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Anti-phase domain size in quenched beta-brass
Scripta METALLURGICA
Vol. 2 , PP. 491-494, 1968 Printed in the United States
Pergamon Press, Inc.
SUMMARY* ANTI-PHASE DOMAIN SIZE IN QUENCHED BETA-BRASS E. Michael Moore, Jr. Department of Mechanical Engineering Division of Materials Science Vanderbilt University Nashville, Tennessee 37203
(Received June 3, 1968) Abstract: The results of this investigation indicate that the growth rate and final size of anti-phase domains (APD) in quenched beta-brass are determined by two factors: (a) the rate of formation and (b) the mobility of dislocation loops nucleated at and trapped in domain boundaries during the quench. It is believed that most of the domain growth occurs in the first 200°K below the critical temperature for ordering.
Experimental Procedure Disks of annealed 51.5 Cu - 48.5 gn beta-brass measuring 0.125 inches in diameter and 0.009 inches in thickness were quenched from both above and below the critical temperature for ordering (Tc) at rates varying from I00 - 100,000°F/set.
Chromel-alumel thermocouple wires
were spot welded to either side of the specimens, and the cooling curve during the quench was shown as a trace on an oscilloscope screen. from above
T
tive areas.
c
The resultant APD size for specimens quenched
= 738°K was determined from electron micrographs taken over several representa-
An average intercept distance between domain boundaries was used as the measure
of the APD size. Results Electron micrographs of annealed specimens showed them to be structureless, contain one or two dislocations per grain, and have an average grain size of about 250 microns.
All
specimens quenched from just below T c were likewise structureless and devoid of dislocations, whereas every specimen quenched from above T
c
contained plentiful dislocation networks clearly
outlining APD. The effect of quenching rate on APD size in beta-brass can be separated into three regions:
(a) for rates greater than 105 °F/set, the APD size must decrease rapidly with
increasing quenching rates because for this rate the domain size is already 0.9 microns
491
ANTI-PHASE DOMAIN SrZE IN QUENCHED BETA-BRASS
492 (b)
for
effect
rates
b e t w e e n 10 4 - 10 5 ° F / s e c ,
on t h e APD s i z e ,
each grain
contains
a variation
a s shown i n F i g .
a single
of quenching
1, a n d ( c )
for rates
rate
Vol, 2, No. 9
has practlcally
on t h e o r d e r
no
o f 10 2 ° F / s e c ,
APD.
-16 x[v:
,5
dilt~cl r ~ .
-t 4
m,vl,
-q3 ,.,,eaf sc..e, i~l ,.tl m . t l ol
"J2
. ivl. wIech,. 9 ,or.
i i ,i.O
09
r~
' ~,o~o'
' ' ~
zo.ooo
O U ( N C . I N S ~ATE tN t H E W C I ~ I I Y
~,ooo
OF "~
,oo,ooo
zoc~o
FIG. 1 Variation of the APD size of beta-brass with the quenching rate in the vicinity of T • c
(UNITS, "F/~Cl
Discussion When b e t a - b r a s s observed
to nucleate
two r e a s o n s :
(a)
is quenched from above Tc, a t t h e APB.
large
numbers of dlslocation
C u p s c h a l k a n d Brown ( 1 ) h a v e s h o w n t h a t
the vacancy concentration
loops this
are
occurs
a t t h e APB c a n b e m o r e t h a n an o r d e r
for
of
magnitude greater than in the interior of the domain and (b) a dlslocation loop at an APB erases part of the boundary by the removal of
a
layer of atoms.
Consequently,
as beta-brass
is quenched, excess vacancies anneal out preferentially at the APB and condense to form dislocation loops. A slmple plane strain calculation shows that the maximum posslble strain energy induced by quenching stresses in the specimens used is three orders of magnitude less than the binding energy between a dislocation loop lying in an APB and the APB itself. as noted previously, electron micrographs of specimens quenched from below T appreciable numbers of dislocations induced by quenching stresses alone.
c
Furthermore , showed no
Thus, the
appearance of dislocation networks outlining essentially dlslocatlon-free regions in every specimen quenched from above T c is the result of the nucleation of dislocation loops in the APB.
Since (a) there is insufficient quenching strain energy to break the dislocation loops
away from the APB and (b) there are large numbers of loops at the boundaries, the rate of
Vol. 2, No. 9
ANTI-PHASE D O M A I N SIZE IN Q U E N C H E D
BETA-BRASS
493
domain growth and the final domain size are limited by the rate of formation and the mobility of these loops. During a quench excess vacancies condense into dislocation loops at the APB, and unless these loops can move, the APB in that locality is pinned.
There are two possible means by
which the loops can move in such a manner that the APB will not be pinned: (b) prismatic glide.
(a) climb and/or
It is doubtful that many dislocation loops move appreciable distances
by climb in the few milliseconds during which the temperature is high enough so that climb is possible.
Prismatic glide may be a significant factor affecting the growth rate and
final domain size, however, since the observations of Silcox and Hirsch (2) indicate that a large number of the dislocation loops may be prismatic. For temperatures between T
c
and about 500°K, a decrease in temperature should result in
an increased mobility of prismatic loops because these loops can glide without the creation of a cylindrical APB trail only when there is perfect long range order.
On the other hand,
as the temperature drops there is a concomitant decrease in diffusivity, and at some temperature roughly about 500°K this factor will become dominant.
For temperatures below
this, it will be increasingly difficult for a growing APB to drag a prismatic loop along with ~t. Once a dislocation loop is nucleated at an APB, the boundary will be locally pinned unless (a) the loop is prismatic and (b) the direction of boundary motion is in the prismatic glide direction.
The rate of domain growth will be determined by (a) the rate at which
dislocation loops are nucleated by the condensation of vacancies on APB and (b) the mobility of the prismatic loops. the system falls
The final APD size will probably be reached when the temperature of
below about 500°K.
The excess vacancies that anneal out between 500°K and
the bath temperature cause the loops to spiral into the observed tangled helices. The proposed theory explains the fact that for quenching rates on the order of 100°F/set each grain contains a single APD.
During rapid quenches, the excess vacancies condense into
dislocation loops on the APB because this is the quickest way they can be eliminated.
The
free energy of the system can be further lowered, however, if the vacancies have time to anneal completely out, and for slower quenches the brass remains at high enough temperatures for sufficiently long times so that this is possible.
Hence, dislocation loops are not
formed at the APB, and the domain growth is not impeded. is limited only by the grain size of the specimen.
The APD size under these conditions
494
ANTI-PHASE DOMAIN SIZE IN QUENCHED BETA-BRASS
Vol. 2, No. 9
References I.
Cupschalk, S. G. and Brown, N., "Observations of Defects in Beta Brass," Acta Met. 15, 847 (1967).
2.
Silcox, P. B. and Hirsch, P., "Dislocation Loops in Neutron-irradiated Copper," Phil. Mag. ~, 1356 (1959).
*This is a sununary of a M.S. thesis with the same title (56 pages) submitted to the Faculty of the Graduate School of Vanderbilt University.
The research was supported
jointly by the Atomic Energy Comission and the National Science Foundation under grant numbers AT-(40-I)-3091 and GZ-604.
Copies may be obtained from the author st the cost of
reproduction also from the publisher.
Vol. 2 , PP. 491-494, 1968 Printed in the United States
Pergamon Press, Inc.
SUMMARY* ANTI-PHASE DOMAIN SIZE IN QUENCHED BETA-BRASS E. Michael Moore, Jr. Department of Mechanical Engineering Division of Materials Science Vanderbilt University Nashville, Tennessee 37203
(Received June 3, 1968) Abstract: The results of this investigation indicate that the growth rate and final size of anti-phase domains (APD) in quenched beta-brass are determined by two factors: (a) the rate of formation and (b) the mobility of dislocation loops nucleated at and trapped in domain boundaries during the quench. It is believed that most of the domain growth occurs in the first 200°K below the critical temperature for ordering.
Experimental Procedure Disks of annealed 51.5 Cu - 48.5 gn beta-brass measuring 0.125 inches in diameter and 0.009 inches in thickness were quenched from both above and below the critical temperature for ordering (Tc) at rates varying from I00 - 100,000°F/set.
Chromel-alumel thermocouple wires
were spot welded to either side of the specimens, and the cooling curve during the quench was shown as a trace on an oscilloscope screen. from above
T
tive areas.
c
The resultant APD size for specimens quenched
= 738°K was determined from electron micrographs taken over several representa-
An average intercept distance between domain boundaries was used as the measure
of the APD size. Results Electron micrographs of annealed specimens showed them to be structureless, contain one or two dislocations per grain, and have an average grain size of about 250 microns.
All
specimens quenched from just below T c were likewise structureless and devoid of dislocations, whereas every specimen quenched from above T
c
contained plentiful dislocation networks clearly
outlining APD. The effect of quenching rate on APD size in beta-brass can be separated into three regions:
(a) for rates greater than 105 °F/set, the APD size must decrease rapidly with
increasing quenching rates because for this rate the domain size is already 0.9 microns
491
ANTI-PHASE DOMAIN SrZE IN QUENCHED BETA-BRASS
492 (b)
for
effect
rates
b e t w e e n 10 4 - 10 5 ° F / s e c ,
on t h e APD s i z e ,
each grain
contains
a variation
a s shown i n F i g .
a single
of quenching
1, a n d ( c )
for rates
rate
Vol, 2, No. 9
has practlcally
on t h e o r d e r
no
o f 10 2 ° F / s e c ,
APD.
-16 x[v:
,5
dilt~cl r ~ .
-t 4
m,vl,
-q3 ,.,,eaf sc..e, i~l ,.tl m . t l ol
"J2
. ivl. wIech,. 9 ,or.
i i ,i.O
09
r~
' ~,o~o'
' ' ~
zo.ooo
O U ( N C . I N S ~ATE tN t H E W C I ~ I I Y
~,ooo
OF "~
,oo,ooo
zoc~o
FIG. 1 Variation of the APD size of beta-brass with the quenching rate in the vicinity of T • c
(UNITS, "F/~Cl
Discussion When b e t a - b r a s s observed
to nucleate
two r e a s o n s :
(a)
is quenched from above Tc, a t t h e APB.
large
numbers of dlslocation
C u p s c h a l k a n d Brown ( 1 ) h a v e s h o w n t h a t
the vacancy concentration
loops this
are
occurs
a t t h e APB c a n b e m o r e t h a n an o r d e r
for
of
magnitude greater than in the interior of the domain and (b) a dlslocation loop at an APB erases part of the boundary by the removal of
a
layer of atoms.
Consequently,
as beta-brass
is quenched, excess vacancies anneal out preferentially at the APB and condense to form dislocation loops. A slmple plane strain calculation shows that the maximum posslble strain energy induced by quenching stresses in the specimens used is three orders of magnitude less than the binding energy between a dislocation loop lying in an APB and the APB itself. as noted previously, electron micrographs of specimens quenched from below T appreciable numbers of dislocations induced by quenching stresses alone.
c
Furthermore , showed no
Thus, the
appearance of dislocation networks outlining essentially dlslocatlon-free regions in every specimen quenched from above T c is the result of the nucleation of dislocation loops in the APB.
Since (a) there is insufficient quenching strain energy to break the dislocation loops
away from the APB and (b) there are large numbers of loops at the boundaries, the rate of
Vol. 2, No. 9
ANTI-PHASE D O M A I N SIZE IN Q U E N C H E D
BETA-BRASS
493
domain growth and the final domain size are limited by the rate of formation and the mobility of these loops. During a quench excess vacancies condense into dislocation loops at the APB, and unless these loops can move, the APB in that locality is pinned.
There are two possible means by
which the loops can move in such a manner that the APB will not be pinned: (b) prismatic glide.
(a) climb and/or
It is doubtful that many dislocation loops move appreciable distances
by climb in the few milliseconds during which the temperature is high enough so that climb is possible.
Prismatic glide may be a significant factor affecting the growth rate and
final domain size, however, since the observations of Silcox and Hirsch (2) indicate that a large number of the dislocation loops may be prismatic. For temperatures between T
c
and about 500°K, a decrease in temperature should result in
an increased mobility of prismatic loops because these loops can glide without the creation of a cylindrical APB trail only when there is perfect long range order.
On the other hand,
as the temperature drops there is a concomitant decrease in diffusivity, and at some temperature roughly about 500°K this factor will become dominant.
For temperatures below
this, it will be increasingly difficult for a growing APB to drag a prismatic loop along with ~t. Once a dislocation loop is nucleated at an APB, the boundary will be locally pinned unless (a) the loop is prismatic and (b) the direction of boundary motion is in the prismatic glide direction.
The rate of domain growth will be determined by (a) the rate at which
dislocation loops are nucleated by the condensation of vacancies on APB and (b) the mobility of the prismatic loops. the system falls
The final APD size will probably be reached when the temperature of
below about 500°K.
The excess vacancies that anneal out between 500°K and
the bath temperature cause the loops to spiral into the observed tangled helices. The proposed theory explains the fact that for quenching rates on the order of 100°F/set each grain contains a single APD.
During rapid quenches, the excess vacancies condense into
dislocation loops on the APB because this is the quickest way they can be eliminated.
The
free energy of the system can be further lowered, however, if the vacancies have time to anneal completely out, and for slower quenches the brass remains at high enough temperatures for sufficiently long times so that this is possible.
Hence, dislocation loops are not
formed at the APB, and the domain growth is not impeded. is limited only by the grain size of the specimen.
The APD size under these conditions
494
ANTI-PHASE DOMAIN SIZE IN QUENCHED BETA-BRASS
Vol. 2, No. 9
References I.
Cupschalk, S. G. and Brown, N., "Observations of Defects in Beta Brass," Acta Met. 15, 847 (1967).
2.
Silcox, P. B. and Hirsch, P., "Dislocation Loops in Neutron-irradiated Copper," Phil. Mag. ~, 1356 (1959).
*This is a sununary of a M.S. thesis with the same title (56 pages) submitted to the Faculty of the Graduate School of Vanderbilt University.
The research was supported
jointly by the Atomic Energy Comission and the National Science Foundation under grant numbers AT-(40-I)-3091 and GZ-604.
Copies may be obtained from the author st the cost of
reproduction also from the publisher.