4.7 Article

Research on tribological behavior of graphene with in-situ MgO nanoparticles reinforced AZ91 alloy composite

期刊

COMPOSITES COMMUNICATIONS
卷 30, 期 -, 页码 -

出版社

ELSEVIER SCI LTD
DOI: 10.1016/j.coco.2022.101086

关键词

Magnesium-coated graphene; Nanocomposites; Wear mechanism

资金

  1. National Defense Foundation of China [61400040208]
  2. China Postdoctoral Science Foundation [2019M661068]
  3. Key Research and Development Project of Shanxi Province [201903D121009]
  4. Natural Science Foundation of Shanxi Province [201801D221154]
  5. Major Science and Technology Projects of Shanxi Province, China [20181102012]

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Magnesium-coated graphene with improved wettability and dispersion was successfully prepared using a novel organic chemical reduction method. The graphene was uniformly distributed in the matrix, and a finer and more dispersed strengthening phase was observed around it. In addition, MgO nanoparticles were formed on the surface of graphene, enhancing the wear resistance of the composites through nano-scale contact and tight interfacial bonding with the substrate.
Magnesium-coated graphene (GNPs) was successfully prepared by a novel organic chemical reduction method with significantly improved wettability and dispersion. The GNPs were uniformly distributed in the matrix, while a finer and more dispersed strengthening phase beta-Mg17Al12 was precipitated around it. Moreover, MgO nano particles were formed by in-situ reaction on the surface of GNPs, forming nano-scale contact and tight interfacial bonding with the substrate, thereby significantly improving the wear resistance of the composites. The wear mechanism has also changed from severe delamination and abrasive wear to mixed wear of slight delamination, adhesion, and oxidation. The increase in wear resistance is attributed to the combined effect of the lubrication and load transfer of GNPs, the enhanced effect of fine precipitates on the mechanical properties of the matrix, and the synergistic effect of in situ generated MgO nanoparticles against deformation.

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