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Dissemination of IT for the Promotion of Materials Science (DoITPoMS) About DoITPoMS Events Mailing List Contact Us Micrograph Library Teaching and Learning Packages Community (login required) Integrating e-Learning into Materials Education This Workshop, scheduled for 23 June 2004 in Liverpool, is being rescheduled for Easter 2005. Further information © University of Cambridge DoITPoMS, Department of Materials Science and Metallurgy, University of Cambridge http://www.doitpoms.ac.uk/index.html Phase diagrams and solidification http://www.doitpoms.ac.uk/tlplib/phase-diagrams/index.php Solid Solutions http://www.doitpoms.ac.uk/tlplib/solid-solutions/index.php Exsolution in phase diagrams A binary solid solution can show a phase diagram as follows: liquidus solidus The solidus and liquidus separate the single phase regions. This is similar to the Cu-Ni phase diagram. If the system demonstrates exsolution, then there will be a region in the solid state where two solid phases form from the solid solution. This is common and most solid solutions demonstrate it to some degree. Miscibility gap In a eutectic phase diagram, the two-phase solid region meets the solidus/liquidus. Solid solution regions are usually denoted with Greek letters, for example for ferritic iron and for austenitic iron. Demonstration of phase separation The transition from a single phase to two phases (and vice-versa) can be easily demonstrated using a mixture of two suitable liquids. A mixture of cyclohexane and aniline can exist as two separate phases or as a single phase, depending on the temperature. The thermodynamic transition between these two states can be understood by considering the balance between entropy and enthalpy (see Thermodynamics section in this TLP). Aniline and cyclohexane are immiscible over a wide range of compositions below about 35 ºC. In this immiscible region there exists an aniline-rich and a cyclohexane-rich phase, separated by a boundary, seen as a meniscus. When this mixture is heated, the volume of one phase increases at the expense of the other. This can be seen as movement of the meniscus, provided the heating is slow enough. At the transition temperature for the particular composition, there will no longer be two discernable phases. A significant point occurs when the distinction between the two coexisting phases reduces to zero. Here the domains present in the mixture can switch easily between aniline-rich and cyclohexanerich. The composition variance is on such a scale as to interfere with light passing through it. Light will scatter in proportion to the squared difference in n, the index of refraction, of the two phases. Therefore light scatters more as the number of domain interfaces increases. Hence light is scattered strongly by the mixture across a small temperature range around the transition temperature. At the critical point, the scattering is so intense that the system becomes opaque. This phenomenon is called critical opalescence. The domains demonstrate some interesting properties, such as fractal shapes, and there is a peak in the heat capacity. This critical transition temperature is a maximum with respect to the composition. Thus it can be determined by interpolating transition temperatures from known compositions. Demonstration A mixture of equal quantities of cyclohexane and aniline contained in a sealed vial is heated to approximately 35 ºC (i.e. just above the critical temperature), using a water bath (or water from a hot tap). The mixture is allowed to cool, and a laser is pointed at the vial so that it shines onto a screen opposite, as shown in the diagram below. When the critical temperature is reached and the mixture goes from a single phase to two phases, the spot of light on the screen is disrupted as the phases separate. The spot ‘flickers' and then becomes totally diffuse. It will eventually form a single spot again once the transition is completed and the two chemicals have completely separated. The pattern of events can also be seen in reverse as the mixture is heated. View video showing the laser light (as seen on the screen) flickering and spreading out to become completely opaque as the mixture cools through the transition temperature (1.2 MB) ... in separate window ... video alone The video has been speeded up by a factor of about 10. View video showing the vial, which has been filmed perpendicular to the direction of the laser light (left to right) (920 KB) ... in separate window ... video alone Initially, the laser light is seen as a single beam passing through the mixture, but as the transition point is reached, the beam spreads out. The single beam eventually reforms, once the transition is complete. This video has been speeded up by a factor of about 200. Precipitates from solid solution The precipitation of a solid phase from a liquid matrix is governed by a balance between the thermodynamic driving force and the energy penalty for creating new solid-liquid surface interfaces. This determines the size and shape of the precipitates. The precipitation of a solid phase from a solid parent phase is very similar. There are various types of interface between solid phases: a. Coherent - there is perfect registry of the lattices. b. Coherent with strain - it is quite likely for there to be some strain with the interface, due to imperfect matching. The strain energy increases with the size of the growing particle, and there is a transition to a semi-coherent interface. c. Semi-coherent interface - the introduction of dislocations reduces the strain energy (but they themselves contribute to the energy of the system). d. Incoherent - there is no matching of the interface. Coherent Coherent with strain Semi-coherent Incoherent In general, the interfacial free energy will be minimised with better matching of the two phases. Incoherent interfaces have high energy and are relatively mobile because of the greater freedom of atomic motion. The stresses present in the parent matrix as the precipitate grows strongly influences the shape of the precipitate. By modelling the precipitate as an ellipsoid of revolution, the following graph shows how the strain energy is related to the shape. Growth as discs or plates is clearly preferred. A precipitate particle will likely have some coherent and some incoherent interfaces with the matrix. The greater mobility of the incoherent interfaces leads to faster growth in these directions. This anisotropic growth leads to plate and disc morphologies. The bounding coherent interfaces will be parallel to crystallographic planes in the matrix. Solid solution precipitation/exsolution is used to strengthen many alloys. This is known as precipitation hardening , or age hardening. It involves quenching an alloy to a supersaturated state (where the amount of dissolved solute is greater than the equilibrium amount predicted by the phase diagram). A heating schedule can then be applied to control the nature of the precipitation. For example in Al-Cu, a very fine dispersion of q particles hardens the a phase. This age-hardened alloy is used in aerospace applications. View micrograph of a precipitation hardened sample of Al-Cu At lower temperatures, it is preferable to have incoherent precipitates, as the greater strains produce more resistance on dislocation motion. At higher temperatures however, the greater mobililty of the incoherent interfaces allows larger particles to grow at the expense of smaller ones (called coarsening), and the system becomes less effective at strengthening. So for high temperature use, coherent particles are used, such as the g' precipitate in nickel-based superalloys (here a phenomenon called order hardening provides the strengthening mechanism, rather than the strain fields). View micrograph of an order hardened sample of Nickel superalloy Ceramics, which are typically brittle, can also benefit from solid solution precipitation. Zirconia based compounds can be toughened by having tetragonal structure particles in the monoclinic matrix. Propagation of cracks through the zirconia requires the transformation of these precipitates to the monoclinic form. This requires an input of energy, provided by the stress, hence the material is toughened. Another use of solid solution precipitation lies in nano-materials. By precipitating from a solid solution, the nanometre (10-9 m) scale of the microstructure can provide many beneficial effects. For example, the presence of 5 nm diameter carbide particles in steel piano wires helps make it the world's strongest structural material (with some ductility). Precipitation from a liquid phase is too fast to produce such small scale particles.