Dislocation Science


	When you first encounter crystal lattice defects, the one-dimensional dislocations are the most difficult ones to imagine. True, the ubiquitous schematic picture of an edge dislocation is not all that hard to grasp, but everything beyond that gets a bit mind boggling at first. In contrast, all the other defects- vacancies and interstitials, grain boundaries or precipitates - are far easier to imagine. In reality, all defects hang together; they do not exist in splendid isolation. Dislocations and their interaction with all other defects are central to metallurgy and that's why I will devote several modules to this topic.
	1.	The Basics, including Volterra's knife and a few equations.
	2.	The Reality. All the rather weird stuff real dislocations do.
	3.	Specialties. How dislocations reproduce and so on.
	You may a so want to check these modules
		History of dislocations Who invented (or discovered?) dislocations?
		Creep and Fatigue, where creepy or tired dislocations cause big problems.

Invention or Discovery?

Defect Etching in Silicon

Myths and Bullshit Around Quenching

Discovery of Atoms

Antique Texts Concerning Iron

Radiocarbon (C14) Dating

Early Copper Sites

Diffusion in Iron

Heroes of Dislocation Science

Dislocation Science - 1. The Basics

The Al - Cu System

Grain Boundary - Advanced

Experimental Techniques for Measuring Diffusion Parameters

Phenomenological Modelling of Diffusion

Twinning, Shear Deformation and Martensite Formation

Cayönü Tepesi

Size and Density of Precipitates

Displacement and Strain

The Story of Self-Interstitials in Silicon

Atomic Mechanisms of Diffusion

Making Vacancies

Hallan Çemi Tepesi

1. Basics of Segregation

5.3.3 Stacking Faults

Homogeneous Nucleation

Dislocation Science - 2. The Reality

Dislocation Science - 3. Specialities

5.4.1 The dislocation

The Cyprus Copper and Bronze Industry

Early Iron sites

Pictures of Grain Boundaries

Deformation Types

© H. Föll (Iron, Steel and Swords script)