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Diffusion and creep in beryllium oxide
JOURNALOFNUCLEARMATERIALS12,No.3
DIFFUSION
(1964)337-339,NORTH-HOLLANDPUBLISHINGCO.,AMSTERDAM
AND
CREEP
IN
BERYLLIUM
OXIDEt
S. B. AUSTERMAN
Atomics International, Canoga Park, California, USA and R. CHANG
North American Aviation
Science Center, Canoga Park, California, USA Received 5 February 1964
The interrelationship
the creep diffusion
between creep and diffusion
in Be0 was discussed by one of the authors several years agol).
A recapitulation
time appears appropriate
of the subject
deformation Herringa),
A model of diffusion-controlled
based
on a stress-directed
flow of lattice vacancies. tal
evidence19 4*5, show
creep of polycrystalline
Accumulated that the Be0
activation
diffusional
tempe-
in polycrystalline larger than
from single crystals and have lower
energies, suggesting that 0 diffuses along in polycrystalline
BeO. The
data are not included in fig. 1 for reasons of clarity. The “steady-state”
experimenupon
coefficients
orders of magnitude
the grain boundaries
and
creep of polyorystalline
could be controlled
“steady-state”
depends
are several
those obtained
creep
by Nabarro2)
d) The 0 diffusion Be0
since more accurate mea-
has been proposed
at a given
rature.
at this
surements of both the diffusion of Be and 0 in Be0 are available.
coefficients
by the lattice diffusion of Be or
the grain boundary
grain
diffusion
of 0. Since the creep
size and stress in a manner predicted by the Nabarro-
activation
Herring
agree quite well with the Be lattice diffusion
mechanism.
and 0 is involved
Since the motion
in mass transport,
of both Be
energy
and creep diffusion
ving species should control the creep rate. Compari-
data, it is concluded
that “steady-state
sons of the chemical diffusion data with creep diffu-
polycrystalline
is controlled
sion data are shown in fig. 1. The following
diffusion
points
are noted:
Be0
of the Be ions.
data
diffusion ” creep of
by
the
It is assumed
lattice that
0
diffuses much more rapidly along the grain bounda-
a) The activation “steady-state”
energies for Be diffusion and for
ries and hence is not the rate controlling
creep all lie within the range of 4.0
similar mechanism
to 5.0 electron volts. calculated
has been proposed
species. A
by Paladin0
and CobleT) for the creep of polycrystalline
b) The Be diffusion coefficients coefficients
coefficients
while not at all with the 0 grain boundary
the slower mo-
Be0
and the diffusion
from creep data agree within
comes very large.
an order of magnitude. c) The 0 diffusion coefficients
The Be ion diffuses is practically (single crystal data)
are much lower than the Be diffusion (single crystal as well as polycrystalline
Al,O,.
The model does not apply when the grain size be-
temperature
coefficients
range
isotropic
in the
1500 to 2000 “C, as shown
in
fig. 2. This suggests that the diffusion of Be in Be0
data) and
is by the vacancy diffusion
t This work was supported in part by the U. S. Atomic Energy Commission.
would
mechanism,
give
than is experimentally 337
as interstitial
rise to a geater observed.
Be
anisotropy
This is consistent
S. B. AUSTERMAN
338
Fig. 1.
Comparison
of chemical
diffusion
AND
R. CHANG
coefficients and creep diffusion Be7 chemical diffusion.
coefficients
in BeO. Creep diffusion
and
DIFFUSION AND CREEP IN BERYLLIUM OXIDE DIFFUSION
.
0
PARALLEL
n
PERPENDICULAR
To
339 COEFFICIENT
Q IMPURITY
c-Ax6
TO C-AXIS
Be0
IMPURITY-EXCESS
VALENCE
PRODUCT
Fig. 3. Effect of impurities on diffusion penetration of Be7 in BeO. (Abscissa, in arbitrary units, is plotted as ZC~ (nip2), where Ciis the concentration of cation impurity i
. 1
4.4
I,
Id
1
4.6
l/TX
Fig. 2.
I
5.0
4.0
I1
I
5.2
54
I
T'8,
represent of valency “i. Symbols in figure, circles and data points from Be0 of three different origins.)
I
5.6
104(+)
Diffusion penetration of Be’ in monocrystalline and polycrystalline BeO.
are partly
bound
extremely
interesting
to the impurities.
It should
to undertake
be
similar studies
of high purity Be0 in order to confirm the present findings.
with the observed
enhancement
impure BeO, illustrated Interpretation
of Be diffusion
in
in fig. 3.
of the Be diffusion in Be0 in terms
of a vacancy mechanism is, however, not completely satisfactory. represent
It is believed
diffusion
the variations vation
region
in the diffusion coefficients
data where
and acti-
energies are due to impurity-vacancy
ciation and to impurity phenomena
NaCi
that the present
in the extrinsic
described
containing
interpretation
precipitation, by Dreyfus
divalent
‘) 2,
and Nowick
impuritiess).
This
Y 4,
cation impurity
and Be
is quite large such that in the tempera-
ture range 1000 to 1700 “C the Be ion vacancies
1 (1959) 174-81
Conference
on Strength
of Solids,
1948) p. 75
C. Herring, J. Appl. Phys. 21 (1950) 437 R. R. Vandervoort
and W. L. Barmore, J. Am. Ceram.
Sot. 46 (1963) 1804
7
for new
R. Chang, J. Nucl. Mat. F. R. N. Nabarro,
The Physical Society (London,
similar to the
suggests that the energy of associa-
tion between a polyvalent ion vacancy
asso-
References
“)
Second Annual Report -
High Temperature
and Reactor
Development
Component
Materials
Program.
I. - Materials. GEMP-177A,
General Electric
sion Laboratory
(Feb. 28, 1963)
J. B. Holt, Radiation
Department
UCRL-6940
(Nov. 28,
1962),
Vol.
Propul-
Lawrence
Laboratory
‘)
A. E. Paladin0 and R. L. Coble, J. Am. Ceram. Sot. 46
?
R. W. Dreyfus
(1963) 133-6 and A. S. Nowick,
Suppl. (1962) 473-477
J. Appl.
Phys. 33
DIFFUSION
(1964)337-339,NORTH-HOLLANDPUBLISHINGCO.,AMSTERDAM
AND
CREEP
IN
BERYLLIUM
OXIDEt
S. B. AUSTERMAN
Atomics International, Canoga Park, California, USA and R. CHANG
North American Aviation
Science Center, Canoga Park, California, USA Received 5 February 1964
The interrelationship
the creep diffusion
between creep and diffusion
in Be0 was discussed by one of the authors several years agol).
A recapitulation
time appears appropriate
of the subject
deformation Herringa),
A model of diffusion-controlled
based
on a stress-directed
flow of lattice vacancies. tal
evidence19 4*5, show
creep of polycrystalline
Accumulated that the Be0
activation
diffusional
tempe-
in polycrystalline larger than
from single crystals and have lower
energies, suggesting that 0 diffuses along in polycrystalline
BeO. The
data are not included in fig. 1 for reasons of clarity. The “steady-state”
experimenupon
coefficients
orders of magnitude
the grain boundaries
and
creep of polyorystalline
could be controlled
“steady-state”
depends
are several
those obtained
creep
by Nabarro2)
d) The 0 diffusion Be0
since more accurate mea-
has been proposed
at a given
rature.
at this
surements of both the diffusion of Be and 0 in Be0 are available.
coefficients
by the lattice diffusion of Be or
the grain boundary
grain
diffusion
of 0. Since the creep
size and stress in a manner predicted by the Nabarro-
activation
Herring
agree quite well with the Be lattice diffusion
mechanism.
and 0 is involved
Since the motion
in mass transport,
of both Be
energy
and creep diffusion
ving species should control the creep rate. Compari-
data, it is concluded
that “steady-state
sons of the chemical diffusion data with creep diffu-
polycrystalline
is controlled
sion data are shown in fig. 1. The following
diffusion
points
are noted:
Be0
of the Be ions.
data
diffusion ” creep of
by
the
It is assumed
lattice that
0
diffuses much more rapidly along the grain bounda-
a) The activation “steady-state”
energies for Be diffusion and for
ries and hence is not the rate controlling
creep all lie within the range of 4.0
similar mechanism
to 5.0 electron volts. calculated
has been proposed
species. A
by Paladin0
and CobleT) for the creep of polycrystalline
b) The Be diffusion coefficients coefficients
coefficients
while not at all with the 0 grain boundary
the slower mo-
Be0
and the diffusion
from creep data agree within
comes very large.
an order of magnitude. c) The 0 diffusion coefficients
The Be ion diffuses is practically (single crystal data)
are much lower than the Be diffusion (single crystal as well as polycrystalline
Al,O,.
The model does not apply when the grain size be-
temperature
coefficients
range
isotropic
in the
1500 to 2000 “C, as shown
in
fig. 2. This suggests that the diffusion of Be in Be0
data) and
is by the vacancy diffusion
t This work was supported in part by the U. S. Atomic Energy Commission.
would
mechanism,
give
than is experimentally 337
as interstitial
rise to a geater observed.
Be
anisotropy
This is consistent
S. B. AUSTERMAN
338
Fig. 1.
Comparison
of chemical
diffusion
AND
R. CHANG
coefficients and creep diffusion Be7 chemical diffusion.
coefficients
in BeO. Creep diffusion
and
DIFFUSION AND CREEP IN BERYLLIUM OXIDE DIFFUSION
.
0
PARALLEL
n
PERPENDICULAR
To
339 COEFFICIENT
Q IMPURITY
c-Ax6
TO C-AXIS
Be0
IMPURITY-EXCESS
VALENCE
PRODUCT
Fig. 3. Effect of impurities on diffusion penetration of Be7 in BeO. (Abscissa, in arbitrary units, is plotted as ZC~ (nip2), where Ciis the concentration of cation impurity i
. 1
4.4
I,
Id
1
4.6
l/TX
Fig. 2.
I
5.0
4.0
I1
I
5.2
54
I
T'8,
represent of valency “i. Symbols in figure, circles and data points from Be0 of three different origins.)
I
5.6
104(+)
Diffusion penetration of Be’ in monocrystalline and polycrystalline BeO.
are partly
bound
extremely
interesting
to the impurities.
It should
to undertake
be
similar studies
of high purity Be0 in order to confirm the present findings.
with the observed
enhancement
impure BeO, illustrated Interpretation
of Be diffusion
in
in fig. 3.
of the Be diffusion in Be0 in terms
of a vacancy mechanism is, however, not completely satisfactory. represent
It is believed
diffusion
the variations vation
region
in the diffusion coefficients
data where
and acti-
energies are due to impurity-vacancy
ciation and to impurity phenomena
NaCi
that the present
in the extrinsic
described
containing
interpretation
precipitation, by Dreyfus
divalent
‘) 2,
and Nowick
impuritiess).
This
Y 4,
cation impurity
and Be
is quite large such that in the tempera-
ture range 1000 to 1700 “C the Be ion vacancies
1 (1959) 174-81
Conference
on Strength
of Solids,
1948) p. 75
C. Herring, J. Appl. Phys. 21 (1950) 437 R. R. Vandervoort
and W. L. Barmore, J. Am. Ceram.
Sot. 46 (1963) 1804
7
for new
R. Chang, J. Nucl. Mat. F. R. N. Nabarro,
The Physical Society (London,
similar to the
suggests that the energy of associa-
tion between a polyvalent ion vacancy
asso-
References
“)
Second Annual Report -
High Temperature
and Reactor
Development
Component
Materials
Program.
I. - Materials. GEMP-177A,
General Electric
sion Laboratory
(Feb. 28, 1963)
J. B. Holt, Radiation
Department
UCRL-6940
(Nov. 28,
1962),
Vol.
Propul-
Lawrence
Laboratory
‘)
A. E. Paladin0 and R. L. Coble, J. Am. Ceram. Sot. 46
?
R. W. Dreyfus
(1963) 133-6 and A. S. Nowick,
Suppl. (1962) 473-477
J. Appl.
Phys. 33