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2 results

  • 13 - Solidification

  • from Part III - Types of Phase Transformations
  • Brent Fultz, California Institute of Technology
  • Book:
    Phase Transitions in Materials
    Published online:
    24 April 2020
    Print publication:
    14 May 2020, pp 342-372

  • Summary

    There is a marked kinetic asymmetry between melting and solidification -- the two are quite different as phase transformations. Solidification can occur by different mechanisms that create very different solid microstructures. This chapter emphasizes processes at the solid-liquid interface during solidification, and the microstructure and solute distributions in the newly formed solid. During solidification, a solid-liquid interface moves forward as the liquid is consumed, and the velocity of the interface increases with the rate of heat extraction. Instabilities set in even at relatively small velocity, however, and a flat interface evolves into finger-like columns or tree-like dendrites of growing solid. This instability is driven by the release of latent heat and the partitioning of solute atoms at the solid-liquid interface. Finger-like solids have more surface area, so countering the instability is surface energy. Solidification involves the evolution of several coupled fields. Crystallographic orientation of the growing solid phase is also important for the growth rate and surface energy.

  • Thermodynamic Evaluation of the Interface Stability Between Selected Metal Oxides and Co

  • Ying Yang, Peter F. Ladwig, Y. Austin Chang, Feng Liu, Bharat. B. Pant, Allan E. Schultz
  • Journal:
    Journal of Materials Research / Volume 19 / Issue 4 / April 2004
    Published online by Cambridge University Press:
    03 March 2011, pp. 1181-1186
    Print publication:
    April 2004

  • For an interface to be considered thermodynamically stable, the phases in contact must be in equilibrium with each other (connected by a stable tie-line) and have negligible mutual solubility on the phase diagram. The stability of Co based magnetic tunnel junctions (MTJs), with Co/MxO1-x/Co structures (M = Al, Gd, Hf, La, Mg, Si, Ti, Ta, Y and Zr), were evaluated with regard to these two conditions. Specifically, low temperature ternary isothermal phase diagrams were calculated and evaluated for the Co–M–O systems. All of these systems have at least one oxide in equilibrium with Co and thus have at least one thermodynamically stable tunnel barrier candidate for use in Co based MTJs. In light of the assumptions made in this analysis, along with the uncertainty in applying bulk enthalpy data to thin films, the current evaluation of interfacial stability serves as a first step in identifying suitable stable tunneling barrier materials in MTJs for detailed study.