Tribological self-repairing behavior in ATP/Al composites: An orthogonal experimental study on attapulgite mineral effects

Tribological self-repairing behavior in ATP/Al composites: An orthogonal experimental study on attapulgite mineral effects

The introduction of self-repairing functional materials effectively improves the tribological properties of metals by in-situ repairing of micro-damage on worn surfaces during friction. In this work, attapulgite (ATP)-reinforced Al matrix composites (ATP/Al) were fabricated via spark plasma sinterin...

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Bibliographic Details
Main Authors: Z. Yang, Z.G. Xing, H.L. Yu, G. Jin, Y.L. Yin, Z.Y. Song, X.F. Cui, W. Zheng, J.T. Gong, F.Y. Zhang
Format: Article
Language:English
Published: Elsevier 2025-07-01
Series:Journal of Materials Research and Technology
Subjects:
Attapulgite
Aluminum matrix composites
Wear
Self-repairing
Tribological behavior
Online Access:http://www.sciencedirect.com/science/article/pii/S2238785425015960
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Summary:The introduction of self-repairing functional materials effectively improves the tribological properties of metals by in-situ repairing of micro-damage on worn surfaces during friction. In this work, attapulgite (ATP)-reinforced Al matrix composites (ATP/Al) were fabricated via spark plasma sintering (SPS) using natural ATP minerals and Al powder as raw materials. The tribological performance of ATP/Al-steel sliding pairs under oil-lubricated conditions was investigated using a three-level four-factor orthogonal experimental design on an SRV-IV tribometer. Comparative analysis revealed that the composite materials exhibited reductions of 15.38–66.87 % in friction coefficient, 21.6–54.68 % in wear volume, and 10.5–39.71 % in counterpart steel ball wear scar diameter compared to pure Al sintered counterparts. The order of importance that affected the friction-reducing performance of the composites was load, ATP content, sliding time, and frequency, whereas the order of the anti-wear property was sliding duration, ATP content, load, and frequency. The frictional mechanochemical effect induces the in-situ construction of a self-repairing layer, composed of binary and ternary metal oxides, ceramics, ATP phase transformation products, and graphite, on the worn surface. The in situ formed self-repairing layer exhibits dual functionality: (1) high hardness ensuring mechanical durability, and (2) shear-induced graphitization providing solid lubricity, synergistically reducing friction and wear across sliding interfaces.
ISSN:2238-7854

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