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Open Access Research Article Just Accepted
Slippery liquid-infused porous surface with layered double hydroxides for enhanced corrosion and wear resistance of TC4 alloys
Friction
Available online: 14 November 2025
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The poor wear performance and susceptibility to pitting corrosion of titanium alloys in practical applications have attracted increasing attention. Layered double hydroxides (LDH) coatings, with two-dimensional structure, have shown great potential in protecting metals from corrosion and wear. However, the dense oxide layer on titanium alloys has hindered the development of LDH on these materials. In this study, a ZnAl LDH coating was fabricated on the surface of TC4 alloy via an in situ growth method. Molybdic acid anions were subsequently incorporated into the LDH interlayer through an ion exchange process. Inspired by biomimetic principles, a UV-grafted PDMS-infused slippery surface was prepared based on the nanoporous structure of ZnAl LDH, resulting in a protective surface with excellent hydrophobicity, corrosion resistance, and wear resistance. The anti-corrosion performance of the surface was evaluated using Tafel polarization and electrochemical impedance spectroscopy (EIS). The results demonstrated excellent corrosion protection for the TC4 substrate, as indicated by a low corrosion current density of 2.34 × 10-7 A/cm². Compared with the bare TC4 alloy, the modified surface exhibited improved improved wear performance, owing to the infused silicone oil and ZnAl LDH nanosheets. This work not only provides valuable insights into the controllable in situ fabrication of LDH coatings but also offers a new strategy for the broader application of TC4 alloys and further research in the field of metal protection.

Open Access Research Article Issue
A robust membrane with dual superlyophobicity for solving water-caused lubricant deterioration and water contamination
Friction 2023, 11(8): 1442-1454
Published: 17 January 2023
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Downloads:68

Lubricants are often contaminated by water in different ways. Water-polluted lubricants extremely accelerate wear corrosion, leading to the deterioration of lubricity performance. Recently, multiphase media superwettability has been developed to endow one surface with compatible functions, such as on-demand separation of oily wastewater. However, realizing the robustness of the dual superlyophobic surface to solve water-caused lubricant deterioration and water contamination as needed remains challenges. Herein, a robust dual superlyophobic membrane is presented to realize on-demand separation for various lubricant–water emulsions. Compared to pure lubricants, the purified lubricants have equivalent tribology performance, which are much better than that of water-polluted lubricants. The as-prepared membrane maintains dual superlyophobicity, high-efficient for water or lubricant purification, and excellent tribology performance of the purified lubricant, even after immersion in hot liquids for 24 h, multicycle separation, and sandpaper abrasion for 50 cycles. Water-polluted lubricant extremely accelerates wear corrosion to promote catalytic dehydrogenation of lubricants, generating too much harmful carbon-based debris. This work shows great guiding significance for recovering the tribology performance of water-polluted lubricants and purifying water by the dual superlyophobic membrane.

Open Access Research Article Issue
Electron transfer dominated triboelectrification at the hydrophobic/slippery substrate–water interfaces
Friction 2023, 11(6): 1040-1056
Published: 08 July 2022
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Downloads:56

Triboelectric nanogenerator (TENG) based on triboelectrification has attracted wide attention due to its effective utilization of green energy sources such as marine energy. However, researches about liquid–liquid triboelectrification are still scanty as solid–liquid triboelectrification has been widely studied. Herein, this work focuses on the hydrophobic/slippery substrate–water interfacial triboelectrification based on the solid friction materials of polytetrafluoroethylene (PTFE) nanoparticles. The hydrophobic/slippery substrate–water interfacial triboelectrification are studied by assembling PTFE coated Al sheets and perfluoropolyether (PFPE) infused PTFE coated Al sheets (formed the slippery lubricant-infused surfaces (SLIPSs)) as the friction electrode, and water as liquid friction materials, respectively. The results show that the hydrophobic TENG output performances improved as the PTFE nanoparticles cumulating, and the SLIPSs TENG output performances increased with the thinner PFPE thickness. Both the triboelectrification behavior of hydrophobic/SLIPSs TENG assembled in this work are dominated by the electron transfer. Thanks to the introduction of SLIPSs, the SLIPSs TENG exhibits superior stability and durability than the hydrophobic TENG. The investigation of hydrophobic/slippery substrate–water interfacial triboelectrification contributes to optimize the TENG performances, and expands the application in harsh environments including low temperature and high humidity on the ocean.

Open Access Research Article Issue
Lubricant self-replenishing slippery surface with prolonged service life for fog harvesting
Friction 2022, 10(10): 1676-1692
Published: 04 September 2021
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Downloads:50

Slippery lubricant-infused surfaces exhibit excellent fog-harvesting capacities compared with superhydrophobic and superhydrophilic surfaces. However, lubricant depletion is typically unavoidable under dynamic conditions, and reinfused oil is generally needed to recover the fog-harvesting capacity. Herein, an effective strategy for delaying the depletion of lubricant to prolong the service life of fog harvesting is proposed. An ultrathin transparent lubricant self-replenishing slippery surface was fabricated via facile one-step solvent evaporation polymerization. The gel film of the lubricant self-replenishing slippery surface, which was embedded with oil microdroplets, was attached to glass slides via the phase separation and evaporation of tetrahydrofuran. The gel film GFs-150 (with oil content 150 wt% of aminopropyl-terminated polydimethyl siloxane (PDMS–NH2)) exhibited superior slippery and fog-harvesting performance to other gel films. Furthermore, the slippery surfaces with the trait of oil secretion triggered by mechanical stress exhibited better fog-harvesting capabilities and longer service life than surfaces without the function of lubricant self-replenishment. The lubricant self-replenishing, ultrathin, and transparent slippery surfaces reported herein have considerable potential for applications involving narrow spaces, visualization, long service life, etc.

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