1、Oleic acid tailored Al2O3

Initially, 10 g of ethanol and 50 mg of oleic acid were dissolved entirely, and then 10 g of epoxy resin was diluted in the solution. Subsequently, different concentrations of AZ ceramic nanoparticles (0.05, 0.1, and 0.15 wt%) were added and thoroughly mixed using magnetic stirring.

2、Sustainable approach for catalytic green epoxidation of oleic acid with

Therefore, this study aimed to optimize the catalytic epoxidation of palm oleic acid concerning the oxirane content by applying ion exchange resin as a catalyst.

3、油溶性Oleic acid modified Fe3O4 nano（90nm）,油酸修饰

随后，油酸（oleic acid）通常用作表面活性剂，通过溶剂或热处理，将油酸分子吸附在Fe3O4颗粒的表面。 这个过程可以使得Fe3O4颗粒表面具有亲油性，从而增强其在有机相中的分散性。

4、关于Oleic acid modified Fe3O4 nano（150nm）的文献应用

关于Oleic acid modified Fe3O4 nano（150nm）的文献应用 今天小编瑞禧整理并分享关于Oleic acid modified Fe3O4 nano（150nm）的文献应用： 文献描述： 采用水热法合成了在液体石蜡中具有良好亲和性和稳定性的Fe3O4/油酸 (OA)纳米粒子。

Unsaturated Polyester Resin Nanocomposites Containing ZnO Modified with

CDI–OA–APS–ZnO nanoparticles were embedded in the net structure of the UP composites through chemical bonds between oleic acid, styrene, and polyester resin, which significantly influence the cure reaction of UP resin and the properties of UP composites.

Oleic acid modified acrylic resin

Oleic acid modified acrylic resin information, including chemical properties, structure, melting point, boiling point, density, formula, molecular weight, uses, prices, suppliers, SDS and more, available at Chemicalbook.

Effect mechanism of the Fe3O4 nanoparticles on mechanical properties

In this paper, the nanocomposites reinforced epoxy that modified with oleic acid Fe 3 O 4 nanoparticles (OMNPs) had been successfully prepared.

Preparation and Characterization of a Novel Biodegradable Epoxy Resin

In this paper we demonstrate the efficient epoxidation of oleic acid with performic acid generated in situ from formic acid and hydrogen peroxide in the presence of H2SO4 as catalyst.

Corrosion Resistance Study of Cyclocarboxypropyl Oleic Acid

In this study, polyaniline powders doped with different molar concentrations of cyclocarboxypropyl oleic acid (CCHOA) were synthesized and incorporated into epoxy resin to create composite coatings.

Direct Continuous Synthesis of Oleic Acid

In this work, a direct continuous synthesis route of oleic acid (OA)-modified Fe 3 O 4 nanoparticles was proposed and achieved by combining flow co-precipitation of Fe 3 O 4 nanoparticles in a membrane dispersion microcontactor with the in-line introduction of OA.

In modern industry, the performance of materials determines the breadth and depth of their application fields. As an important class of polymer materials, modified oleic acid resin plays an irreplaceable role in multiple domains due to its unique chemical structure and physical properties. This article explores the fundamental characteristics, preparation methods, and practical significance of modified oleic acid resin.

I. Basic Concept of Modified Oleic Acid Resin

Modified oleic acid resin is a polymer material synthesized through chemical reactions that combine natural vegetable oil acids with synthetic resins. This resin exhibits excellent temperature resistance, electrical insulation, and processability while retaining the biodegradability and environmental friendliness of vegetable oils. Widely used in coatings, adhesives, sealants, composites, and other fields, it is a critical material for advancing green chemistry and sustainable development.

II. Preparation Methods of Modified Oleic Acid Resin

The synthesis of modified oleic acid resin involves multiple steps, including raw material selection, ratio design, and reaction condition control. First, appropriate vegetable oils and synthetic resins (e.g., epoxy resins, phenolic resins) are chosen. The reaction is then initiated through heating, stirring, or other means to chemically bond the vegetable oils with the resins, forming a stable modified oleic acid resin. Additionally, additives can be incorporated to enhance specific properties, such as mechanical strength or weather resistance.

III. Applications of Modified Oleic Acid Resin

1. Coatings Industry

Modified oleic acid resin is extensively used in coatings. Its superior temperature resistance, electrical insulation, and mechanical strength make it ideal for protective coatings in high-temperature environments, such as automotive engine components and electrical equipment surfaces. Furthermore, its strong adhesion and wear resistance have led to widespread adoption in waterproof and anticorrosion coatings for construction.

2. Adhesives Industry

Modified oleic acid resin plays a vital role in adhesive formulations. Its exceptional bonding properties and thermal stability suit it for bonding various materials, including metals, plastics, and ceramics. Additionally, its outstanding aging resistance ensures long-term durability in adhesive applications.

3. Sealants Industry

Modified oleic acid resin offers significant advantages in sealant applications. Its low-smoke, halogen-free nature makes it suitable for special sectors like aerospace and nuclear power plants. its corrosion resistance effectively prevents chemical erosion of sealed components.

4. Composites Industry

Modified oleic acid resin is indispensable in composite materials. When combined with high-performance fibers or matrices, it substantially improves composite properties, such as strength, rigidity, and chemical resistance. This makes it a preferred choice for manufacturing advanced composites.

modified oleic acid resin, as a high-performance polymer material, demonstrates unique advantages across diverse applications. With ongoing technological advancements and deeper research into new materials, its applications will expand further, contributing significantly to human progress and sustainability.