix to ensure that the modified composite material has excellent performance after modification.
2. Introducing carborane: Carborane is a compound with a special structure that has strong polarity. By introducing carborane into the epoxy resin, the heat resistance and chemical corrosion resistance of the material can be significantly improved.
3. Curing treatment: In the preparation process, it is necessary to perform curing treatment on the modified epoxy resin. The curing process can be achieved by heating, pressurizing, or using a catalyst.
4. Post-treatment: After curing is completed, post-treatment of the composite material is also needed, such as surface treatment, heat treatment, etc., to further improve its performance.

II. Properties of Carborane-Modified Epoxy Resin

Carborane-modified epoxy resin has several characteristics:

1. Excellent heat resistance: Due to the presence of carborane, the modified epoxy resin has high heat resistance and can maintain good performance in high-temperature environments.
2. Good corrosion resistance: Carborane-modified epoxy resin also has good corrosion resistance and can resist the erosion of various chemicals.
3. Superior mechanical properties: Byoptimizing the preparation process, carborane-modified epoxy resin with excellent mechanical properties can be prepared to meet the needs of different fields.
4. Easy to process: Carborane-modified epoxy resin has good processing performance and can be formed by injection molding, extrusion, and other methods.

III. Applications of Carborane-Modified Epoxy Resin in Various Fields

Relying on its unique properties, carborane-modified epoxy resin has been widely used in various fields:

1. Electronic packaging: In the electronics industry, carborane-modified epoxy resin can be used to manufacture high-performance electronic packaging materials such as chip packages and circuit boards. These materials can withstand high temperatures and voltages while having good electrical insulation and thermal conductivity.
2. Aerospace: In the aerospace field, carborane-modified epoxy resin can be used to manufacture high-performance structural and functional parts. For example, for aircraft wings, engine housings, etc., which can improve the overall structural stability and load-bearing capacity.
3. Automotive manufacturing: In the automotive manufacturing field, carborane-modified epoxy resin can be used to manufacture high-performance automotive parts such as brake systems and suspension systems. These materials can provide better wear resistance and fatigue resistance, improving the overall performance of the car.
4. Medical devices: In the medical device field, carborane-modified epoxy resin can be used to manufacture high-performance medical device components such as artificial joints and surgical instruments. These materials have good biocompatibility and biodegradability, promoting the healing of human tissues.

As a new material with excellent properties, carborane-modified epoxy resin has shown broad application prospects in many fields. Through reasonable preparation methods and processing technologies, carborane-modified epoxy resin with excellent performance can be prepared to meet the needs of different industries. With the continuous progress and innovation of science and technology, we have reason to believe that carborane-modified epoxy resin will play a more important role in future development.