• Title of article

    Nickel–carbon nanocomposites: Synthesis, structural changes and strengthening mechanisms Original Research Article

  • Author/Authors

    D. Nunes، نويسنده , , M. Vilarigues، نويسنده , , J.B. Correia، نويسنده , , P.A Carvalho، نويسنده ,

  • Issue Information
    دوهفته نامه با شماره پیاپی سال 2012
  • Pages
    11
  • From page
    737
  • To page
    747
  • Abstract
    The present work investigates Ni–nanodiamond and Ni–graphite composites produced by mechanical synthesis and subsequent heat treatments. Processing of nickel–carbon nanocomposites by this powder metallurgy route poses specific challenges, as carbon phases are prone to carbide conversion and amorphization. The processing window for carbide prevention has been established through X-ray diffraction by a systematic variation of the milling parameters. Transmission electron microscopy confirmed the absence of carbide and showed homogeneous particle distributions, as well as intimate bonding between the metallic matrix and the carbon phases. Ring diffraction patterns of chemically extracted carbon phases demonstrated that milled nanodiamond preserved crystallinity, while an essentially amorphous nature could be inferred for milled graphite. Raman spectra confirmed that nanodiamond particles remained largely unaffected by mechanical synthesis, whereas the bands of milled graphite were significantly changed into the typical amorphous carbon fingerprint. The results on the annealed nanocomposites showed that milling with Ni accelerated graphitization of the carbon phases during heat treatments at 973 and 1073 K in both composites. At the finer scales, the nanocomposites exhibited a remarkable microhardness enhancement (∼70%) compared with pure nanostructured nickel. The Hall–Petch relation and the Orowan–Ashby equation are used to discuss strengthening mechanisms and the load transfer ability to the reinforcing particles.
  • Keywords
    Nanodiamond , Hall–Petch relation , Mechanical synthesis , Nanocomposites , Carbide formation
  • Journal title
    ACTA Materialia
  • Serial Year
    2012
  • Journal title
    ACTA Materialia
  • Record number

    1146089