Difference between revisions of "Dilatant shear bands in solidifying metals"

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==Summary==
 
==Summary==
  
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[[Image:Nonlinear_2.jpg |right| |200px| |thumb| Figure 2.]]
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[[Image:dilatant_2.jpg |right| |200px| |thumb| Figure 2.]]
 
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The authors study the microstructure of partially solidified alloys under shear.  During the solidification of a metallic alloy, it has been shown that after nucleation, crystals are initially dispersed in the liquid and the material behaves as a suspension.  As the crystals grow, the volume fraction of solid, <math>f_s</math> increases, and at a critical value <math>f_s^{Coh}</math>, there is a sharp increase in viscosity due to the formation of a loose solid.  As the metal continues to solidify, partial cohesion between solids develops, allowing the solid to transmit shear, compressive, and tensile strains.  Although metals at high volume fraction have been studied extensively, metals at relatively low volume fractions (<math>f_s^{Coh} \leq f_s \leq 0.5</math>) have not.  This paper deals with dilatancy in solidifying metal alloys in this low volume fraction regime.
 
The authors study the microstructure of partially solidified alloys under shear.  During the solidification of a metallic alloy, it has been shown that after nucleation, crystals are initially dispersed in the liquid and the material behaves as a suspension.  As the crystals grow, the volume fraction of solid, <math>f_s</math> increases, and at a critical value <math>f_s^{Coh}</math>, there is a sharp increase in viscosity due to the formation of a loose solid.  As the metal continues to solidify, partial cohesion between solids develops, allowing the solid to transmit shear, compressive, and tensile strains.  Although metals at high volume fraction have been studied extensively, metals at relatively low volume fractions (<math>f_s^{Coh} \leq f_s \leq 0.5</math>) have not.  This paper deals with dilatancy in solidifying metal alloys in this low volume fraction regime.

Revision as of 22:09, 5 December 2009

Reference

Gourlay, C.M., Dahle, A.K., Nature 445 (2007).

Keywords

dilatancy, shear, granular media

Summary

Figure 1.
Figure 2.

The authors study the microstructure of partially solidified alloys under shear. During the solidification of a metallic alloy, it has been shown that after nucleation, crystals are initially dispersed in the liquid and the material behaves as a suspension. As the crystals grow, the volume fraction of solid, <math>f_s</math> increases, and at a critical value <math>f_s^{Coh}</math>, there is a sharp increase in viscosity due to the formation of a loose solid. As the metal continues to solidify, partial cohesion between solids develops, allowing the solid to transmit shear, compressive, and tensile strains. Although metals at high volume fraction have been studied extensively, metals at relatively low volume fractions (<math>f_s^{Coh} \leq f_s \leq 0.5</math>) have not. This paper deals with dilatancy in solidifying metal alloys in this low volume fraction regime.

In the main set of experiments, an Mg alloy was deformed during solidification using a four-bladed vane. Figure 1 shows the torque versus vane response; it shows an increase in torque to a peak value, then a sharp decrease, and finally deformation continues at a lower torque than the initial torque. Figure 2 is a macrograph of one-quarter of the cross-section of the sample, and it shows a porous band just outside the radius of the vane. The authors note that the torque-vane curve shown in Figure 1 and the shear band shown in Figure 2 are characteristic of compacted cohesionless granular material. Compacted granular materials exhibit Reynolds dilatancy - that is, they expand when sheared because particles must increase the space between themselves in order to rearrange.

It is thus shown that the solidifying alloy has a similar rheology to a cohesionless granular material. However, the similar rheology holds only in a certain range above the cohesion volume fraction. For the Mg alloy in the experiment, this range was <math>0.2<f_s<0.35</math>. This suggests that the models developed for granular materials can be applied to partially solid alloys. This is significant because understanding the mechanics and microstructure of solidifying alloys is essential to enhancing industrial casting processes.