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Formation of stabilized zirconia with rare earth fluorides
Journal of Fluorine Chemistry, 40 (1988)
FommIo~
0F
375-385
375
ZIRCONIA WITH RARE'EARTH FLUORIDES*
STABILIZED
Masayuki TAKASHIMA and Gentaro KANO
Department of Industrial Chemistry, Faculty of Engineering, Fukui University, 3-9-l Bunkyo, Fukui-shi, 910 (Japan)
SUMMARY
New
reactions
to
prepare stabilized zirconia using rare
earth fluorides as the solid electrolyte
have been examined by
means of X-ray diffraction, DTA and EPMA methods.
The
rare earth fluorides of yttrium and samarium through reacted with zrO2 to form new (LnFSZ)consisting of (2x+3y)Zr02
the
of stabilized
types
ternary
system
eleven lutetium zirconias
of zr02-Ln203-LnF3.
+ (4y+2z)LnF3 = 2(zro2)x(Ln203)y(LnF3)s + 3~zrF4
where x, y and z represent the stabilizing composition at which the homogeneous
solid solution with the fluorite structure is
formed, and x + y + z = 1.
This reaction begins to take place
at about 600 C and is completed
by firing at temperatures
ranging from 1000 to 1300 OC for a few hours in an argon atmosphere. INTRODUCTION Zirconium
oxide,
zr02,
is
one
of the most
interesting
materials in technology. So-called stabilized ceramic zirconia is well-known as the oxide ion conducting solid elecused for fuel cells trolyte (II and oxygen sensors[2], and *
also
has
attracted
special
interest -recently
in
Dedicated to Emeritus Professor W.K.R.Musgrave on the occasion of his 70th birthday.
0022-1139/88/$3.50
0 Elsevier Sequoia/Printed in The Netherlands
376
zirconium-toughened phase it
changes
from
Therefore, or rare
and
earth
earth
So,we
wish
oxide
and
above
studying
fluorides
fluoride
the solid
earth
earth
react
between
examined
analysis
and
eleven
atmosphere,
structure,
reaction
rare
or
with
that
zirconias,LnFSZ,are phase
fluorides
thermal
reaction
in an argon
the cubic
stabilized
to report
differential
with
earth
[5].
phase
could
at up to 13OO'C
[4].
alkaline
alkaline
of
a
4% when
tetragonal
with
1600°C
found that zirconia
exhibits
of about
the
the solid
solutions
rare
to
stabilized
by firing
fluorides
zirconia
contraction
monoclinic
various and
and that solid
Pure
[3].
a volume
is usually
been
elements
rare
the
oxides
have
zirconia earth
with
zirconia
earth
We
rare
ceramics
transformation
formed.
between
by X-ray
is, the
zirconium
diffraction,
electron
probe
micro
analysis.
RESULTS
AND DISCUSSION
Fig.1
shows
systems, endothermic From X-ray marked
stabilized
steeply
even
ionic
at 1400
about
this
radii
than
crystal crystal
size.
of the fluorite
type
that the
formation
or rare earth
For rare
for the
earth
ionic
is surrounded
zirconia
the high
[4].
the
formation earth
ions
0.92 i and
elements does
not
with proceed
point
site is
is to be little
in
peaks of
is at
size of the cation
the octa-coordinate
1.27 i
OC.
fluorides.In
that the break
the possible
three
due to the transformat-
1.0 i , this reaction
The site is
were
or
1400
the tripositive rare radius of Ln 3+ up to about
0.93 i if there
radius
the
temperatures
OC. It is reasonable
structure.
Two up to
confirmed
with
of Zr02-Lx-G3
Lu.
against
the crystal
substitutionally
to be about
wa6
of zirconia
the DTA peak
0.92 i., because
occupy
it
and the others
zirconias
over
through
in each DTA curve
data,
structure
are plotted
for the reaction Sm
corresponded
zirconia
by increasing
Y and
appeared
arrows
of stabilized
larger
are
diffraction
ion of crystal
more
Ln
peaks
by
Fig.2
the DTA curves
where
calculated
disordering
with
to
of the
oxide
ions whose
temperature
structure
Temperature
('C)
1300
1200
1000
1100
v
w
Zr02-YbF3
P
f
I
\
V-Y
V
v
I
ZrOq-TmF34p.
ZrO2-ErF37;
Zr02-YF3
ZrOZ-DyF3
ZrOq-TbF3
ZrO2-GdF3
ZrO2-EuF3
Zr02-SmF3
1400
II
(Heating rate; 15'C/min, In argon stream)
Fig.l.DTA curves for the reaction between Zr02 and various LnF3
r
0.80
1000 0.85
Ln3+ radius
0.90
(i)
0.95
Fig.2.Relationship between the DTA peak temperature and Ln3+ radius.
9 PI
E 1 < 1200 1 2 2 y 1100
E; 0 1300
1400
1.00
378
During rare earth
the
solid
fluorides
phase. reaction of
Y
between
and Sm through Lu,
zirconia and the weight of
sample mixture decreased about 15 wt% at the most. Fig. 3 shows the change in weight
for zirconia-YF3,
-EuF3 and -HoF3,after Any systems
firing for three hours at various temperatures. begin to decrease "C, the weight
in weight at about 600°C , and at around 900
decrease
becomes
great ,and then , above about
1100 'C, it reaches almost the limit decrease of about 15 wt%. The
plot
of
the
weight
decrease
s
time reveals that the
greater part of the weight decrease is over within
a
half
hour, as shown in Fig. 4.
600
800
1000
1200
1300
Reaction temperature ('C) Fig.3.Relationship between the weight change and the reaction temperature for (Zr02)0_75(LnF3)0.25 Reaction time; 3 h, In argon stream O:Zr02-EuF3, l :ZrO2-HoF3, @::r02-YF3,
an
379
L 0
I
I
I
I
I
1
2
3
4
5
Reaction time (h) Fig.4.Weight decrease-time curves for the reaction of Zr02-LnF3 systems at 12OO'C in an argon stream
l :ZrO2-HoF9,
0 :ZrO2-EuF9,
Fig.5
shows
the
X-ray
@:Zr02-YF3.
diffraction
powder
patterns
products for zirconia-holmium fluoride mixtures HoF3 which were prepared by firing at various three hours in an argon atmosphere.
of 25
with
the mol%
temperatures for
In the pattern for 500 "C,
all diffraction lines are due to only the starting materials of the monoclinic
zirconia and hexagonal
is, at this temperature
no reaction
holmium
fluoride, that
is found to take place.
At 700 OC, the diffraction lines of HoF3 have disappeared
and
some new lines begin to appear. These are identified to be
due
to the holmium fluoride oxide, HoFO. In the pattern for 900 'C, the lines assigned to the cubic-zirconia
are
dominant.
The
pattern for 1100 'C shows that this product is the single phase of the cubic with the crystal lattice constant a,:5.16 i.
HOW-
ever, even at 1100
tube
'C,
in case of using a sealed alumina
for a reaction vessel, as the bottom profile in Fig. 5
shows,
the product is not a single phase but consists of three
phases
of the cubic zirconia and two of starting materials.
This fact
suggests that the solid phase reaction cannot be driven to completion if the volatile products cannot escape from the tion system.
reac-
380
Open boat w/ i.
Seal tubing
lloo"c
30
40
50
60
Diffraction angle (29'), CuKs Fig.5.X-Ray diffraction patterns of products from (Zr02)Q.75(HoF3)Q.25 at various temperatures; 0: Monoclinic Zr02, 0: Rhombohedral HoFO,
Fig.6
shows
the
0: Hexagonal HoF3, 0: Cubic zirconia.
change
in weight
plotted
against
content of LnF3 in a starting mixture in the case of at 12QO'C for three hours in an argon stream.
the
reaction
The dotted area
shows the contents of LnF3, at which the homogeneous
phase of
cubic zirconia is obtained. The weight decreases almost linearly with increasing LnF3 content and the weight change is found to stop at around the content of fluoride rich end of the range in which the homogeneous cubic phase is formed. The limit of the weight decrease is between 13 and 15 wt%, and seems depend to a limited extent on the species of rare earth.
to
381
Monoclinic Cubic ZrO24
0
10
20
Cubic / / L
30
Content of LnF3
Cubic + LnF3
40
50
(mol%)
Fig.6.Relationship between weight change and the content of LnF in a start mixture (Reaction at 1a00°C for 3 h); 0: EuF3, 0: HoF3, c): YF3.
Next,we
attempted
to analyze
the products
by electron
probe micro analysis. Fig.7 is the spectrum of the sublimate trapped in a filter placed at the outlet of the argon line and the
solid
product remaining in a alumina boat for a Zr02-HoF3
hours. reaction at llOO‘°C for three after system sublimate consists of aluminum, zirconium and fluorine.
The On
the other hand, the components of the solid product are zircopresent in the nium, holmium, fluorine and oxygen. Aluminium sublimate sublimes
is assumed to come from aluminum fluoride which above about 700 'C [71, resulting from the reaction
between zirconium tetrafluoride and the sample boat or reaction tubing made of aluminum oxide.
382
Sublimate
20.0
15.0
10.0 . Ho-La
I
I
I
10.0
15.0
20.0
Wave
length
(A)
spectrum of the sublimate and the Fig.7.E.P.M.A. cubic product for (ZrO2)0,75(HoF3)0.25.
Putting
together
the above
phase
reaction
process
earth
fluoride
begin
and
zirconium
fluoride anionic zirconia
oxide
(LnF-SZ)
rare
place
earth
fluoride
goes
the reaction
the
zirconium
sublimes
tetrafluoride
estimated
the
Zirconia
8.
with
each
rare
earth
are formed.
which
from
and
takes
tetrafluoride, out
in Fig.
to react
tetrafluoride
diffusion and
as shown
results,we
other
system. is formed,
or rare
earth
that mutual
interface
,and at that above
rare 6OO'C
means
This
easily
and
at about
oxide
on the solid
600
Above
solid
time
between zirconium
'C,is formed
900°C,
it sublimes
as soon out
and as
, and
383
many
vacant
crystal tive
sites
lattice
rare earth
and can readily stabilized
of tetrapositive
ions begin occupy
zirconia
as the ternary
ion are born
with
system
sites.
the cubic
consisting
y
Consequently,
structure
of ZrO2,
is easily
Ln203
800% yLn203
+ 1.5yZrF4
+ zLnF3
r---7 ZrF4 1
_!
900%
L---’
Subl.
Y Cubic-(Zr02)x(Ln203)y(LnF3)z LnF-SZ ZrF4
Solid
interface Ln3+
Ln3+ Zr4+
Zr4+
I
Ln3+F-
02Zr4+02-
02;r4+02-
F‘Zr4+p2-
02-
02-
02-
02-
02-
ZrO2 lattice
phase
reaction
F-
FLn3+
.+LnF3
process
between
the created
and LnF3.
LnFO
Fig.8.Solid LnF3.
in a
On the other hand, the triposito migrate into the zirconia lattice
the vacant
600 xZr02
zirconium
of zirconia.
Zr02 and
384
In Table and
the
decrease
during
conducting found
1 are summarized
composition
they
Details
lytes.
subsequent
TABLE
reaction
properties
that
the optimum
of products for
three
of LnF-SZs
function
as oxide
of their
reaction
calculated hours.
have
been
the
The
electrical
weight
examined,
ion conducting
characteristics
temperature
from
will
and
solid
we
electro-
be reported
in
a
paper.
1
Optimum
reaction
Reaction
condition
and the composition
Composition
mixture
Reaction temp. -time LnFS(mol%)('C) (h)
System
of LnF-SZ
of LnF-SZ
(Zr02)x(Ln203)y(LnF3)z
Zr02-SmF3
25
1250
3
0.80
0.13
0.07
ZrOZ-EuFS
25
1200
3
0.79
0.10
0.11
ZrOZ-GdFS
25
1200
3
0.78
0.09
0.13
ZrOZ-TbFS
25
1200
3
0.78
0.10
0.12
ZrOZ-DyFS
25
1200
3
0.78
0.10
0.12
ZrOZ-HoFS
25
1200
3
0.78
0.10
0.12
Zr02-YF3
25
1200
3
0.78
0.09
0.13
ZrOZ-ErF9
25
1200
3
0.78
0.09
0.13
Zr02-TmFS
25
1200
3
0.79
0.10
0.11
Zr02-YbFS
25
1100
3
0.78
0.10
0.12
Zr02-LuF9
25
1100
3
0.78
0.10
0.12
EXPERIMENTAL
The rare earth cially
obtained
Fluorides (passed with of
and
and
were
zirconium
400 mesh
each other the
fluorides
mixture
sieve)
and zirconium
guaranteed oxides,
in the appropriate were
which
and thoroughly
oxide
were
to be 99.9-99.99 were dried,
finely were
% pure. powdered
fully
compositions.About
put into an alumina
commer-
boat made
mixed
two grams of
99.5%
385
pure A1203, and heated at a temperature 3 h in an argon temperature, diffraction
atmosphere.
the products , electron-probe
thermal analysis.
After were
from 200to1400 cooling
analyzed
slowly
by means
microanalysis
OC for to room
of X-ray
and differential
The details of these analysis methods were
according to our previous reports [81.
ACKNOWLEDGMENTS Acknowledgment
is made to the Iwatani Naoji Foundation's
Research Grant for support of this research.
We are grateful
to Prof. N Watanabe for helpful advice and to Mr. H. Uno for Xray analysis.
REFERENCES T. Takahashi, in J. Hladik (ed.) 'Physics of Electrolytes',Vol.2, Academic Press, London (1972) 989. K.S. Goto and W. Pluschkell, in J. Hladik (ed.) 'Physics of Electrolytes', Vo1.2, Academic Press, London (1972) 539. R.C.Garvie, R.H. Hannink and R.T. Pascoe, Nature (London), 258, (1975) 703. E.M. Levin, C.R. Robbins, H.F.McMurdie and M.K. Reser Ed., 'Phase Diagrams for Ceramists', Am. Chem. Sot. (1964). A.F. Wells, 'Structural Inorganic Chemistry', Clarendon Press, Oxford (1975) 448. T. Moeller, in F.H. Spedding and A.H. Daane (eds.), 'The Rare Earths', Krieger, New York (1971) 9. W. Klemm and E. Voss, Z. anorg. allgem. Chem., 251 (1943) 233. M. Takashima, G. Kano and H. Konishi, Nippon Kagaku Kaishi, m,1896.
FommIo~
0F
375-385
375
ZIRCONIA WITH RARE'EARTH FLUORIDES*
STABILIZED
Masayuki TAKASHIMA and Gentaro KANO
Department of Industrial Chemistry, Faculty of Engineering, Fukui University, 3-9-l Bunkyo, Fukui-shi, 910 (Japan)
SUMMARY
New
reactions
to
prepare stabilized zirconia using rare
earth fluorides as the solid electrolyte
have been examined by
means of X-ray diffraction, DTA and EPMA methods.
The
rare earth fluorides of yttrium and samarium through reacted with zrO2 to form new (LnFSZ)consisting of (2x+3y)Zr02
the
of stabilized
types
ternary
system
eleven lutetium zirconias
of zr02-Ln203-LnF3.
+ (4y+2z)LnF3 = 2(zro2)x(Ln203)y(LnF3)s + 3~zrF4
where x, y and z represent the stabilizing composition at which the homogeneous
solid solution with the fluorite structure is
formed, and x + y + z = 1.
This reaction begins to take place
at about 600 C and is completed
by firing at temperatures
ranging from 1000 to 1300 OC for a few hours in an argon atmosphere. INTRODUCTION Zirconium
oxide,
zr02,
is
one
of the most
interesting
materials in technology. So-called stabilized ceramic zirconia is well-known as the oxide ion conducting solid elecused for fuel cells trolyte (II and oxygen sensors[2], and *
also
has
attracted
special
interest -recently
in
Dedicated to Emeritus Professor W.K.R.Musgrave on the occasion of his 70th birthday.
0022-1139/88/$3.50
0 Elsevier Sequoia/Printed in The Netherlands
376
zirconium-toughened phase it
changes
from
Therefore, or rare
and
earth
earth
So,we
wish
oxide
and
above
studying
fluorides
fluoride
the solid
earth
earth
react
between
examined
analysis
and
eleven
atmosphere,
structure,
reaction
rare
or
with
that
zirconias,LnFSZ,are phase
fluorides
thermal
reaction
in an argon
the cubic
stabilized
to report
differential
with
earth
[5].
phase
could
at up to 13OO'C
[4].
alkaline
alkaline
of
a
4% when
tetragonal
with
1600°C
found that zirconia
exhibits
of about
the
the solid
solutions
rare
to
stabilized
by firing
fluorides
zirconia
contraction
monoclinic
various and
and that solid
Pure
[3].
a volume
is usually
been
elements
rare
the
oxides
have
zirconia earth
with
zirconia
earth
We
rare
ceramics
transformation
formed.
between
by X-ray
is, the
zirconium
diffraction,
electron
probe
micro
analysis.
RESULTS
AND DISCUSSION
Fig.1
shows
systems, endothermic From X-ray marked
stabilized
steeply
even
ionic
at 1400
about
this
radii
than
crystal crystal
size.
of the fluorite
type
that the
formation
or rare earth
For rare
for the
earth
ionic
is surrounded
zirconia
the high
[4].
the
formation earth
ions
0.92 i and
elements does
not
with proceed
point
site is
is to be little
in
peaks of
is at
size of the cation
the octa-coordinate
1.27 i
OC.
fluorides.In
that the break
the possible
three
due to the transformat-
1.0 i , this reaction
The site is
were
or
1400
the tripositive rare radius of Ln 3+ up to about
0.93 i if there
radius
the
temperatures
OC. It is reasonable
structure.
Two up to
confirmed
with
of Zr02-Lx-G3
Lu.
against
the crystal
substitutionally
to be about
wa6
of zirconia
the DTA peak
0.92 i., because
occupy
it
and the others
zirconias
over
through
in each DTA curve
data,
structure
are plotted
for the reaction Sm
corresponded
zirconia
by increasing
Y and
appeared
arrows
of stabilized
larger
are
diffraction
ion of crystal
more
Ln
peaks
by
Fig.2
the DTA curves
where
calculated
disordering
with
to
of the
oxide
ions whose
temperature
structure
Temperature
('C)
1300
1200
1000
1100
v
w
Zr02-YbF3
P
f
I
\
V-Y
V
v
I
ZrOq-TmF34p.
ZrO2-ErF37;
Zr02-YF3
ZrOZ-DyF3
ZrOq-TbF3
ZrO2-GdF3
ZrO2-EuF3
Zr02-SmF3
1400
II
(Heating rate; 15'C/min, In argon stream)
Fig.l.DTA curves for the reaction between Zr02 and various LnF3
r
0.80
1000 0.85
Ln3+ radius
0.90
(i)
0.95
Fig.2.Relationship between the DTA peak temperature and Ln3+ radius.
9 PI
E 1 < 1200 1 2 2 y 1100
E; 0 1300
1400
1.00
378
During rare earth
the
solid
fluorides
phase. reaction of
Y
between
and Sm through Lu,
zirconia and the weight of
sample mixture decreased about 15 wt% at the most. Fig. 3 shows the change in weight
for zirconia-YF3,
-EuF3 and -HoF3,after Any systems
firing for three hours at various temperatures. begin to decrease "C, the weight
in weight at about 600°C , and at around 900
decrease
becomes
great ,and then , above about
1100 'C, it reaches almost the limit decrease of about 15 wt%. The
plot
of
the
weight
decrease
s
time reveals that the
greater part of the weight decrease is over within
a
half
hour, as shown in Fig. 4.
600
800
1000
1200
1300
Reaction temperature ('C) Fig.3.Relationship between the weight change and the reaction temperature for (Zr02)0_75(LnF3)0.25 Reaction time; 3 h, In argon stream O:Zr02-EuF3, l :ZrO2-HoF3, @::r02-YF3,
an
379
L 0
I
I
I
I
I
1
2
3
4
5
Reaction time (h) Fig.4.Weight decrease-time curves for the reaction of Zr02-LnF3 systems at 12OO'C in an argon stream
l :ZrO2-HoF9,
0 :ZrO2-EuF9,
Fig.5
shows
the
X-ray
@:Zr02-YF3.
diffraction
powder
patterns
products for zirconia-holmium fluoride mixtures HoF3 which were prepared by firing at various three hours in an argon atmosphere.
of 25
with
the mol%
temperatures for
In the pattern for 500 "C,
all diffraction lines are due to only the starting materials of the monoclinic
zirconia and hexagonal
is, at this temperature
no reaction
holmium
fluoride, that
is found to take place.
At 700 OC, the diffraction lines of HoF3 have disappeared
and
some new lines begin to appear. These are identified to be
due
to the holmium fluoride oxide, HoFO. In the pattern for 900 'C, the lines assigned to the cubic-zirconia
are
dominant.
The
pattern for 1100 'C shows that this product is the single phase of the cubic with the crystal lattice constant a,:5.16 i.
HOW-
ever, even at 1100
tube
'C,
in case of using a sealed alumina
for a reaction vessel, as the bottom profile in Fig. 5
shows,
the product is not a single phase but consists of three
phases
of the cubic zirconia and two of starting materials.
This fact
suggests that the solid phase reaction cannot be driven to completion if the volatile products cannot escape from the tion system.
reac-
380
Open boat w/ i.
Seal tubing
lloo"c
30
40
50
60
Diffraction angle (29'), CuKs Fig.5.X-Ray diffraction patterns of products from (Zr02)Q.75(HoF3)Q.25 at various temperatures; 0: Monoclinic Zr02, 0: Rhombohedral HoFO,
Fig.6
shows
the
0: Hexagonal HoF3, 0: Cubic zirconia.
change
in weight
plotted
against
content of LnF3 in a starting mixture in the case of at 12QO'C for three hours in an argon stream.
the
reaction
The dotted area
shows the contents of LnF3, at which the homogeneous
phase of
cubic zirconia is obtained. The weight decreases almost linearly with increasing LnF3 content and the weight change is found to stop at around the content of fluoride rich end of the range in which the homogeneous cubic phase is formed. The limit of the weight decrease is between 13 and 15 wt%, and seems depend to a limited extent on the species of rare earth.
to
381
Monoclinic Cubic ZrO24
0
10
20
Cubic / / L
30
Content of LnF3
Cubic + LnF3
40
50
(mol%)
Fig.6.Relationship between weight change and the content of LnF in a start mixture (Reaction at 1a00°C for 3 h); 0: EuF3, 0: HoF3, c): YF3.
Next,we
attempted
to analyze
the products
by electron
probe micro analysis. Fig.7 is the spectrum of the sublimate trapped in a filter placed at the outlet of the argon line and the
solid
product remaining in a alumina boat for a Zr02-HoF3
hours. reaction at llOO‘°C for three after system sublimate consists of aluminum, zirconium and fluorine.
The On
the other hand, the components of the solid product are zircopresent in the nium, holmium, fluorine and oxygen. Aluminium sublimate sublimes
is assumed to come from aluminum fluoride which above about 700 'C [71, resulting from the reaction
between zirconium tetrafluoride and the sample boat or reaction tubing made of aluminum oxide.
382
Sublimate
20.0
15.0
10.0 . Ho-La
I
I
I
10.0
15.0
20.0
Wave
length
(A)
spectrum of the sublimate and the Fig.7.E.P.M.A. cubic product for (ZrO2)0,75(HoF3)0.25.
Putting
together
the above
phase
reaction
process
earth
fluoride
begin
and
zirconium
fluoride anionic zirconia
oxide
(LnF-SZ)
rare
place
earth
fluoride
goes
the reaction
the
zirconium
sublimes
tetrafluoride
estimated
the
Zirconia
8.
with
each
rare
earth
are formed.
which
from
and
takes
tetrafluoride, out
in Fig.
to react
tetrafluoride
diffusion and
as shown
results,we
other
system. is formed,
or rare
earth
that mutual
interface
,and at that above
rare 6OO'C
means
This
easily
and
at about
oxide
on the solid
600
Above
solid
time
between zirconium
'C,is formed
900°C,
it sublimes
as soon out
and as
, and
383
many
vacant
crystal tive
sites
lattice
rare earth
and can readily stabilized
of tetrapositive
ions begin occupy
zirconia
as the ternary
ion are born
with
system
sites.
the cubic
consisting
y
Consequently,
structure
of ZrO2,
is easily
Ln203
800% yLn203
+ 1.5yZrF4
+ zLnF3
r---7 ZrF4 1
_!
900%
L---’
Subl.
Y Cubic-(Zr02)x(Ln203)y(LnF3)z LnF-SZ ZrF4
Solid
interface Ln3+
Ln3+ Zr4+
Zr4+
I
Ln3+F-
02Zr4+02-
02;r4+02-
F‘Zr4+p2-
02-
02-
02-
02-
02-
ZrO2 lattice
phase
reaction
F-
FLn3+
.+LnF3
process
between
the created
and LnF3.
LnFO
Fig.8.Solid LnF3.
in a
On the other hand, the triposito migrate into the zirconia lattice
the vacant
600 xZr02
zirconium
of zirconia.
Zr02 and
384
In Table and
the
decrease
during
conducting found
1 are summarized
composition
they
Details
lytes.
subsequent
TABLE
reaction
properties
that
the optimum
of products for
three
of LnF-SZs
function
as oxide
of their
reaction
calculated hours.
have
been
the
The
electrical
weight
examined,
ion conducting
characteristics
temperature
from
will
and
solid
we
electro-
be reported
in
a
paper.
1
Optimum
reaction
Reaction
condition
and the composition
Composition
mixture
Reaction temp. -time LnFS(mol%)('C) (h)
System
of LnF-SZ
of LnF-SZ
(Zr02)x(Ln203)y(LnF3)z
Zr02-SmF3
25
1250
3
0.80
0.13
0.07
ZrOZ-EuFS
25
1200
3
0.79
0.10
0.11
ZrOZ-GdFS
25
1200
3
0.78
0.09
0.13
ZrOZ-TbFS
25
1200
3
0.78
0.10
0.12
ZrOZ-DyFS
25
1200
3
0.78
0.10
0.12
ZrOZ-HoFS
25
1200
3
0.78
0.10
0.12
Zr02-YF3
25
1200
3
0.78
0.09
0.13
ZrOZ-ErF9
25
1200
3
0.78
0.09
0.13
Zr02-TmFS
25
1200
3
0.79
0.10
0.11
Zr02-YbFS
25
1100
3
0.78
0.10
0.12
Zr02-LuF9
25
1100
3
0.78
0.10
0.12
EXPERIMENTAL
The rare earth cially
obtained
Fluorides (passed with of
and
and
were
zirconium
400 mesh
each other the
fluorides
mixture
sieve)
and zirconium
guaranteed oxides,
in the appropriate were
which
and thoroughly
oxide
were
to be 99.9-99.99 were dried,
finely were
% pure. powdered
fully
compositions.About
put into an alumina
commer-
boat made
mixed
two grams of
99.5%
385
pure A1203, and heated at a temperature 3 h in an argon temperature, diffraction
atmosphere.
the products , electron-probe
thermal analysis.
After were
from 200to1400 cooling
analyzed
slowly
by means
microanalysis
OC for to room
of X-ray
and differential
The details of these analysis methods were
according to our previous reports [81.
ACKNOWLEDGMENTS Acknowledgment
is made to the Iwatani Naoji Foundation's
Research Grant for support of this research.
We are grateful
to Prof. N Watanabe for helpful advice and to Mr. H. Uno for Xray analysis.
REFERENCES T. Takahashi, in J. Hladik (ed.) 'Physics of Electrolytes',Vol.2, Academic Press, London (1972) 989. K.S. Goto and W. Pluschkell, in J. Hladik (ed.) 'Physics of Electrolytes', Vo1.2, Academic Press, London (1972) 539. R.C.Garvie, R.H. Hannink and R.T. Pascoe, Nature (London), 258, (1975) 703. E.M. Levin, C.R. Robbins, H.F.McMurdie and M.K. Reser Ed., 'Phase Diagrams for Ceramists', Am. Chem. Sot. (1964). A.F. Wells, 'Structural Inorganic Chemistry', Clarendon Press, Oxford (1975) 448. T. Moeller, in F.H. Spedding and A.H. Daane (eds.), 'The Rare Earths', Krieger, New York (1971) 9. W. Klemm and E. Voss, Z. anorg. allgem. Chem., 251 (1943) 233. M. Takashima, G. Kano and H. Konishi, Nippon Kagaku Kaishi, m,1896.