1、Tung oil and rosin synergistically modified fluorinated epoxy resin
The present research demonstrates the synthesis of a novel FEP-TR resin by strategically incorporating biomass-based tung oil and rosin into a fluorinated epoxy matrix.
2、Journal of Applied Polymer Science
Experimental results demonstrated that the thermally cured fluorinated epoxy resins showed good thermal stability with decomposition temperature at 5% weight loss of 342–364°C in nitrogen, high glass transition temperature (Tg) of 165–171°C (determined by DMA), and outstanding mechanical properties with flexural strengths of 79–119 MPa ...
3、Degradable bio
New fluorinated Schiff-based epoxy resins derived from biomass exhibit good mechanical, fire resistance, and properties. This work demonstrates SA-BTB-EP’s potential as a composite matrix and offers a green way to make bio-based fluorinated materials.
4、Preparation and properties of a fluorinated epoxy resin with
In this article, a novel fluorinated epoxy resin (diglycidol ether of 2,4-bis (1,1,1,3,3,3-hexafluoroisopropyl) fluorobenzene (FB-EP)) with 45.7 wt% fluorine content was synthesized from fluorobenzene, epichlorohydrin and hexafluoroacetone.
5、Preparation of fluorinated epoxy‐phthalonitrile resins with excellent
At present, fluorinated epoxy resin (F-EP) is widely used, but its thermal and mechanical properties cannot meet the demand.
Fluorinated epoxy resin as a low adhesive mould for composite material
Adhesion results are discussed in terms of free surface energy of the modified epoxy resins, chemical affinity between the 2 resins and also mechanical properties of final surface of cured modified epoxy resins.
Preparation and Characterization of Fluorinated Acrylate and Epoxy Co
In this study, a new fluorinated chain extender (HFBMA-HPA) synthesized by free radical copolymerization and epoxy resin (E-44) were used to co-modify WPU, and five waterborne fluorinated polyurethane (WFPU) emulsions with different fluorine contents were prepared by the self-emulsification method.
Low dielectric constant and highly intrinsic thermal conductivity
Therefore, novel fluorine-containing liquid crystal epoxy compounds (TFSAEy) with fluorinated groups, biphenyl units, and flexible alkyl chains are first synthesized via amidation and esterification reactions.
Advanced studies on synthesis and cure reaction of fluorinated epoxy resin
Fluorinated epoxy resins (FERs) were extensively studied for applications in electronic packaging, optical waveguides, and antifouling coatings. This research focuses on the synthesis and characterization of FER following a polycondensation reaction between fluorinated bisphenol and epichlorohydrin.
Highly
In the present study, we developed a novel fluorinated epoxy omniphobic coating (FEOC) that addresses all the above shortcomings, making it low-cost, eco-friendly, anti-ultraviolet, self-healed, highly transparent, mechanically robust and chemically resistant.
In the vast realm of modern materials science, epoxy resins have become an indispensable cornerstone in numerous fields due to their excellent chemical stability, mechanical properties, and electrical insulation. when confronted with extreme environmental challenges such as high temperatures, pressures, or radiation, traditional epoxy resins often fall short. To broaden their application scope, scientists have proposed an innovative approach: fluorinated epoxy resins. By incorporating fluorine elements, this novel material not only significantly enhances its temperature resistance, pressure tolerance, and radiation resistance but also outperforms conventional epoxy resins in specific scenarios.
The birth of fluorinated epoxy resins stems from the relentless pursuit of high-performance materials. Driven by scientific research and technological advancements, scientists discovered that fluorine can react with hydroxyl groups in epoxy resins to form stable fluoride bonds, endowing the material with new chemical and physical properties. The successful development of fluorinated epoxy resins not only expands the epoxy resin family but also provides more reliable material options for many high-tech industries.
The superior performance of fluorinated epoxy resins主要体现在以下几个方面:
1. Enhanced Temperature Resistance Under extreme working conditions, traditional epoxy resins may soften or decompose due to elevated temperatures. In contrast, fluorinated epoxy resins maintain structural stability at higher temperatures, ensuring the long-term reliability of equipment or components.
2. Improved Pressure Resistance In high-pressure environments, material deformation or failure often leads to system collapse. Fluorinated epoxy resins resist pressure-induced effects by increasing strength and hardness, safeguarding structural integrity.
3. Superior Radiation Tolerance In fields like nuclear energy, aerospace, and military applications, radiation is a common challenge. Fluorinated epoxy resins absorb and disperse radiative energy, reducing material damage and extending service life.
4. Excellent Electrical Insulation In applications requiring insulation, fluorinated epoxy resins effectively prevent current leakage, ensuring circuit safety and stability.
The preparation of fluorinated epoxy resins involves sophisticated processes, including epoxy resin selection, fluorination reaction catalysis, and curing agent formulation. Catalyst choice is critical, as it directly impacts reaction speed and degree. Additionally, precise control of curing agent types and dosages ensures the final product meets performance expectations.
Fluorinated epoxy resins hold immense potential across diverse fields:
- Electronic Packaging: Enables smaller, more reliable packaging solutions.
- Aerospace: Suitable for manufacturing high-temperature-resistant, radiation-tolerant components.
- Energy Sector: Functions as a high-performance insulating material to ensure grid safety.
As technology advances and markets expand, fluorinated epoxy resins are poised to play an increasingly vital role in materials science.
Despite their advantages, challenges remain. Cost is a significant barrier, as high R&D and production expenses may deter small and medium-sized enterprises (SMEs) from adoption. Additionally, their processability might lag behind traditional epoxies, necessitating further optimization during design and manufacturing.
Looking ahead, fluorinated epoxy resins are full of boundless possibilities. With progress in materials science, they are expected to showcase unique strengths in more domains, contributing to human advancement. Let us anticipate the day when fluorinated epoxy resins become a brilliant star in materials science, illuminating the path forward.
