Mineral oil lubricants protect engine parts from wear, and this effect is enhanced by adding polymer nanoparticles to the lubricating oil. A UK team has now discovered that epoxy functionalization of these nanoparticles further promotes friction reduction on metal surfaces. As the team reports in the journal Angewandte Chemie, nanoparticles containing epoxy groups adhere strongly to stainless steel surfaces, which leads to a significant reduction in friction.
Automotive engines comprising well lubricated parts consume less fuel, produce lower emissions, and suffer less long-term wear. Mineral oil is widely used as a lubricant, and nanoparticles can be directly prepared within this solvent using a technique known as polymerization-induced self-assembly. Coating the surface of the metal components with nanoparticles of a few dozen millionths of a millimeter in size protects them from direct contact.
Csilla György and Steve Armes at the University of Sheffield (UK) designed “hairy” nanoparticles comprising oil-soluble poly(lauryl methacrylate) chains and an oil-insoluble nanoparticulate core. These nanoparticles were made to stick strongly to metal surfaces by introducing epoxy groups into the “hairs” by copolymerizing lauryl methacrylate with glycidyl methacrylate, an epoxy-functional monomer.
The team found that the epoxy-bearing nanoparticles reacted with hydroxy groups located at the surface of stainless steel. This reaction led to strong adhesion of the nanoparticles, a phenomenon known as chemical adsorption. Whether chemical adsorption occurred or not depended on the precise location of the epoxy groups. “To our surprise, introducing a far larger number of epoxy groups into the nanoparticle cores had no beneficial effect,” explains Armes.
The adsorbed nanoparticles reduced friction significantly, as the Sheffield team discovered when conducting tribological studies in collaboration with scientists at Lubrizol, an engine oil additives company based in the UK. “Remarkably, the adsorbed nanoparticles remained intact on the stainless steel surface after such experiments, which were conducted at the typical operating temperature of an internal combustion engine,” Armes adds.
Such epoxy-functionalized nanoparticles could therefore mean a further leap in performance for lubricant additives for next-generation engine oil formulations.
About the Author
Prof. Steven P. Armes, FRS, is the Firth Professor of Chemistry and Professor of Polymer and Colloid Chemistry at the Department of Chemistry of the University of Sheffield, UK. His research team combines living radical polymerization techniques with polymerization-induced self-assembly to prepare block copolymer nanoparticles for a wide range of applications.
Angewandte Chemie International Edition
Method of Research
Subject of Research
Enhanced Adsorption of Epoxy-Functional Nanoparticles onto Stainless Steel Significantly Reduces Friction in Tribological Studies
Article Publication Date
The authors declare no conflict of interest.