Dislocations in Solids, Volume 12
Elsevier, Aug 5, 2004 - Technology & Engineering - 602 pages
This is the first volume to appear under the joint editorship of J.P. Hirth and F.R.N. Nabarro. While Volume 11 concentrated on the single topic of dislocations and work hardening, the present volume spreads over the whole range of the study of dislocations from the application by Kléman and his colleagues of homotopy theory to classifying the line and point defects of mesomorphic phases to Chaudhri's account of the experimental observations of dislocations formed around indentations.
Chapter 64, by Cai, Bulatove, Chang, Li and Yip, discusses the influence of the structure of the core of a dislocation on its mobility. The power of modern computation allows this topic to be treated from the first principles of electron theory, and with empirical potentials for more complicated problems. Advances in electron microscopy allow these theoretical predictions to be tested.
In Chapter 65, Xu analyzes the emission of dislocations from the tip of a crack and its influence on the brittle to ductile transition. Again, the treatment is predominantly theoretical, but it is consistently related to the very practical example of alpha iron.
In a dazzling interplay of experiment and abstract mathematics, Kléman, Lavrentovich and Nastishin analyze the line and point structural defects of the many mesomorphic phases which have become known in recent years.
Chapter 67, by Coupeau, Girard and Rabier, is essentially experimental. It shows how the various modern techniques of scanning probe microscopy can be used to study dislocations and their interaction with the free surface.
Chapter 68, by Mitchell and Heuer, considers the complex dislocations that can form in ceramic crystals on the basis of observations by transmission electron microscopy and presents mechanistic models for the motion of the dislocations in various temperature regimes.
While the underlying aim of the study of dislocations in energetic crystals by Armstrong and Elban in Chapter 69 is to understand the role of dislocations in the process of detonation, it has the wider interest of studying dislocations in molecular crystals which are ``elastically soft, plastically hard, and brittle''.
Chaudhri in Chapter 70 discusses the role of dislocations in indentation processes, largely on the basis of the elastic analysis by E.H. Yoffe. The special case of nanoindentations is treated only briefly.
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Dislocations and Disclinations in Mesomorphic Phases
Scanning Probe Microscopy and Dislocations
Dislocations and Mechanical Properties of Ceramics
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activation energy atomistic atoms axis behaviour Burgers vector cathodoluminescence cation cholesteric cleavage configuration core structure crack front crack tip cross-slip curvature curve decomposition direction disclinations dislocation core dislocation density dislocation line dislocation loops dislocation mobility dislocation motion dislocation nucleation displacement dissociation edge dislocations elastic Elban electron etch pits experimental FCC metals FCD’s glide glide plane indenter load interaction kink kink-pair Kleman lattice layers Lett material mechanism microscopy molecules nematic observed oxides parameter Peierls stress phase Philos Phys pile-up plastic deformation point defects R.W. Armstrong rosette arms sample sapphire screw dislocations shear stress shown in Fig silicon simulations single crystals slip bands slip lines slip plane slip system smectic solid spinel stacking fault stacking fault energy strain surface symmetry temperature TGBA tion topological transition yield stress