1. Imperfections in ordered structures
Point defects
Line defects - dislocations
Planar defects – stacking faults

2. Point defects
native – vacancies
– interstitials

3. Point defects impurities – functional position – substitutional
– unintentional
position – substitutional
– interstitial

4. Interstitial positions in fcc lattice
in close-packed structure
octahedral – ro ~ 41% of R
tetrahedral – rt ~ 23% of R
R – atomic radius of the
atoms in hard-sphere model
approximation
4 octahedral positions/cell
8 tetrahedral positions/cell

5. Concetration of point defects
thermodynamic equilibrium – minimized Gibbs free energy
G = H – TS
enthalpy of defect formation
Arrhenius plot
quenching – non-equilibrium concentration of defects

6. Ionic crystals Schottky defect – Frenkel defect – unoccupied anion
and cation sites
Frenkel defect –
atom displaced from its
lattice position to an interstitial site

7. Line defects – Dislocations
dislocation – central object in ductility of crystalline materials
dislocations were
introduced to explain the plasticity of crystalline solids
theoretical estimate of the shear strength – σ ~ G/5 – G/30
the observed values are by 3 – 4 orders of magnitude lower
applied shear stress – motion of dislocation within the slip plane

8. Basic milestones Volterra (1907) – dislocations in elastic continuum
Taylor, Orowan, Polanyi (1934) – concept of dislocations in crystals
Frenkel, Kontorova (1938) – string model
Peierls, Nabarro (1940, 1947) – dislocation motion, barrier model
Shockley (1953) – parcial dislocations in fcc lattice
Hirsch (1956) – observation of dislocations by TEM
Lang (1958) – imaging of dislocations by X-ray topography
Ray, Cockayne (1969) – observation of partial dislocations
by weak beam technique (TEM)

9. Edge dislocation
Burgers vector b – geometrical parameter

10. finish-start/right-hand
Definition of the Burgers vector
FS/RH convention
finish-start/right-hand
edge dislocation

11. Definition of the Burgers vector
screw dislocation

12. Basic axioms n ξ b The Burgers vector is conserved, it does not change
along the dislocation.
For curved dislocation the character of the dislocation
changes (edge vs. screw). ξ b n
b and ξ define
the slip plane

13. Basic axioms A dislocation cannot end inside a perfect crystal.
ends at the free surface
creates closed loop
ends on an other dislocation
Burgers vector of a perfect dislocation must equal to one of
the lattice translation vectors.

14. Energy of the dislocations
elasticity – stress and strain fields of dislocations – Volterra – 1907
ξ ‖ z
E ~ b2
Burgers vector – always the shortest lattice vector

15. Frenkel-Kontorova model
the motion of dislocation cannot be solved
within the framework of theory of elasticity
1938 – first model based on atomic structure
results – the existence of a maximum value for dislocation velocity
– the limit is the sound velocity
– increase of the dislocation energy with velocity
– analogy with the theory of relativity
Frank, van der Merwe (1949) – first theory of misfit dislocations based on
Frenkel-Kontorova model

16. Peierls stress Peierls-Nabarro model of dislocation continuum
atoms at the
interface

17. Peierls stress Peierls-Nabarro model of dislocation
Peierls stress – the force needed to move
a dislocation within a plane of atoms
w – dislocation width
b – Burgers vector
G – shear modulus
ν – Poisson ratio w b
glide
plane

18. interaction with point defects
Motion of dislocations
conservative – glide – sklz
non-conservative – climb – šplhanie
interaction with point defects

19. Intersection of dislocations
direction of motion
emission of
point defects
edge
segment

20. Force acting on dislocations
Peach-Koehler formula

21. Dislocation interaction
force – external – mechanical loading
– internal – from other dislocations
range – long range – between parallel dislocations
– short range – between intersecting dislocations
attraction Fx x
repulsion

22. Dislocation walls formation of stable arrays – dislocation walls
small angle
grain boundaries

23. Interaction with point defects
dislocation climb
high (non-equilibrium)
vacancy concentration
mechanical stress

24. Interaction with point defects
climb force Fcl
Fcl L h
chemical potential = Gibbs free energy/particle

25. Growth of dislocation loops
non-equilibrium point defect concentration
growth of dislocation loops
dislocation
loop
climb force acting on dislocation
tension in dislocation line

26. Consequences of the Peierls barrier
slip planes – lattice planes with largest interplanar distances
Peierls relief – determines the direction of dislocation lines
direction of
motion

27. Peierls relief metallic bond – low σPN covalent bond – high σPN
vybočenia
metallic bond – low σPN
covalent bond – high σPN
strongly localized objects – kinks - vybočenia

28. Selection rules Burgers vectors – shortest lattice translation vectors
vybočenia
Burgers vectors – shortest lattice translation vectors
dislocation orientation – along the Peierls relief
– directions with the smallest indices
slip planes – lattice planes with the largest interplanar distances
direction of slip is given by the orientation of the Burgers vector
slip system – combination of the slip planes and the slip directions
plasticity of polycrystalline materials requires five independent slip systems

29. Dislocations in fcc lattice
vybočenia
shortest lattice vectors
b vectors –
slip planes –
12 slip systems – 5 independent

30. Dislocations in bcc lattice
vybočenia
Dislocations in bcc lattice
shortest lattice vectors
plane
b vectors –
similar reticular density in
different lattice planes
no preferred slip plane

31. Dislocations in bcc lattice
vybočenia
Dislocations in bcc lattice
plane

32. Dislocations in bcc lattice
vybočenia
Dislocations in bcc lattice
plane

33. Dislocations in hcp lattice
vybočenia
Dislocations in hcp lattice
b vectors – 2
basal slip – plane 3 1

34. Dislocations in hcp lattice
vybočenia
Dislocations in hcp lattice
prismatic slip
bc vectors –
ba vectors – 2
ba+ bc 3 1

35. Dislocations in hcp lattice
vybočenia
Dislocations in hcp lattice
pyramidal slip I.
ba+c vectors –
ba vectors – 2 3 1

36. Dislocations in diamond lattice
vybočenia
Dislocations in diamond lattice
stacking of {111} planes
plane (111)
three positions
in fcc lattice –
ABCABCABC

37. glide set dislocations are formed
vybočenia
Dislocations in diamond lattice
[112]
projection of Si lattice B A
[111] C B
d111 A
shuffle
set
glide
glide set dislocations are formed
in diamond lattice

38. Dislocation motion in covalent crystals
vybočenia
Dislocation motion in covalent crystals
additional parameters – energy of kink formation and kink migration
secondary Peierls barrier introduced for kink migration
dislocation velocity
both energies ~ 1 eV
strong dependence of dislocation velocity on T !

39. Stacking faults – vrstevné chyby
vybočenia
Stacking faults – vrstevné chyby
ABCABCABCABC
fcc
ABABABABABAB
hcp
one plane missing –
intrinsic stacking fault
ABCABABCABC
one excess plane –
extrinsic stacking fault
ABCABACABCAB

40. Stacking faults and partial dislocations
vybočenia
Stacking faults and partial dislocations
SF – terminate at the free surface of crystal
– bounded by partial dislocation
type of partial dislocation reveals the process leading to the creation of SF A C B A C B
vacancy condensation –
intrinsic SF
condensation of interstitials –
extrinsic SF
SF is bounded by a Frank parcial dislocation –

41. vybočenia
Stacking faults and partial dislocations AB AC
ABCABCABCABC
CABCABCA
ABCACABCABCA
plane B is missing

42. Shockley partial dislocations
vybočenia
Shockley partial dislocations
30°
mixed dislocation
90°
edge dislocation
energy of SF ~ 50 mJ/m2
weak beam imaging
perfect 60° dislocation – splitted into two Shockley partial
bounding an intrinsic SF in the dislocation core

43. Microtwinning ABCABCABCABC ABCABABCABCA ABCABACABCAB ABCABACBCABC
vybočenia
Microtwinning
ABCABCABCABC
glide of one Shockley
partial dislocation –
formation of intrinsic SF
ABCABABCABCA
ABCABACABCAB
ABCABACBCABC
ABCABACBABCA
repetition of the process –
formation of a microtwin
formation by plastic deformation
or at the process of crystal growth
random distribution –
polytypism – ZnS, SiC
microtwin