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The force between a dislocation dipole and a non-parallel dislocation
SCTA
60
METALLURGICA,
at 4°K. using standard d.c. potentiometric with the specimen in a magnetic Resistivity ducibly
field of 300 oersteds.
changes of lo-l2 ohm-cm
measured.
(The
techniques
could be repro-
experimental
details
are
given in Ref. 2.) The isochronal
annealing
are shown in Fig. 1.
data for 30 min anneals
Two distinct
annealing
stages
centered around 50°C and 130°C were observed. change of slope method of determining energies
which
characterized
stages was applied. not exhibit
these
two
1.0 f
annealing
datat2) the defect
stage was identified
mobile
as the monovacancy.
in this
The mag-
isochronal step is the divacancy. Attempts to measure the Ee$zctive m . the temperature range of 30-70°C in anomalous
resistivity
temperature
increases
was increased
when the
as shown
in
Fig. 2. These transients may have resulted from the breakup
of small vacancy
temperature
References 1. R.
W. BALLUFFI Quenched Metals,
and
0.
R.
693.
W.
SIEGEL,
Academic
Lattice Defects in Press, New York
(1965).
2. M. WUTTIG and H. K. BIRNBAIX, to bepuh1ishedin.J. Phys. Chem. Solids. 3. S. MADER, A. SEEGER and E. SIMSCH, 2. Metallk. 52, 785 (1961). 4. I. G. GREENBIELD and H. G. F. WILSDOR+, J. Phys. Sot. Japan 18, Suppl 3, 20 (1963). * Received Julv 6. 1965. This research was supported in part by Wright Patterson Air Force Base under contract AF 33(615)-1695.
a value of
netic data indicate that the defect mobile in the 50°C
annealing
1966
0.1 eV. On the basis of the magnetic
and the resistivity
resulted
14,
The data in the 130°C stage did
any transientsc2) and yielded
Eeffective = 1x
The
the activation
VOL.
clusters
was increased.
as the annealing
The increase in resistivity
The force between a dislocation dipole and a non-parallel dislocation* The influence of a dislocation dislocations
dipole D, composed
L, and L1’, on another dislocation
of
L, can
be described in detail by forces f on unit elements of L, or, very roughly,
by the total force F.
Some simple conclusions
will be drawn for the total
force F for the case when D and L, are non-parallel. Let us first mention
the results for the total force
would then require that pnv < npzv (where pnv is the
F2*l between two straight infinite non-parallel disloca-
resistivity
tions given
of a cluster of n divacancies).
Although of E~~‘tive defect
the difficulties in relating measured values the energy
to
will exist
vacancy
clusters
of motion
generally,
the instability
may be peculiar
et uZ.(~! have suggested
of a particular of small
to nickel.
that prismatic
Mader
loops may be
difficult to form in nickel below the Curie temperature because of magnetization however
form
during
effects. the
Some clusters may
quench
at temperatures
above the Curie temperature
and be retained to lower
temperatures.
then tend to dissociate
These would
into divacancies
on isothermal
culty of forming vacancy may be supported and Wilsdorf(4) and in irradiated mission electron temperatures interpreted mobility,
annealing.
The diffi-
clusters at low temperatures
by the observations
that vacancy
clustering
earlier
(Kroupa(l));
the forces
on unit
elements for this case were discussed in detail recently by Hartley Let
us
and Hirth,c2) and Bullough
assume
an
infinite
elastic
and Sharp.t3) medium
with
shear modulus 1~and Poisson ratio Y. The coordinates are chosen as in Fig. 1: the dislocation z axis, the dislocation
L, lies in the
L, is parallel to the xz plane,
intersects the y axis at the point y = (x (ial is thus the shortest distance between the non-parallel
lines L,, L, ;
we assume a + 0) and makes an angle /I with the z
Z
of Greenfield in quenched
nickel was not observed
by trans-
microscope
techniques
at annealing
below 200°C.
Greenfield
and Wilsdorf
their results on the basis of a low defect
which does not appear tenable in view of the
present results. M.
WUTTIG
H. K. BIRNBAUM Depart*ment of Mining,
Metallurgy
and Petroleum Engineering University of Illinois Urbana,, Illinois
FIG. 1. Dislocation dipole D, composed of dislocations and L,‘, and another straight dislocation L,.
L,
LETTERS
we assume 0 < /l < rrt.
direction;
of the dislocation
The Burgers vectors b(l)
and bc2) of L, and L, are general.
formula)
The total force F2*l
L, due to dislocation f 2~1(deduced
by integrating
The orientation
lines and the sense of the angle p is
shown in Pig. 1 by arrows. on dislocation
along L,.
L, was obtained(l)
from the Peach-Koehler
It has only B’f,’ component
zero which is a function
opposite
the dislocations
direction
sides or attractive
non-
of /3, bf$, bi’), br), ba”),u, v, and
sign a and does not depend on the distance intersecting
TO
Ial ; after
the force changes to the
(the force is repulsive
from both
61
EDITOR
distribution
of forces f on unit elements of L, changes
in a complicated
way but the total force F, which is an
integral of f along L,, is zero or, in the special case when L, intersects the inside of the dipole, generally a non-zero constant. A dislocation
in a crystal does not, of course, move
as a solid whole.
The motion
of a dislocation
trolled by forces f on the dislocation external stresses, different obstacles
L, let us now consider a
is con-
elements due to (e.g. the disloca-
tion dipoles), friction stress and also by the line tension of the dislocation
which acts against its curvature.
cases when the forces f are practically
from both sides).
Instead of one dislocation
THE
a short segment of a dislocation
concmtrated
In on
it is possible to take
dislocation
roughly the total force F as a point force or to calculate
location
the mean value off
dipole D, composed of L, and another disL1’: which is parallel to L, and has opposite
Burgers vector, b(l)’ = -b(l).
on this segment as f = F/l, where
1 is the length of the segment ; for the case of disloca-
The distance c between L, and L,’ and the angle p (Fig. 1) are arbitrary. From
tion L, in the close neighbourhood
the results mentioned
1 m c/sin b. This approach is justified by the action of
above it follows directly for the
total force F from the dipole dislocation
D on the non-parallel
L, that : (i) the total force F is zero when
the dislocation
L, does not intersect
tween L, and L,‘. sects the ribbon open interval
the ribbon
(ii) When the dislocation between
L, and L,’
be-
L, inter-
(a is from
(0, c sin CJJ) ; we assume p f
the
0, p # 7r)
the total force F has only the F, component
non-zero
or inside the dipole,
the line tension which decreases the sensitivity dislocation
to local variation
especially when the width c of the dipole is small and when the dislocation
L, moves under external
The total force from the dislocation L, on the dipole When the dislocation L2 is outside
D as a whole is -F.
(it acts in the direction of the shortest distance between
the dipole the total forces on individual L, and L,’ are opposite
or L,‘L,)
which does not
depend on the distances c and [a/ and is equal to 2Fis1. Using the value F$’
given in Ref. 1 it follows that
1FJ from equation
[( b(l) b(2) _ z
z
Z
2
1 (1)
The results given lead, therefore,
sign for a < 0 (37 < q < 27r).
Obviously, for CJJ = 0 or q = r the total force F = 0 also for a = 0. These simple but somewhat
surprising
with the use of the concept in an infinite medium. solution
to move the dipole with
it or, at least, to bend it locally.
where the + sign holds for a > 0 (0 < q~ < r) and the
locations
L, is inside the
L, moves under an external shear
stress it tries, in this position,
conclusion
not give a complete
When the dislocation
when the dislocation
x
connected
to l/2
(1)) ; they only try to make the
dipole the forces on Ll and L,’ have the same direction;
b(l) b(2)
-
dislocations
(and equal in magnitude
dipole locally wider or narrower and do not try to move it as a whole.
F,=f+
shea,r
stress.
the non-parallel
lines L,L,
of the
of f on short segments,
for the theories
the con-
tribution
to the hardening
of the elastic interaction
between
the
non-parallel
dipoles
and
dislocations,
insofar as they run outside the dipoles, can very well be neglected.
results are
of infinite dis-
For B +
to the following
of hardening:
F.KROUPA
0 they do
for the dislocation
L,
Institute of Physics
D; in this case the total force II and not only F Y but will also depend on b:) and b@)
Czechoslovak Academy of Sciences
total force : when a non-parallel dislocation L, moves as a rigid whole in the stress field of the dipole D, the
References
parallel to t’he dipole
Prague, Czechoslovakia
also F, can be infinite or zero. Let us stress once more the physical meaning of the
i The author is indebted to Dr. J. Hornstra for drawing his attention to the fact that the restriction 0 < p < n should be added in(l) to ensure the right sign of the total force.
1. F. KROUPA, Czech.J. Phys. Bll, 847 (1961). 2. C. S. HARTLEY, J. P. HIRTH, Acta Met.13,79 (1965). 3. R. BULLOU~H, J. V. SHARP, Phil. Mug. 11,605 (1965). * Received
May 20, 1965;
revised July 2, 1965.
60
METALLURGICA,
at 4°K. using standard d.c. potentiometric with the specimen in a magnetic Resistivity ducibly
field of 300 oersteds.
changes of lo-l2 ohm-cm
measured.
(The
techniques
could be repro-
experimental
details
are
given in Ref. 2.) The isochronal
annealing
are shown in Fig. 1.
data for 30 min anneals
Two distinct
annealing
stages
centered around 50°C and 130°C were observed. change of slope method of determining energies
which
characterized
stages was applied. not exhibit
these
two
1.0 f
annealing
datat2) the defect
stage was identified
mobile
as the monovacancy.
in this
The mag-
isochronal step is the divacancy. Attempts to measure the Ee$zctive m . the temperature range of 30-70°C in anomalous
resistivity
temperature
increases
was increased
when the
as shown
in
Fig. 2. These transients may have resulted from the breakup
of small vacancy
temperature
References 1. R.
W. BALLUFFI Quenched Metals,
and
0.
R.
693.
W.
SIEGEL,
Academic
Lattice Defects in Press, New York
(1965).
2. M. WUTTIG and H. K. BIRNBAIX, to bepuh1ishedin.J. Phys. Chem. Solids. 3. S. MADER, A. SEEGER and E. SIMSCH, 2. Metallk. 52, 785 (1961). 4. I. G. GREENBIELD and H. G. F. WILSDOR+, J. Phys. Sot. Japan 18, Suppl 3, 20 (1963). * Received Julv 6. 1965. This research was supported in part by Wright Patterson Air Force Base under contract AF 33(615)-1695.
a value of
netic data indicate that the defect mobile in the 50°C
annealing
1966
0.1 eV. On the basis of the magnetic
and the resistivity
resulted
14,
The data in the 130°C stage did
any transientsc2) and yielded
Eeffective = 1x
The
the activation
VOL.
clusters
was increased.
as the annealing
The increase in resistivity
The force between a dislocation dipole and a non-parallel dislocation* The influence of a dislocation dislocations
dipole D, composed
L, and L1’, on another dislocation
of
L, can
be described in detail by forces f on unit elements of L, or, very roughly,
by the total force F.
Some simple conclusions
will be drawn for the total
force F for the case when D and L, are non-parallel. Let us first mention
the results for the total force
would then require that pnv < npzv (where pnv is the
F2*l between two straight infinite non-parallel disloca-
resistivity
tions given
of a cluster of n divacancies).
Although of E~~‘tive defect
the difficulties in relating measured values the energy
to
will exist
vacancy
clusters
of motion
generally,
the instability
may be peculiar
et uZ.(~! have suggested
of a particular of small
to nickel.
that prismatic
Mader
loops may be
difficult to form in nickel below the Curie temperature because of magnetization however
form
during
effects. the
Some clusters may
quench
at temperatures
above the Curie temperature
and be retained to lower
temperatures.
then tend to dissociate
These would
into divacancies
on isothermal
culty of forming vacancy may be supported and Wilsdorf(4) and in irradiated mission electron temperatures interpreted mobility,
annealing.
The diffi-
clusters at low temperatures
by the observations
that vacancy
clustering
earlier
(Kroupa(l));
the forces
on unit
elements for this case were discussed in detail recently by Hartley Let
us
and Hirth,c2) and Bullough
assume
an
infinite
elastic
and Sharp.t3) medium
with
shear modulus 1~and Poisson ratio Y. The coordinates are chosen as in Fig. 1: the dislocation z axis, the dislocation
L, lies in the
L, is parallel to the xz plane,
intersects the y axis at the point y = (x (ial is thus the shortest distance between the non-parallel
lines L,, L, ;
we assume a + 0) and makes an angle /I with the z
Z
of Greenfield in quenched
nickel was not observed
by trans-
microscope
techniques
at annealing
below 200°C.
Greenfield
and Wilsdorf
their results on the basis of a low defect
which does not appear tenable in view of the
present results. M.
WUTTIG
H. K. BIRNBAUM Depart*ment of Mining,
Metallurgy
and Petroleum Engineering University of Illinois Urbana,, Illinois
FIG. 1. Dislocation dipole D, composed of dislocations and L,‘, and another straight dislocation L,.
L,
LETTERS
we assume 0 < /l < rrt.
direction;
of the dislocation
The Burgers vectors b(l)
and bc2) of L, and L, are general.
formula)
The total force F2*l
L, due to dislocation f 2~1(deduced
by integrating
The orientation
lines and the sense of the angle p is
shown in Pig. 1 by arrows. on dislocation
along L,.
L, was obtained(l)
from the Peach-Koehler
It has only B’f,’ component
zero which is a function
opposite
the dislocations
direction
sides or attractive
non-
of /3, bf$, bi’), br), ba”),u, v, and
sign a and does not depend on the distance intersecting
TO
Ial ; after
the force changes to the
(the force is repulsive
from both
61
EDITOR
distribution
of forces f on unit elements of L, changes
in a complicated
way but the total force F, which is an
integral of f along L,, is zero or, in the special case when L, intersects the inside of the dipole, generally a non-zero constant. A dislocation
in a crystal does not, of course, move
as a solid whole.
The motion
of a dislocation
trolled by forces f on the dislocation external stresses, different obstacles
L, let us now consider a
is con-
elements due to (e.g. the disloca-
tion dipoles), friction stress and also by the line tension of the dislocation
which acts against its curvature.
cases when the forces f are practically
from both sides).
Instead of one dislocation
THE
a short segment of a dislocation
concmtrated
In on
it is possible to take
dislocation
roughly the total force F as a point force or to calculate
location
the mean value off
dipole D, composed of L, and another disL1’: which is parallel to L, and has opposite
Burgers vector, b(l)’ = -b(l).
on this segment as f = F/l, where
1 is the length of the segment ; for the case of disloca-
The distance c between L, and L,’ and the angle p (Fig. 1) are arbitrary. From
tion L, in the close neighbourhood
the results mentioned
1 m c/sin b. This approach is justified by the action of
above it follows directly for the
total force F from the dipole dislocation
D on the non-parallel
L, that : (i) the total force F is zero when
the dislocation
L, does not intersect
tween L, and L,‘. sects the ribbon open interval
the ribbon
(ii) When the dislocation between
L, and L,’
be-
L, inter-
(a is from
(0, c sin CJJ) ; we assume p f
the
0, p # 7r)
the total force F has only the F, component
non-zero
or inside the dipole,
the line tension which decreases the sensitivity dislocation
to local variation
especially when the width c of the dipole is small and when the dislocation
L, moves under external
The total force from the dislocation L, on the dipole When the dislocation L2 is outside
D as a whole is -F.
(it acts in the direction of the shortest distance between
the dipole the total forces on individual L, and L,’ are opposite
or L,‘L,)
which does not
depend on the distances c and [a/ and is equal to 2Fis1. Using the value F$’
given in Ref. 1 it follows that
1FJ from equation
[( b(l) b(2) _ z
z
Z
2
1 (1)
The results given lead, therefore,
sign for a < 0 (37 < q < 27r).
Obviously, for CJJ = 0 or q = r the total force F = 0 also for a = 0. These simple but somewhat
surprising
with the use of the concept in an infinite medium. solution
to move the dipole with
it or, at least, to bend it locally.
where the + sign holds for a > 0 (0 < q~ < r) and the
locations
L, is inside the
L, moves under an external shear
stress it tries, in this position,
conclusion
not give a complete
When the dislocation
when the dislocation
x
connected
to l/2
(1)) ; they only try to make the
dipole the forces on Ll and L,’ have the same direction;
b(l) b(2)
-
dislocations
(and equal in magnitude
dipole locally wider or narrower and do not try to move it as a whole.
F,=f+
shea,r
stress.
the non-parallel
lines L,L,
of the
of f on short segments,
for the theories
the con-
tribution
to the hardening
of the elastic interaction
between
the
non-parallel
dipoles
and
dislocations,
insofar as they run outside the dipoles, can very well be neglected.
results are
of infinite dis-
For B +
to the following
of hardening:
F.KROUPA
0 they do
for the dislocation
L,
Institute of Physics
D; in this case the total force II and not only F Y but will also depend on b:) and b@)
Czechoslovak Academy of Sciences
total force : when a non-parallel dislocation L, moves as a rigid whole in the stress field of the dipole D, the
References
parallel to t’he dipole
Prague, Czechoslovakia
also F, can be infinite or zero. Let us stress once more the physical meaning of the
i The author is indebted to Dr. J. Hornstra for drawing his attention to the fact that the restriction 0 < p < n should be added in(l) to ensure the right sign of the total force.
1. F. KROUPA, Czech.J. Phys. Bll, 847 (1961). 2. C. S. HARTLEY, J. P. HIRTH, Acta Met.13,79 (1965). 3. R. BULLOU~H, J. V. SHARP, Phil. Mug. 11,605 (1965). * Received
May 20, 1965;
revised July 2, 1965.