Boundary lubrication by adsorption film

Self Cite

With the development of surface and interface science and technology, methods for the online modulation of interfacial performance by external stimuli are in high demand. Switching between ultra-low and high friction states is a particular goal owing to its applicability to the development of precision machines and nano/micro-electromechanical systems. In this study, reversible switching between superlubricity and high friction is realized by controlling the electric potential of a gold surface in aqueous salt solution sliding against a SiO 2 microsphere. Applying positive potential results creates an ice-like water layer with high hydrogen bonding and adhesion at the interface, leading to nonlinear high friction. However, applying negative potential results in free water on the gold surface and negligible adhesion at the interface, causing linear ultra-low friction (friction coefficient of about 0.004, superlubricity state). A quantitative description of how the external load and interfacial adhesion affected friction force was developed, which agrees well with the experimental results. Thus, this work quantitatively reveals the mechanism of potential-controlled switching between superlubricity and high-friction states. Controlling the interfacial behavior via the electric potential could inspire novel design strategies for nano/micro-electromechanical and nano/micro-fluidic systems.

Section: Introductionmentioning

confidence: 99%

Quantification/mechanism of interfacial interaction modulated by electric potential in aqueous salt solution

Bai

et al. 2020

Self Cite

“…For instance, when the dependence of the kinetic friction coefficient on the relative velocity (μ-v curve) is negative, steady sliding at the equilibrium point becomes unstable, and the instability generates shudder [2]. Stick-slip is another type of shudder that results from the discontinuity between static and kinetic friction; stick-slip can arise when the static friction is higher than the dynamic friction [3,4]. The tendencies of a wet clutch to experience both stick-slip and shudder are usually characterized by the μ-v curve.…”

Section: Introductionmentioning

confidence: 99%

Investigation of calcium phosphate (CaP) tribofilms from commercial automatic transmission fluids (ATFs) and their correlation with antishudder performance

Di¹,

Xu²,

Liu³

et al. 2019

The friction properties of wet clutches are highly dependent on the surface tribofilms formed by automatic transmission fluids (ATFs). Here, four commercial ATFs were evaluated with a disc-on-disc tribometer to study tribofilm formation on steel surfaces and the effects of tribofilms on the friction properties. The chemical composition, stoichiometry, structure, and thickness of the tribofilms were investigated by scanning electron microscopy (SEM), energy dispersive X-ray spectrometry (EDX), secondary ion mass spectrometry (SIMS), and X-ray photoelectron spectroscopy (XPS). Calcium phosphate (CaP) tribofilms form on the friction surface with all ATFs, which contributes to their antishudder characteristics. The thickness and surface coverage of CaP tribofilms are positively correlated with their antishudder properties.

“…For a thick film, the contact surfaces are separated completely by a fluid layer, which makes the ordered layers less important and leads to a lubrication regime that shows EHL behavior [4,5]. When the thickness of a film is decreased to a few nanometers, the fluid layer and ordered layers are destroyed, only the adsorbed layers (or tribochemical layers) function between the contact surfaces, and BL [6] is established there. Clearly, a transition regime is expected between EHL and BL, where the fluid layer, ordered layers, and adsorbed layers (or tribochemical layers) coexist and function to reduce the friction.…”

Section: Introductionmentioning

confidence: 99%

Molecular behaviors in thin film lubrication—Part three: Superlubricity attained by polar and nonpolar molecules

Halmans

2018

In thin-film lubrication (TFL), generally, the viscosity of the lubricant and its coefficient of friction (CoF) increase. Finding a method to reduce the CoF in TFL is a significant challenge for tribologists. In the present work, we report a robust superlubricity attained by using polyalkylene glycols (PAGs, polar molecules) and poly-α-olefins (PAOs, nonpolar molecules) as lubricants on steel/steel friction pairs that have been pre-treated by wearing-in with polyethylene glycol aqueous solution (PEG(aq)). A steady superlubricity state with a CoF of 0.0045 for PAG100 and 0.006 for PAO6 could be maintained for at least 1 h. Various affecting factors, including the sliding velocity, normal load, and viscosity of the lubricants, were investigated. Element analysis proved that composite tribochemical layers were deposited on the worn region after the treatment with PEG(aq). These layers were formed by the tribochemical reactions between PEG and steel and composed of various substances including oxides, iron oxides, FeOOH, and Fe(OH) 3 , which contributed to the superlubricity. In addition to the tribochemical layers, ordered layers and a fluid layer were formed by the PAGs and PAOs during the superlubricity periods. All the three types of layers contributed to the superlubricity, indicating that it was attained in the TFL regime. Accordingly, a mechanism was proposed for the superlubricity of the PAGs and PAOs in the TFL regime in this work. This study will increase the scientific understanding of the superlubricity in the TFL regime and reveal, in the future, the potential for designing superlubricity systems on steel surfaces for industrial applications.