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On calculations of the crss of alloys containing coherent precipitates
ON
CALCULATIONS
OF THE CRSS OF ALLOYS COHERENT PRECIPITATES* V.
CONTAINING
GEROLDT
Two recent estimates on the critical resolved shear stress of alloys containing coherent precipitates are critically compared. The differences between both estimates are discussed in detail. In both cases t)he interaction between dislocation and precipitates is assumed to occur via the elasticstrain field surrounding t,he coherent particles. Both estimates are performed in three steps: one calculates (i) the maximum repelling interaction force of the coherency strain field on the dislocation as a function of the position of (ii) The average distance I; between repelling strain fields along the dislocation line; and the slip plane; It is shown that the most. important difference between both (iii) there follows an averaging procedure. estimates is introduced by the averaging procedures. CALCCL
DE
LA
CISSIOX
CRITIQUE DES
RESOLUE
PRECIPITES
POUR
DES
SLLIAGES
CONTEXAST
COHERENTS
Deux &valuations r&entes de la cission critique r&solue pour des alliages contenant des pr&ipit& coh&ent,s sont soigneusement comparBes en vue d’une Etude critique. Les diffbrences entre les deux &valuations sont disc&es en d&ail. Dans les deux cas on suppose que l’interaction dislocations-p&&pit& se produit par l’interm&diaire du champ de deformation Qlastique entourent les particules cohhrentes. Les deux &ah&ions comprennent trois stades: on calcule (i) d’abord la force d’interaction repulsive maximum exe&e par le champ de coh&zion sur la dislocation, comme une fontion de la position (ii) ensuite la distance L moyenne entre les champs de contraintes de &p&ion 1e du plan de glissement; L’auteur montre que (iii) enfin suit une n&thode de calcul des moyennes. long de la ligne de dislocation; la diffhrence la plus importante entre les deux &valuations vient des m&hodcs de calcul des moyenn(~s. irBER
DIE
BERECHSUNG
DER MIT
KRITISCHEN
KOHBRENTER
SCHUBSPANNUNG
T’OS
LEGIERVSGES
AUSSCHEIDUNG
Es werden zwei Abschktzungen iiber die kritische Schubspannung 70 von Legierungen mit kohiirent,er Ausscheidung miteinander verglichen und ihre IJnterschiede eingehend diskutiert. In beiden Fiillen wird angenommen, dalj die Wechselwirkung zwischen Versetzung und Ausschaidung iiber das elastische Spannungsfeld erfolgt, das die kohiirenten Teilchen umgibt. Beide Abschhtzungen werden in 3 Schritten durchgefiihrt: Berechnung (i) der maximalen abstoI3enden Kraftwirkung K des koh&renten Spannungsfeldes auf die Versetzung als Funktion der Gleitebenenlage, (ii) dos mittleren Abstandes L zwischen abstoBenden Spannungsfeldern liings der Versetzungslinie und (iii) des Mittelwertes von T,,. Es wird
gezeigt, da13 die groDen Unterschiede Mit,telwertbildung hervorgerufen werden.
zwischen
1. INTRODUCTION
In a recent publication discusses stress
the increase
(CRSS)
two-phase
due
alloy.
to
of the critical
resolved
rewritten
in a slightly
the difference
and
between
st,rain fields
in a
strained coherent
different
way.
particle
G is
value
parameters
of
of the
R is the
and the matrix.
average radius of the spherical precipitated particles and f is their volume fraction. b is the length of the Burgers
vector.
formula
has
The line t,ension T of the original
been
taken
as G. b2/2. Equation
ACTS
dependence Authors
METALLITRGICA,
VOL.
16, JCNE
1963
between
both
formulae
is the
ArO
with the volume fraction. I used a straight line approximation in their
estimate. Contrary to this Gleiter claims this approximation to be invalid. He used an optimising method
for his estimate
II.
Therefore,
one might
conclude that the differences of equation (1) and (2) are caused by these approximations. The purpose of tions result in a AT~ that differs only by a constant numerical
Institut
of
(2)
the present paper is to prove that both approxima-
(1)
*
Received October 25, 1967. t Max-Planck-Institut fiir Metallforschung, Metallkunde, Stuttgart, Germany.
Their result
AT,’ = 3G&3’2f1’2(R/b)1’2 The main difference
(1)
F is the positive
the lattice
untcrschiedliche
was
His result is
bhe shear modulus
durch
kornt2) (referred t,o as I in this paper).
shear
ATO” = 11 .SG,3’2fj’“( R/6)“2 when
Abschlltzungen
differs from a formula derived by Gerold and Haber-
Gleiter(l) (referred to as II) coherency
beiden
dependence
fiir
factor.
method of averaging. 823
The
obvious
on f, however:
differences
in the
have t,heir cause in the
L1C’l’X
824 2.
THE
GENERAL
THE
The
CONCEPT
of the
CRSS
interacting
dislocation
and
different If
the
syst’em:
the
at
force
K
the
strain
field.
used
particle
center
of
slip plane
a
as
with
gliding Here,
discussed
radius
Cartesian
of the
of three
between
are
spherical
the
R is
coordinate
dislocations
is taken
to be z = z,,. The general direction of the dislocation line is parallel to the y-axis. In the following discusIt’s is assumed. sion, an edge type dislocation position
at’ maximum
flmct’ion X,(y).
interaction
The force K(z,)
K(z,)
= b
is given
surrounding
the
by
the
is then defined as
-z TJ-UY), s -- m
where 7i is the internal strains
(3)
Y> %I dY
for
r2 < R2
xR% Ti(2,.Y, z) = A . 7
for
r2 > R2
distance,
where 4’ is the function
is not
curves X,(y,
He
equation
K”(z,/R)
(4)
In addition
(3).
average
centers
along
depends
on the radius
distance the
particles
is the calculation
L between
dislocation
repelling force This distance
line.
R and the volume
as well as on the
A+,)
fraction
bending
f
of the
= A . bR++,/R)
is still a function
value of A++,)
= K(z,)/bL
of z,,/R also plotted in Fig. 1.
the ratio 4”/+’ is shown in the
all three
The
authors
A,,.
I
used
a
simple
approximation
originally given by Fleischerc3) to calculate distance
L for single solute
In this, the distance
the average
aOoms in a dilute
alloy.
L depends on the bending
angle
28 of the dislocation.
For small values
of K where
0 Y K/2T P KlGb2
(5)
of the position
which is the CRSS
will review
of the slip
where
T is the line energy
is approximated
(8)
of the dislocation
which
by Gb2/2. The rc>sult is
The following
steps
as taken
by
I and II.
CALCULATION
OF SHEAR
The interacting For the estimate
dislocation y-axis. is
discussion,
(7
this angle is small
plane, zO. The third and final step takes an optimum
authors
values
results in
upper part’ of the diagram.
dislocation between the particles. From both steps a critical shear stress results
paragraphs
This estimate
3.2 Calculation of the average d&mace L step of the estimate
of the
which
“optimized”
to zOthe force K depends on the particle
radius R. The second
of the
r2 = x2 + y2 + 9.
and
line approxi-
calculated
z,,) which give rise to maximum
of the integral,
For further
position
in Fig. 1.
that this straight
valid.
with $I’ being a function A = ~.C:.E:
Z/R
of the normalized
(z,/R) . #II is plotted
Author II maintains
with
3.1
plane
I.
mation
acting on the dislocation:
,ri = 0
Slip
The dependence of the force functions 4’ and $I1 and their ratio #“/$I on the slip plane distance ZJR.
FIG.
coordinate
stress field due to coherency More precisely, particle.
it is bhc shear component
3.
19F8
of the maximum
t,he coherency
approximations
above. located
16.
OF
consists
The first is the calculation
repelling
J70L.
CALCULATIONS
calculation
steps.
METXLLURGICA,
THE
CRITICAL
K’(z,,
This quantity
depends
which is the effective
force K (zO) (I) assumed
line parallel
line approximation.) R) = A . bR - +‘(z,,/R)
Their
the
to the result (6)
on K(z,)
as well as on Az,,/R
range of influence of a particular
strain field perpendicular
of K the authors
line to be a straight
(Straight
RESOLVED
STRESS
to t,he glide plane.
Its value
will be discussed in the next section. The author based on calculations prefers a treatment Labusch,t4)
II of
which lead to similar results as calculations
* The equivalent equation of Fleischer‘s has an additional factor 1.23. For further discassion see equation (18).
bv Friedel.(@
and neglected
The result is R
(10)
L
(15).
If one uses equation
bet,ween the particles.
The range of influence of the
st’rain field perpendicular
to the glide plane is given
by the quant,ity h which corresponds
to AZ of equation
,4s it, will be shown in the discussion,
instead of equation bracket
which
to the second
Thus he came to equation
-
0.46(6fln)1!3]
(16)
(1). These equations differ by the
influences
the
result
considerably.
It reduces the value of AT* by 20-30% the dependence
(1).
(15) t,he final result is
AT” = 1.04A~,‘1[l
In this case the quantity RI.5 depends on AT, which is a measure of the curvature of the dislocation line
(9).
t$he t,erm corresponding
one in equation
and changes
on f.
equations
4. DISCUSSION
(9) and (10) are quite similar. As has been shown
3.3 The u.rerfqe over z.
From rcpations (6) and (9) the authors I got the result
the estimates authors
size and differ mainly AT(io) _=
This equation
(d!?‘)‘:“.($I)3i2(!y2
has to be averaged
in the following
which
was done
O.‘iR).
The
t,aken.
Then the range ALAR was increased until a
maximum
average
value
of
value (z,, N
[#13 * (d.~/R)]l/z
value for the average
was reached.
wa,s For
larger ranges AZ, the average decreases continuously, The maximum
average
was calculated to be 0.36. equation
(2).
independent
at AZ = 0.8R
occurred
and
With this value one obt*ains
The main point of thr volume
is that Az = 0.8R
is
fraction f of the precipi-
t#at,e. Author
II used a different estimate for AZ, i.e. the
quant,$v h in his notation.
He defines
(i)
shows
posi-
line are given in Fig. 2. The
the situation
for the slip plane
interaction
between
dislocation
and
The applied shear &ress pulls the dislocation
into the upward direction. the critical positions (ii) Attractive pulls
the
critical positions
Curves a’ and b’ then are
of a dislocation
medium (6’) interaction stress
of the slip
of critical
There are two possibilities :
Repulsive
part.icle.
for small values
for low (a’) and
forces.
interaction. dislocation
The applied shear downwards leading t,o
a” (for low interact,ion forces) or b”
(for medium forces). Curves I and II show the assumed critical positions used in the theories curves
are used forces.
by
for both
authors
I and II.
repulsive
and
These
attractive
The st,raight line approximation
(12)
which is half the mean spatial distance
between
the
Tt should be pointed out that, an addit,ional
dependence Inserting
part
interaction
h = (~/6~)1/3R
particles.
upper
z0 = 0.1 R.
by both
on t,he particle
Two examples
tions of the dislocation
way (see Fig. 1). A small range AZ/R
was selected where 4’ has its maximum
zO/B.
paragraphs
force K(zJ
show the same dependence
plane distance
(11)
in the preceding
of the interaction
on f is introduced
by t)his assumpt,ion,
equa’tions (7). (10) and (12) into equation (5)
t,he result, is zo= 0,89R
A--.
The aI-cragc over z0 was done by integrating I A+
h AT
dz,
s0
fl4) Ic
The main part of t,his integral is ”
hlfl
+‘“(s)
ds = 0.97 -
Expected Curve a’: Curve b’: Curve au:
0.445R/h
s
for duthor
Criticalposltions of a dislocation line. line positions (shown only in the upper part). low repelling interaction. medium repelling interaction. low attracting interaction. Curve b”: medium attraction interaction. Approximated line positions: I: straight line approximation II: “optimized” line approximation. FIG. 2.
h/R > 1/(4/5)
II used the value of h defined in equation
(15) (12)
ACTA
X26
I b’
METALLURGICA,
VOL.
16,
1968
intermediate position of curves a’ and a” or The “optimized” approximation II 6”.
is an
and
drastically
favours
the
attractive
case
(curves
a”
and b”). There is a big difference between theoretical curves a” or b”. The calculated
curve II and the “real”
values of K, and K,, differ by 30%.
(See equations
(6), (7) and Fig. 1). The lower part of Fig. 2 shows the crit,ical positions plane
for the dislocation
z0 = 0.89R.
Here,
I and II are plotted.
only
line on the slip
the
values K, and KI1 differ by 3%. therefore, t,hat the big difference occurs
a,s a consequence
curve II.
of the extreme
Wiedersich(@
relating
the
curvature
internal
strain
field.
For
fits quite
approximation
the
equation
dislocation
values
With
to
the
its maximum
&R/b < 0.2
his
AZ = 0.8R
line
independent
I, equation
(6) which
is
values of &R/b,
increasing
however, he found smaller values for K compared with This deviation is contrary that approximation. to the deviation
of the estimate
seems to be more realistic. tion by Wiedersich, already
by author
According
the straight
line approximation
is an upper limit for the function
over, K depends more symmetric
K.
More-
also on the sign of zolR and is no as in approximations
I and II.
to be
0.3R < x0 < 1.1 R.
It is
from
of the volume fraction f of the precipitate. author
II
used
tional
to R and a function
of f.
results in a different dependence To explain this difference, are plotted
in Fig.
assumed constant. the averaging
3.
half
This assumption
of AT,,(~).
several functions
All
other
ATE
parameters
are
Both solid curves are calculated by
method used by authors I. They differ K(z,)
by the function
adopted,
AT,, = 1.567,‘).
equation
(7) for
equation
(1).
the
using either equation or equation
The dashed
lated by the averaging (10)
h being
a range
the average spatial particle distance which is propor-
curve,
AT,, = K/bL into equation
1
8
in %
This range was estimated
(6) (lower curve, AT, = AT,‘)
4.2 The particle distance L Tf one substitutes the final result is
value. reaching
In contrast,
II and
to the calcula-
fraction
FIG. 3. Xormalized CRSS AT~ as a function of the particle volume fraction f. Solid lines: averaging method I, linear and “optimized” approximations, equations (6) and (7). Dashed line: averaainn method II. equation (7). Dash-dot line: aveiagkg method 11,kquation (15).
of
numerically
well with the straight
of authors to R.
proportional
of
6
4
volume
case better.
calculated
force K via the differential
the interaction
K(z/R)
position
2
D
It is suggested, in the first case
The force K, fit the “real”
Very recently
curve
approximations
In this case, the calculated
method force
This equation,
(7) (upper
curve
is calcu-
of author
II, using
function, however.
as given
by
neglects
the
influence of the upper limits of the averaging integral, (17)
equation
(14).
The
dashed-dotted
line takes
account this influence given by equation which is quite similar to equation
(9) in the case of
Obviously,
the averaging
method
into
(15).
II always gives
there is an h = AZ. In spite of this similarity, important difference. In equation (10) ATE is the
lower values of ATE (dash-dot
line) as compared to the
averaging
solid line).
increase of the CRSS;
differences occur for low values of the volume fraction
R/L is also fixed. equations function
it is a fixed value;
In contrast,
therefore,
the quantity
K in
(9) and (17) is a function of zO, R/L is also a is therefore of zO. The above substitution
not quite correct.
main
differences
The largest
In that case, the ranges used for the averaging
procedures
show maximum
h, equation
differences.
The quantity
(la), then is large resulting in low values
A question arises about the validity averaging between
the
estimates,
equations (1) and (a), occur by the averaging procedures. An important r61e is played by the distance over which a particle influences a dislocation on a given slip plane. This sphere of influence is determined differently
I (upper
of the average force K acting on the dislocation
4.3 The average over z The
f.
method
by authors I and II.
a range AZ where the interaction
Authors
I assumed
force K(z,/R)
has
procedures.
Let us assume a hypothetical
interaction between a dislocation which is restricted to the particle equal
and a particle volume. In this
the range AZ or h is restricted
case, undoubtedly, values
line.
of the different
to or lower
than
to
R, i.e. the particle
radius. Here, one never would average over regions where no influence occurs. Therefore, h will be independent
of
f,
thus
leading
to
an
averaging
GEROLD:
procedure
HARDENING
similar to method I.
decrease
the
CRSS.
COHERENT
As
has
this should
been
proved,
Al-Zn
averaging method II leads ho lower values of AT, t,han method
1. From this, one can conclude
I gives the better estimate.
If ,rnl and precipitate
WITH
R=LOA /
(2) therefore,
on f. EXPERIMENTS
are tile zinc
mz
20
that method
Equation
should givr the right, dependence 5. COMPARISON
XL’i
PRECII’I’YATES
If we now assume an
intera~t,io~l reaching to farther distances, not
BP
con~ent~rations in the
and in Dhe ma.trix. respectively,
the volume
fraction f is dc+ined by
where
md is t,he zinc
According
concentration
of
to equat#ion (I), one finds (AT&~/~ -_.f -
whereas, according
-f-
equations
ment,,
recent
various
A-Zn
m2
(19)
mA -
alloys
CRSS 70 as a function
mz
(20)
of
are taken.
Haberkorn”)
on
He measured
t,he
of the particle radius R and of
t’hc alloy concentration ‘nz_4. To correct for the friction force in the depleted matrix 0.2 kg/mm2 were subtracted’s)
from
dist#inct particle t)o equations validity
(19)
T”. and
of oquat,ions
corresponding
AT,
values
R were
radius
(20) (I)
to equation
and
in Fig. (2).
belonging
plotted
to
4 testing Only
a
a,ccording the
the curve
20 is a straight, line.
It
9
7 at. %
FIG. 4. Relationsbi~)between ~~~and~lllo~ic~fl(!erltration, ns.4,according to equat,ions (19) and (20) and to rmm~wemmts.‘TJ
This
(19) and (20) with the experi-
measurements
3 5 zinc concentration,
int’ersects the concentration
to equat’ion (2) one expects
(Ar,$ To compare
mA -
1
t,he alloy.
corresponds
well
axis at. pn,e= 1 .T at. % Zn. t’o
analyzing small angle X-ray
m2 =
1.75
found
by
sca.ttering.‘g)
REFERENCES 1. H. GLEITER, %. anger. Phys. 23, No. 2, 108 (1967). 2. V. GERALD and H. HABERKORN, Php. Status soli& 18, 675 (1966). 3. R. L. E'LEISCHER, Th.e Strengthening of Hrfals, editrd by D. PECKNER. Reinhold (1964). 4. R. LABUSCH, 2. Phya. 167,452 (1962). 5. J. FRIEDEL, Les Dislocatdans. Gauthier-Viliars (1956). 6. H. ~~~EDERSICH, lnt. Conf. strength Hat& Alto,y, Tokyo, 1967. 7. H. HABERKORN, Phys. Status Solidi 15,I53 (1966). 8. H. HABERKORN and I". GEROLD, Phys. Stutus Solidi 15, 167 119661. 9. 1’. &ROLL), Snzall A@e S-ray Scatter&g, Proceedings of the Conference held at. Syracuse 1965: Gordon & Breach, p. 277, 1967.
CALCULATIONS
OF THE CRSS OF ALLOYS COHERENT PRECIPITATES* V.
CONTAINING
GEROLDT
Two recent estimates on the critical resolved shear stress of alloys containing coherent precipitates are critically compared. The differences between both estimates are discussed in detail. In both cases t)he interaction between dislocation and precipitates is assumed to occur via the elasticstrain field surrounding t,he coherent particles. Both estimates are performed in three steps: one calculates (i) the maximum repelling interaction force of the coherency strain field on the dislocation as a function of the position of (ii) The average distance I; between repelling strain fields along the dislocation line; and the slip plane; It is shown that the most. important difference between both (iii) there follows an averaging procedure. estimates is introduced by the averaging procedures. CALCCL
DE
LA
CISSIOX
CRITIQUE DES
RESOLUE
PRECIPITES
POUR
DES
SLLIAGES
CONTEXAST
COHERENTS
Deux &valuations r&entes de la cission critique r&solue pour des alliages contenant des pr&ipit& coh&ent,s sont soigneusement comparBes en vue d’une Etude critique. Les diffbrences entre les deux &valuations sont disc&es en d&ail. Dans les deux cas on suppose que l’interaction dislocations-p&&pit& se produit par l’interm&diaire du champ de deformation Qlastique entourent les particules cohhrentes. Les deux &ah&ions comprennent trois stades: on calcule (i) d’abord la force d’interaction repulsive maximum exe&e par le champ de coh&zion sur la dislocation, comme une fontion de la position (ii) ensuite la distance L moyenne entre les champs de contraintes de &p&ion 1e du plan de glissement; L’auteur montre que (iii) enfin suit une n&thode de calcul des moyennes. long de la ligne de dislocation; la diffhrence la plus importante entre les deux &valuations vient des m&hodcs de calcul des moyenn(~s. irBER
DIE
BERECHSUNG
DER MIT
KRITISCHEN
KOHBRENTER
SCHUBSPANNUNG
T’OS
LEGIERVSGES
AUSSCHEIDUNG
Es werden zwei Abschktzungen iiber die kritische Schubspannung 70 von Legierungen mit kohiirent,er Ausscheidung miteinander verglichen und ihre IJnterschiede eingehend diskutiert. In beiden Fiillen wird angenommen, dalj die Wechselwirkung zwischen Versetzung und Ausschaidung iiber das elastische Spannungsfeld erfolgt, das die kohiirenten Teilchen umgibt. Beide Abschhtzungen werden in 3 Schritten durchgefiihrt: Berechnung (i) der maximalen abstoI3enden Kraftwirkung K des koh&renten Spannungsfeldes auf die Versetzung als Funktion der Gleitebenenlage, (ii) dos mittleren Abstandes L zwischen abstoBenden Spannungsfeldern liings der Versetzungslinie und (iii) des Mittelwertes von T,,. Es wird
gezeigt, da13 die groDen Unterschiede Mit,telwertbildung hervorgerufen werden.
zwischen
1. INTRODUCTION
In a recent publication discusses stress
the increase
(CRSS)
two-phase
due
alloy.
to
of the critical
resolved
rewritten
in a slightly
the difference
and
between
st,rain fields
in a
strained coherent
different
way.
particle
G is
value
parameters
of
of the
R is the
and the matrix.
average radius of the spherical precipitated particles and f is their volume fraction. b is the length of the Burgers
vector.
formula
has
The line t,ension T of the original
been
taken
as G. b2/2. Equation
ACTS
dependence Authors
METALLITRGICA,
VOL.
16, JCNE
1963
between
both
formulae
is the
ArO
with the volume fraction. I used a straight line approximation in their
estimate. Contrary to this Gleiter claims this approximation to be invalid. He used an optimising method
for his estimate
II.
Therefore,
one might
conclude that the differences of equation (1) and (2) are caused by these approximations. The purpose of tions result in a AT~ that differs only by a constant numerical
Institut
of
(2)
the present paper is to prove that both approxima-
(1)
*
Received October 25, 1967. t Max-Planck-Institut fiir Metallforschung, Metallkunde, Stuttgart, Germany.
Their result
AT,’ = 3G&3’2f1’2(R/b)1’2 The main difference
(1)
F is the positive
the lattice
untcrschiedliche
was
His result is
bhe shear modulus
durch
kornt2) (referred t,o as I in this paper).
shear
ATO” = 11 .SG,3’2fj’“( R/6)“2 when
Abschlltzungen
differs from a formula derived by Gerold and Haber-
Gleiter(l) (referred to as II) coherency
beiden
dependence
fiir
factor.
method of averaging. 823
The
obvious
on f, however:
differences
in the
have t,heir cause in the
L1C’l’X
824 2.
THE
GENERAL
THE
The
CONCEPT
of the
CRSS
interacting
dislocation
and
different If
the
syst’em:
the
at
force
K
the
strain
field.
used
particle
center
of
slip plane
a
as
with
gliding Here,
discussed
radius
Cartesian
of the
of three
between
are
spherical
the
R is
coordinate
dislocations
is taken
to be z = z,,. The general direction of the dislocation line is parallel to the y-axis. In the following discusIt’s is assumed. sion, an edge type dislocation position
at’ maximum
flmct’ion X,(y).
interaction
The force K(z,)
K(z,)
= b
is given
surrounding
the
by
the
is then defined as
-z TJ-UY), s -- m
where 7i is the internal strains
(3)
Y> %I dY
for
r2 < R2
xR% Ti(2,.Y, z) = A . 7
for
r2 > R2
distance,
where 4’ is the function
is not
curves X,(y,
He
equation
K”(z,/R)
(4)
In addition
(3).
average
centers
along
depends
on the radius
distance the
particles
is the calculation
L between
dislocation
repelling force This distance
line.
R and the volume
as well as on the
A+,)
fraction
bending
f
of the
= A . bR++,/R)
is still a function
value of A++,)
= K(z,)/bL
of z,,/R also plotted in Fig. 1.
the ratio 4”/+’ is shown in the
all three
The
authors
A,,.
I
used
a
simple
approximation
originally given by Fleischerc3) to calculate distance
L for single solute
In this, the distance
the average
aOoms in a dilute
alloy.
L depends on the bending
angle
28 of the dislocation.
For small values
of K where
0 Y K/2T P KlGb2
(5)
of the position
which is the CRSS
will review
of the slip
where
T is the line energy
is approximated
(8)
of the dislocation
which
by Gb2/2. The rc>sult is
The following
steps
as taken
by
I and II.
CALCULATION
OF SHEAR
The interacting For the estimate
dislocation y-axis. is
discussion,
(7
this angle is small
plane, zO. The third and final step takes an optimum
authors
values
results in
upper part’ of the diagram.
dislocation between the particles. From both steps a critical shear stress results
paragraphs
This estimate
3.2 Calculation of the average d&mace L step of the estimate
of the
which
“optimized”
to zOthe force K depends on the particle
radius R. The second
of the
r2 = x2 + y2 + 9.
and
line approxi-
calculated
z,,) which give rise to maximum
of the integral,
For further
position
in Fig. 1.
that this straight
valid.
with $I’ being a function A = ~.C:.E:
Z/R
of the normalized
(z,/R) . #II is plotted
Author II maintains
with
3.1
plane
I.
mation
acting on the dislocation:
,ri = 0
Slip
The dependence of the force functions 4’ and $I1 and their ratio #“/$I on the slip plane distance ZJR.
FIG.
coordinate
stress field due to coherency More precisely, particle.
it is bhc shear component
3.
19F8
of the maximum
t,he coherency
approximations
above. located
16.
OF
consists
The first is the calculation
repelling
J70L.
CALCULATIONS
calculation
steps.
METXLLURGICA,
THE
CRITICAL
K’(z,,
This quantity
depends
which is the effective
force K (zO) (I) assumed
line parallel
line approximation.) R) = A . bR - +‘(z,,/R)
Their
the
to the result (6)
on K(z,)
as well as on Az,,/R
range of influence of a particular
strain field perpendicular
of K the authors
line to be a straight
(Straight
RESOLVED
STRESS
to t,he glide plane.
Its value
will be discussed in the next section. The author based on calculations prefers a treatment Labusch,t4)
II of
which lead to similar results as calculations
* The equivalent equation of Fleischer‘s has an additional factor 1.23. For further discassion see equation (18).
bv Friedel.(@
and neglected
The result is R
(10)
L
(15).
If one uses equation
bet,ween the particles.
The range of influence of the
st’rain field perpendicular
to the glide plane is given
by the quant,ity h which corresponds
to AZ of equation
,4s it, will be shown in the discussion,
instead of equation bracket
which
to the second
Thus he came to equation
-
0.46(6fln)1!3]
(16)
(1). These equations differ by the
influences
the
result
considerably.
It reduces the value of AT* by 20-30% the dependence
(1).
(15) t,he final result is
AT” = 1.04A~,‘1[l
In this case the quantity RI.5 depends on AT, which is a measure of the curvature of the dislocation line
(9).
t$he t,erm corresponding
one in equation
and changes
on f.
equations
4. DISCUSSION
(9) and (10) are quite similar. As has been shown
3.3 The u.rerfqe over z.
From rcpations (6) and (9) the authors I got the result
the estimates authors
size and differ mainly AT(io) _=
This equation
(d!?‘)‘:“.($I)3i2(!y2
has to be averaged
in the following
which
was done
O.‘iR).
The
t,aken.
Then the range ALAR was increased until a
maximum
average
value
of
value (z,, N
[#13 * (d.~/R)]l/z
value for the average
was reached.
wa,s For
larger ranges AZ, the average decreases continuously, The maximum
average
was calculated to be 0.36. equation
(2).
independent
at AZ = 0.8R
occurred
and
With this value one obt*ains
The main point of thr volume
is that Az = 0.8R
is
fraction f of the precipi-
t#at,e. Author
II used a different estimate for AZ, i.e. the
quant,$v h in his notation.
He defines
(i)
shows
posi-
line are given in Fig. 2. The
the situation
for the slip plane
interaction
between
dislocation
and
The applied shear &ress pulls the dislocation
into the upward direction. the critical positions (ii) Attractive pulls
the
critical positions
Curves a’ and b’ then are
of a dislocation
medium (6’) interaction stress
of the slip
of critical
There are two possibilities :
Repulsive
part.icle.
for small values
for low (a’) and
forces.
interaction. dislocation
The applied shear downwards leading t,o
a” (for low interact,ion forces) or b”
(for medium forces). Curves I and II show the assumed critical positions used in the theories curves
are used forces.
by
for both
authors
I and II.
repulsive
and
These
attractive
The st,raight line approximation
(12)
which is half the mean spatial distance
between
the
Tt should be pointed out that, an addit,ional
dependence Inserting
part
interaction
h = (~/6~)1/3R
particles.
upper
z0 = 0.1 R.
by both
on t,he particle
Two examples
tions of the dislocation
way (see Fig. 1). A small range AZ/R
was selected where 4’ has its maximum
zO/B.
paragraphs
force K(zJ
show the same dependence
plane distance
(11)
in the preceding
of the interaction
on f is introduced
by t)his assumpt,ion,
equa’tions (7). (10) and (12) into equation (5)
t,he result, is zo= 0,89R
A--.
The aI-cragc over z0 was done by integrating I A+
h AT
dz,
s0
fl4) Ic
The main part of t,his integral is ”
hlfl
+‘“(s)
ds = 0.97 -
Expected Curve a’: Curve b’: Curve au:
0.445R/h
s
for duthor
Criticalposltions of a dislocation line. line positions (shown only in the upper part). low repelling interaction. medium repelling interaction. low attracting interaction. Curve b”: medium attraction interaction. Approximated line positions: I: straight line approximation II: “optimized” line approximation. FIG. 2.
h/R > 1/(4/5)
II used the value of h defined in equation
(15) (12)
ACTA
X26
I b’
METALLURGICA,
VOL.
16,
1968
intermediate position of curves a’ and a” or The “optimized” approximation II 6”.
is an
and
drastically
favours
the
attractive
case
(curves
a”
and b”). There is a big difference between theoretical curves a” or b”. The calculated
curve II and the “real”
values of K, and K,, differ by 30%.
(See equations
(6), (7) and Fig. 1). The lower part of Fig. 2 shows the crit,ical positions plane
for the dislocation
z0 = 0.89R.
Here,
I and II are plotted.
only
line on the slip
the
values K, and KI1 differ by 3%. therefore, t,hat the big difference occurs
a,s a consequence
curve II.
of the extreme
Wiedersich(@
relating
the
curvature
internal
strain
field.
For
fits quite
approximation
the
equation
dislocation
values
With
to
the
its maximum
&R/b < 0.2
his
AZ = 0.8R
line
independent
I, equation
(6) which
is
values of &R/b,
increasing
however, he found smaller values for K compared with This deviation is contrary that approximation. to the deviation
of the estimate
seems to be more realistic. tion by Wiedersich, already
by author
According
the straight
line approximation
is an upper limit for the function
over, K depends more symmetric
K.
More-
also on the sign of zolR and is no as in approximations
I and II.
to be
0.3R < x0 < 1.1 R.
It is
from
of the volume fraction f of the precipitate. author
II
used
tional
to R and a function
of f.
results in a different dependence To explain this difference, are plotted
in Fig.
assumed constant. the averaging
3.
half
This assumption
of AT,,(~).
several functions
All
other
ATE
parameters
are
Both solid curves are calculated by
method used by authors I. They differ K(z,)
by the function
adopted,
AT,, = 1.567,‘).
equation
(7) for
equation
(1).
the
using either equation or equation
The dashed
lated by the averaging (10)
h being
a range
the average spatial particle distance which is propor-
curve,
AT,, = K/bL into equation
1
8
in %
This range was estimated
(6) (lower curve, AT, = AT,‘)
4.2 The particle distance L Tf one substitutes the final result is
value. reaching
In contrast,
II and
to the calcula-
fraction
FIG. 3. Xormalized CRSS AT~ as a function of the particle volume fraction f. Solid lines: averaging method I, linear and “optimized” approximations, equations (6) and (7). Dashed line: averaainn method II. equation (7). Dash-dot line: aveiagkg method 11,kquation (15).
of
numerically
well with the straight
of authors to R.
proportional
of
6
4
volume
case better.
calculated
force K via the differential
the interaction
K(z/R)
position
2
D
It is suggested, in the first case
The force K, fit the “real”
Very recently
curve
approximations
In this case, the calculated
method force
This equation,
(7) (upper
curve
is calcu-
of author
II, using
function, however.
as given
by
neglects
the
influence of the upper limits of the averaging integral, (17)
equation
(14).
The
dashed-dotted
line takes
account this influence given by equation which is quite similar to equation
(9) in the case of
Obviously,
the averaging
method
into
(15).
II always gives
there is an h = AZ. In spite of this similarity, important difference. In equation (10) ATE is the
lower values of ATE (dash-dot
line) as compared to the
averaging
solid line).
increase of the CRSS;
differences occur for low values of the volume fraction
R/L is also fixed. equations function
it is a fixed value;
In contrast,
therefore,
the quantity
K in
(9) and (17) is a function of zO, R/L is also a is therefore of zO. The above substitution
not quite correct.
main
differences
The largest
In that case, the ranges used for the averaging
procedures
show maximum
h, equation
differences.
The quantity
(la), then is large resulting in low values
A question arises about the validity averaging between
the
estimates,
equations (1) and (a), occur by the averaging procedures. An important r61e is played by the distance over which a particle influences a dislocation on a given slip plane. This sphere of influence is determined differently
I (upper
of the average force K acting on the dislocation
4.3 The average over z The
f.
method
by authors I and II.
a range AZ where the interaction
Authors
I assumed
force K(z,/R)
has
procedures.
Let us assume a hypothetical
interaction between a dislocation which is restricted to the particle equal
and a particle volume. In this
the range AZ or h is restricted
case, undoubtedly, values
line.
of the different
to or lower
than
to
R, i.e. the particle
radius. Here, one never would average over regions where no influence occurs. Therefore, h will be independent
of
f,
thus
leading
to
an
averaging
GEROLD:
procedure
HARDENING
similar to method I.
decrease
the
CRSS.
COHERENT
As
has
this should
been
proved,
Al-Zn
averaging method II leads ho lower values of AT, t,han method
1. From this, one can conclude
I gives the better estimate.
If ,rnl and precipitate
WITH
R=LOA /
(2) therefore,
on f. EXPERIMENTS
are tile zinc
mz
20
that method
Equation
should givr the right, dependence 5. COMPARISON
XL’i
PRECII’I’YATES
If we now assume an
intera~t,io~l reaching to farther distances, not
BP
con~ent~rations in the
and in Dhe ma.trix. respectively,
the volume
fraction f is dc+ined by
where
md is t,he zinc
According
concentration
of
to equat#ion (I), one finds (AT&~/~ -_.f -
whereas, according
-f-
equations
ment,,
recent
various
A-Zn
m2
(19)
mA -
alloys
CRSS 70 as a function
mz
(20)
of
are taken.
Haberkorn”)
on
He measured
t,he
of the particle radius R and of
t’hc alloy concentration ‘nz_4. To correct for the friction force in the depleted matrix 0.2 kg/mm2 were subtracted’s)
from
dist#inct particle t)o equations validity
(19)
T”. and
of oquat,ions
corresponding
AT,
values
R were
radius
(20) (I)
to equation
and
in Fig. (2).
belonging
plotted
to
4 testing Only
a
a,ccording the
the curve
20 is a straight, line.
It
9
7 at. %
FIG. 4. Relationsbi~)between ~~~and~lllo~ic~fl(!erltration, ns.4,according to equat,ions (19) and (20) and to rmm~wemmts.‘TJ
This
(19) and (20) with the experi-
measurements
3 5 zinc concentration,
int’ersects the concentration
to equat’ion (2) one expects
(Ar,$ To compare
mA -
1
t,he alloy.
corresponds
well
axis at. pn,e= 1 .T at. % Zn. t’o
analyzing small angle X-ray
m2 =
1.75
found
by
sca.ttering.‘g)
REFERENCES 1. H. GLEITER, %. anger. Phys. 23, No. 2, 108 (1967). 2. V. GERALD and H. HABERKORN, Php. Status soli& 18, 675 (1966). 3. R. L. E'LEISCHER, Th.e Strengthening of Hrfals, editrd by D. PECKNER. Reinhold (1964). 4. R. LABUSCH, 2. Phya. 167,452 (1962). 5. J. FRIEDEL, Les Dislocatdans. Gauthier-Viliars (1956). 6. H. ~~~EDERSICH, lnt. Conf. strength Hat& Alto,y, Tokyo, 1967. 7. H. HABERKORN, Phys. Status Solidi 15,I53 (1966). 8. H. HABERKORN and I". GEROLD, Phys. Stutus Solidi 15, 167 119661. 9. 1’. &ROLL), Snzall A@e S-ray Scatter&g, Proceedings of the Conference held at. Syracuse 1965: Gordon & Breach, p. 277, 1967.