Atomic, Electron and Phonon Aspects of the Edge Dislocation in Iron

H.B. Liu; J.A. Ascencio

doi:10.4028/www.scientific.net/DDF.224-225.37

Paper Titles

Free Surface Relaxation and Two-Beam TEM Imaging of Straight Dislocations in Thin Foils
p.1

Free Volume Diffusion and Optimisation of Soft Magnetic Properties in Amorphous Alloys Based on Iron
p.13

Super-High Concentrations of Vacancies in Regions of High Concentration of Point Defects and Composition of Vacancy-Oxygen Complexes in These Regions in Pd, Ta, W and Pt Polycrystals
p.27

Atomic, Electron and Phonon Aspects of the Edge Dislocation in Iron
p.37

Calculation of Tracer and Chemical Diffusion Coefficients in the Intermetallic Compound β-AgMg
p.45

Investigation of Hydride Formation in Crystalline and Amorphous Metallic Alloys Using Electrochemical Hydrogen Permeation Tests
p.53

Vacancy-Formation Thermodynamics in Aluminium and Nickel: a Computational Study
p.59

Hydrogen Diffusion in Laves-Phase Compounds
p.75

Chemical and Intrinsic Hydrogen Diffusion in Pd_0.75Ag_0.25–H Alloys: NMR Aspects
p.93

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Atomic, Electron and Phonon Aspects of the Edge Dislocation in Iron

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Defect and Diffusion Forum (Volumes 224-225)

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37-44

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https://doi.org/10.4028/www.scientific.net/DDF.224-225.37

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Online since:

December 2003

Authors:

H.B. Liu, J.A. Ascencio

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Edge Dislocation, Electron Structure, Iron, Molecular Dynamic (MD)

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