• Title of article

    Laboratory micro- and nanoscale X-ray tomographic investigation of Al–7 at.%Cu solidification structures

  • Author/Authors

    Patterson، نويسنده , , B.M. and Henderson، نويسنده , , K.C. and Gibbs، نويسنده , , P.J. and Imhoff، نويسنده , , S.D. and Clarke، نويسنده , , A.J.، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2014
  • Pages
    9
  • From page
    18
  • To page
    26
  • Abstract
    X-ray computed tomography across multiple length scales provides an opportunity to non-destructively visualize and quantify the micro- to nano-scale microstructural features of solidification structures in three dimensions. Aluminum–7 at.%copper samples were directionally solidified at three cooling rates (0.44, 0.67, and 1.33 °C/s), resulting in systematic changes in the as-solidified microstructure, which are difficult to quantify using traditional microscopic techniques. The cooling rate of a material affects its ultimate microstructure, and characterizing that microstructure is key to predicting and understanding its bulk properties. Here, two different laboratory X-ray computed tomography instruments were used to characterize as-solidified microstructures, including micro-scale computed tomography with approximately 1 mm field-of-view, ~ 1.7 μm resolution, and nano-scale X-ray computed tomography ~ 65 μm FOV, 150 nm resolution. Micro-scale X-ray radiography and computed tomography enabled a quantitative investigation of changes in the primary dendritic solidification structure with increasing cooling rate. Nano-scale absorption contrast X-ray computed tomography resolved the distinct phases of the lamellar eutectic structure and three dimensional measurements of the ~ 1 μm interlamellar spacing. It is found that the lamella eutectic structure thickness is inversely proportional to the cooling rate. Nano-scale Zernike phase contrast was also used to image voids at eutectic colony boundaries. The application and resolution of these two instruments are discussed with respect to the resolvable features of the solidification structures.
  • Keywords
    aluminum , Copper , Eutectic , X-ray tomography , solidification
  • Journal title
    Materials Characterization
  • Serial Year
    2014
  • Journal title
    Materials Characterization
  • Record number

    2269539