Surfactant-free CuO nanoball-based nanolubricants: Experimental insights into dispersion stability, thermo-rheological properties and tribological behavior

IF 8.2 1区工程技术 Q1 ENGINEERING, MECHANICAL

Friction Pub Date : 2025-08-04 DOI:10.26599/frict.2025.9441155

Siraj Azam, Sang-Shin Park

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Abstract

This study presents a comprehensive investigation into the synthesis, dispersion behavior, and performance evaluation of surfactant-free copper oxide (CuO) nanoballs (NBs) dispersed in polyalphaolefin (PAO) oil. CuO NBs were synthesized via a modified precipitation technique and characterized using X-ray diffraction (XRD), Raman spectroscopy, Fourier-transform infrared (FTIR) spectroscopy, scanning electron microscopy (SEM), and transmission electron microscopy (TEM), confirming their monoclinic crystal structure and spherical morphology with particle sizes ranging from 25 to 132 nm. The dispersion quality and long-term stability of nanolubricants were assessed using UV–Vis spectroscopy and zeta potential analysis, which indicated that 0.01 wt% CuO achieved the highest stability (zeta potential: 154.3 mV) and minimal sedimentation up to 10 days. Rheological measurements showed Newtonian behavior across all concentrations, with the highest relative viscosity observed at 0.05 wt% and 100 °C. The viscosity index improved at lower concentrations, supporting the lubricant’s thermal adaptability under dynamic shear conditions. Thermal conductivity increased with CuO addition, peaking at 0.01 wt%, primarily due to enhanced Brownian motion and reduced nanoparticle agglomeration. Tribological performance, evaluated using a reciprocating tribometer under a 10 N load and 840 m stroke length, revealed that 0.01 wt% CuO achieved a 37% reduction in the coefficient of friction (COF) (0.055) and the lowest specific wear rate among all tested samples. Surface analysis via 3D profilometry and SEM/EDS revealed smoother contact surfaces and no evidence of CuO deposition, suggesting a rolling friction mechanism as the dominant lubrication mode. These findings confirm that surfactant-free CuO NBs significantly enhance the tribological, rheological, and thermal properties of PAO oil, offering a cost-effective and environmentally friendly solution for high-performance industrial lubrication systems.

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无表面活性剂的CuO纳米球基纳米润滑剂：分散稳定性、热流变特性和摩擦学行为的实验见解

研究了分散在聚α -烯烃（PAO）油中的无表面活性剂氧化铜（CuO）纳米球（NBs）的合成、分散行为和性能评价。采用改进的沉淀法合成了CuO NBs，并利用x射线衍射（XRD）、拉曼光谱（Raman spectroscopy）、傅里叶变换红外光谱（FTIR）、扫描电镜（SEM）和透射电镜（TEM）对其进行了表征，证实了其单斜晶型结构和球形形貌，粒径范围为25 ~ 132 nm。利用紫外可见光谱和zeta电位分析对纳米润滑剂的分散质量和长期稳定性进行了评估，结果表明0.01 wt%的CuO具有最高的稳定性（zeta电位：154.3 mV）和最小的沉淀长达10天。流变学测量在所有浓度下都显示出牛顿行为，在0.05 wt%和100 °C时观察到最高的相对粘度。在较低的浓度下，粘度指数有所提高，支持了润滑油在动态剪切条件下的热适应性。导热系数随着CuO的加入而增加，在0.01 wt%时达到峰值，主要是由于布朗运动增强和纳米颗粒团聚减少。在10 N载荷和840 m行程长度下，使用往动式摩擦计对摩擦性能进行了评估，结果显示，0.01 wt% CuO可使摩擦系数（COF）降低37%(0.055)，并且是所有测试样品中比磨损率最低的。通过三维轮廓仪和SEM/EDS对表面进行分析，发现接触面更光滑，没有CuO沉积的证据，表明滚动摩擦机制是主要的润滑模式。这些研究结果证实，不含表面活性剂的CuO NBs显著提高了PAO油的摩擦学、流变学和热性能，为高性能工业润滑系统提供了一种经济、环保的解决方案。

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来源期刊

Friction Engineering-Mechanical Engineering

CiteScore

12.90

自引率

13.20%

发文量

324

审稿时长

13 weeks

期刊介绍： Friction is a peer-reviewed international journal for the publication of theoretical and experimental research works related to the friction, lubrication and wear. Original, high quality research papers and review articles on all aspects of tribology are welcome, including, but are not limited to, a variety of topics, such as: Friction: Origin of friction, Friction theories, New phenomena of friction, Nano-friction, Ultra-low friction, Molecular friction, Ultra-high friction, Friction at high speed, Friction at high temperature or low temperature, Friction at solid/liquid interfaces, Bio-friction, Adhesion, etc. Lubrication: Superlubricity, Green lubricants, Nano-lubrication, Boundary lubrication, Thin film lubrication, Elastohydrodynamic lubrication, Mixed lubrication, New lubricants, New additives, Gas lubrication, Solid lubrication, etc. Wear: Wear materials, Wear mechanism, Wear models, Wear in severe conditions, Wear measurement, Wear monitoring, etc. Surface Engineering: Surface texturing, Molecular films, Surface coatings, Surface modification, Bionic surfaces, etc. Basic Sciences: Tribology system, Principles of tribology, Thermodynamics of tribo-systems, Micro-fluidics, Thermal stability of tribo-systems, etc. Friction is an open access journal. It is published quarterly by Tsinghua University Press and Springer, and sponsored by the State Key Laboratory of Tribology (TsinghuaUniversity) and the Tribology Institute of Chinese Mechanical Engineering Society.