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11	Macroscopic dislocation modelling Tighe, Stephen Patrick January 1992 (has links) Work-hardened metals typically possess large numbers of dislocations in complex three-dimensional configurations about which little is known theoretically. Here these large numbers of dislocations are accounted for by means of a dislocation density tensor, which is obtained by applying an averaging process to families of discrete dislocations. Some simple continuous distributions are examined and an analogy is drawn with solenoids in electromagnetism before the question of the equilibrium of dislocation configurations is studied. It is then proved that the only finite, simply-connected distribution of dislocations in equilibrium in the absence of applied stresses are ones in which all components of stress vanish everywhere. Some examples of these zero stress everywhere (ZSE) distributions are then given, and the concept of 'plastic distortion' is used to facilitate their interpretation as rotations of the crystal lattice. Plastic distortion can also be understood as a distribution of infinitesimal dislocation loops ('Kroupa loops'), and this idea is used in Chapter 4 to investigate the dislocation distributions which correspond to elastic inclusions. The evolution, under an applied stress, of some simple ZSEs is analysed, and the idea of 'polarisation' is introduced, again in analogy with electromagnetism. Finally, a mechanism is conjectured for the onset of plastic flow. 519
12	Visualization and simulation of defect structures in the B2 phase of NiAl / Ternes, J. Kevin, January 1994 (has links) Thesis (M.S.)--Virginia Polytechnic Institute and State University, 1994. / Vita. Abstract. Includes bibliographical references (leaves 116-119). Also available via the Internet.
13	Characterization of dislocation structures and their influence on processing of al alloys Trivedi, Pankaj, January 2005 (has links) (PDF) Thesis (Ph.D.)--Washington State University. / Includes bibliographical references.
14	Effect of solute on dislocation distribution and twin frequency of austenitic stainless steels Fawley, Robert William, January 1966 (has links) Thesis (M.S.)--University of Wisconsin--Madison, 1966. / eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.
15	Size effects and deformation mechanisms in nanoscale metallic multilayered composites Akasheh, Firas, January 2007 (has links) (PDF) Thesis (Ph. D.)--Washington State University, May 2007. / Includes bibliographical references (p. 130-136).
16	Deformation of alpha-uranium. St. John, Charles Falding January 1964 (has links) An investigation as to the characteristics of flow and fracture for alpha-uranium were carried out over the temperature range -196°C to 270°C. The parameters relevant to grain size and strain rate were investigated. It was established that the flow stress and the fracture stress in the semi-brittle region vary linearly with the grain size parameter (1/D½). Evidence suggests that the sensitivity of flow stress to grain size is directly related to the importance of glide dislocation action as the deformation mode. Strain rate change irreversibility was found to exist at low strains for all temperatures investigated. This evidence, correlated with the effect of grain size, indicates that massive structural changes occur in the early stages of flow. This agrees with electron transmission microscopy results as established by other workers. / Applied Science, Faculty of / Materials Engineering, Department of / Graduate Uranium Dislocations in metals Dislocations in crystals
17	Grain boundary relaxation in four high purity, face-centered cubic metals / Cordea, James Nicholas January 1965 (has links) No description available. Engineering Metal crystals Dislocations in metals
18	The mechanical behavior of electrochemically polarized nickel single crystals / Latanision, R. M. January 1968 (has links) No description available. Engineering Nickel Deformations Dislocations in metals
19	Computer simulations of elastically strained surfaces and grain boundaries in bcc crystals / Price, Clifford Warren January 1975 (has links) No description available. Engineering Surface energy Dislocations in metals
20	Properties of low dislocation density metal crystals Buckley-Golder, I. M. January 1977 (has links) This thesis describes the growth, X-ray diffraction assessment and tensile deformation properties of dislocation-free copper single crystals. As such it has been possible to conveniently section the work carried out into these three main areas within this thesis. Consequently, each chapter may be read almost independently of the others with references and further work suggestions being incorporated at the end of each chapter. This format, it is felt, does not disjoint the work: rather, it enables the central theme (i.e. the title of this thesis) to be developed in a much more continuously clear way than is normally apparent in a thesis where conclusions, further work suggestions and references are not drawn together until the end of the volume. Chapter I opens with a brief outline of the crystal growth methods which could have been used to produce low dislocation density (< 10<sup>6</sup> cm/cm<sup>3</sup>) crystals by utilising the three fundamental phase transitions, i.e. solid to solid, vapour to solid and liquid to solid. The Czochralski method is then discussed in detail since it was used by the author to produce dislocation-free copper single crystals. The technological problems in obtaining such crystals are extensively enumerated and solutions presented. For instance, melt surface vibrations were eliminated by using a continuous flow of cooling water, by standing the complete crystal puller on a bed of foam, and by rigidly clamping the R.F. coil. It is emphasised that these technological problems must be solved before the scientific aspects of the growth of dislocation-free crystals can be studied. It is further shown that the author's modified crystal growing technique can be reliably used to grow dislocation-free crystals of copper each time, providing adequate care is taken over growth rates (1.2 cm/hr); specimen shape (a long thin "double-neck" must precede the required crystal to eliminate dislocations propagating from the seed and to act as a heat flow resistance); and crystal cooling rates (a long "tail" allowed the crystal to reach the ambient temperature slowly thereby minimising dislocation by thermal stresses and/or vacancy condensation). In the future, it is suggested, an automated crystal pulling system would be advantageous and a study of crystal growth in a synchrotron X-ray beam could be potentially definitive experiment on crystal growth. Chapter II looks at the theoretical aspects of Czochralski crystal growth with the aid of a new model which has been analysed on the Oxford University Computer. The model assumes a crystal-neck-seed configuration to be "sitting" on a liquid and examines the influence of geometric changes of the seed-neck-crystal and of radiation changes on the temperature gradients, primarily at the growth front. Four elements were chosen for study in this way: Si, Ge, Ag, Cu, i.e. four elements which have been grown dislocation-free. It was found that the seed size and shape played a small part in determining the interfacial temperature gradients, DT<sub>c</sub>(0), of all the elements. The neck, however, could have a marked influence on DT<sub>c</sub>(0) values in metals but not so much in semiconductor crystals. By geometric control alone it was found that the best way to reduce DT<sub>c</sub>(0) values was to grow a large diameter crystal. The influence of radiation losses was found to be marked for semiconductor crystals but not for metal crystals. Finally, it is concluded that to minimise DT<sub>c</sub>(0) values then the seed and neck must be long and thin and the crystal fat. These results fit in well with experimental knowledge. Further work to be carried out could consider the influence of a varying ambient temperature and convective heat losses on the interfacial temperature gradients. Chapter III is concerned with the interaction of X-rays with perfect crystals. The Lang-Borrmann X-ray topography technique is examined, and the experimental methods used to obtain X-ray topographs taken throughout this work are discussed. The major part of the chapter takes up the discussion of the theoretical interaction of X-rays with a perfect crystal set to diffract such X-rays. It is demonstrated that for a plane-wave incident on a cylindrical crystal, for the boundary condition to be satisfied the dispersion surface tie-points are displaced as the crystal traverses the incident X-ray beam. Thus the crystal wave-vectors no longer exactly satisfy the Bragg condition. This effect, was never unambiguously monitored experimentally because of the incident beam divergence. It is suggested that a future study could consider this problem in more detail. The Takagi-Taupin-Uragami generalised X-ray diffraction theory is reviewed and then used to calculate the intensity in the diffracted beam of a traverse topograph from a perfect cylindrical copper crystal. This computer simulation is also compared to an experimental condition. In both cases it is found that the Bragg surface of the crystal produces a very intense reflection whilst the remainder of the crystal gives a much reduced diffracted intensity in comparison. This asymmetric profile is interpreted in terms of absorption mechanisms which are strong at the centre of the crystal but not at the surface. The general agreement between theory and experiment is considered to be good although a few discrepancies arose, e.g. the lateral extent of the Bragg surface peak was found to be larger for the experiment than for the theory. Continued research in this area must explore further these small discrepancies; and it is suggested that a possible line of future study would be to examine theoretically and experimentally the X-ray diffraction from dislocation-free cylindrical crystals which possess low absorption coefficients (e.g. aluminium, silicon) for harder radiations (e.g. M<sub>oK<sub>1</sub></sub>, Ag<sub>K<sub>1</sub></sub>). It should then be possible to produce interference fringes and then it should be possible to examine the effects of a strain gradient on fringe spacing and visibility. Chapter IV sets out to discuss the tensile deformation behaviour of [1-2-3] growth axis, dislocation-free, chromium plated copper single crystals. This is done using the results from two sets of coupled experiments: an Instron deformation study and a synchrotron deformation investigation. It is first shown that chromium plating can destroy the perfection of the crystal unless care is exercised over plating temperatures and times. It was finally found that after plating for 10 seconds at 55C (1 μm of Cr deposited) that there was no indication of lattice dislocation. The stress-strain curve of a chromium plated dislocation-free copper crystal (Cr thickness 1 μm) is shown to exhibit a yield point commensurate with that for a non-plated, dislocation-free copper crystal, i.e. 90 g/mm<sup>2</sup>. The work hardening curve is shown to be comprised of three distinct regions: an initial rapid work hardening rate; a transitionary work hardening rate; and a stabilised work hardening rate up to a shear strain of 6%. In straining the crystal through these regions the work hardening rate progressively decreased. For a plated crystal which is dislocation-free initially it is shown that serrations in the flow curve occur, whilst for all other crystals these are shown to be absent. Such serrations are argued to occur by a source suppression and new source operation mechanism during the early deformation stages (1% shear strain), and then by a crack formation mechanism at the copper-chromium interface during the later stages of deformation. The initial work hardening rates (18 kg/mm<sup>2</sup>) were found to be independent of coating thickness (0.5 μm and 1 μm) but in the latter two regions the thicker coating imparted a higher work hardening rate to the crystal than the thinner layer, e.g. for a 0.5 μm chromium layer the work hardening rate was 1.65 kg/mm<sup>2</sup> in region iii and for a 1 μm chromium layer it was 2.97 kg/mm<sup>2</sup> in region iii. It is tentatively suggested that the chromium layer affected mobile dislocation motion rather than dislocation generation. The synchrotron work produced no evidence to support the argument that dislocation motion up the elastic line took place. Yielding was found to occur at a stress level similar to that measured in the Instron work. The complex stress system imposed by the deformation jig and the lack of resolution rendered it impossible to decide where the dislocation sources were located. Further increases in the load on the crystal produced double slip and this was argued to prematurely occur because of the combination of torsion, bending and tension which the crystal experienced. Certain interfacial dislocation activity was registered but this was not readily analysed in terms of surface sources. The yielding behaviour was inhomogeneous and appeared to be remote from the few slip bands induced by specimen transport. After yielding evidence was found for dislocation pile-up at the centre of the crystal. It is pointed out that future studies should use a better design of deformation jig so as to apply only a tensile stress to the crystal. Plating thickness and specimen size could be further explored. 548

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