University of Wollongong
Browse

File(s) not publicly available

Tribological behavior of aqueous copolymer lubricant in mixed lubrication regime

journal contribution
posted on 2024-11-16, 08:29 authored by Thi Dinh Ta, Anh TieuAnh Tieu, Hongtao ZhuHongtao Zhu, Qiang ZhuQiang Zhu, Prabouno B Kosasih, Jie Zhang, Guanyu DengGuanyu Deng
Although a number of experiments have been attempted to investigate the lubrication of aqueous copolymer lubricant, which is applied widely in metalworking operations, a comprehensive theoretical investigation at atomistic level is still lacking. This study addresses the influence of loading pressure and copolymer concentration on the structural properties and tribological performance of aqueous copolymer solution of poly(propylene oxide)-poly(ethylene oxide)-poly(propylene oxide) (PPO-PEO-PPO) at mixed lubrication using a molecular dynamic (MD) simulation. An effective interfacial potential, which has been derived from density functional theory (DFT) calculations, was employed for the interactions between the fluid's molecules and iron surface. The simulation results have indicated that the triblock copolymer is physisorption on iron surface. Under confinement by iron surfaces, the copolymer molecules form lamellar structure in aqueous solution and behave differently from its bulk state. The lubrication performance of aqueous copolymer lubricant increases with concentration, but the friction reduction is insignificant at high loading pressure. Additionally, the plastic deformation of asperity is dependent on both copolymer concentration and loading pressure, and the wear behavior shows a linear dependence of friction force on the number of transferred atoms between contacting asperities.

Funding

A physically based abrasive wear model for high-speed steel at high temperature

Australian Research Council

Find out more...

History

Citation

Ta, T. D., Tieu, K., Zhu, H., Zhu, Q., Kosasih, P. B., Zhang, J. & Deng, G. (2016). Tribological behavior of aqueous copolymer lubricant in mixed lubrication regime. ACS Applied Materials and Interfaces, 8 (8), 5641-5652.

Journal title

ACS Applied Materials and Interfaces

Volume

8

Issue

8

Pagination

5641-5652

Language

English

RIS ID

105802

Usage metrics

    Categories

    Keywords

    Exports

    RefWorks
    BibTeX
    Ref. manager
    Endnote
    DataCite
    NLM
    DC