- Email: [email protected]
Glass formation and crystallization in alkali-containing fluoride glasses
Journal ofNonCrystalline North-HoUand.Amstcrdam
Solids 95 &96 (1987)
481
GLASS FORMATION
Xiujian
487 - 494
AND CRYSTALLIZATION
ZHAO and
Sumio
IN
ALKALI-CONTAINING
FLUORIDE
GLASSES
SAKKA
Institute for Chemical Research, Kyoto and Division of Molecular Engineering, Kyoto University, Sakyo-ku. Kyoto-shi
University, Uji-shi. Graduate School of 606. Japan
Kyoto-fu Engineering,
611
Glass formation range, glass-forming ability and crystallization kinetics were studied with alkali-containing fluoride systems of compositions (~DO-X)(D.~Z~F~~D.~A~F~~O.~B~F~)~~L~(N~, K or Cs)F. Glass formation range decreases with increasing size of alkali ion. Maximum of glass-forming ability is found around the alkali fluoride (RF) concentration of 5-20 mol%. The composition corresponding to the maximum shifts to lower RF concentrations with increasing size of alkali ion. The glass-forming ability appears to be mainly determined by the difference between crystallization and glass transition temperatures. Crystallization kinetics study shows that the maximum of glass-forming ability corresponds to a minimum of the activation energy of crystallization for glasses containing LiF.
1.
INTRODUCTION Heavy
a1.l
metal
in
waveguides
excellent
(-250
nm)
glasses
to
have
mid-IR
very
is
yet.
clear
In
this
Alkali of
the
glass
With the
2.
in
LiF-containing activation
of
glasses energy
R is
for
range
the
and
in
K or
the
glass
crystallization growth
range
be
related
is the
are
(loo-x)(0.6ZrFq.
discussion
to
systems
ability
of
to
glass
fluoride
compositions
and
on these
contrast
as
of
formation
for UV
fluoride
considered
glass-forming
Cs.
near
studies In
kinetics is
of
formation
et
systems
from
alkali-containing
of
Poulain
optical
communication
a number
can
glass
glasses Na.
Li.
ions
crystal
in
by
for
applications. on
(RF)
ions
fluoride
alkali
reported
length
years, and
studies
formation
where role
wave
ten
fluoride
alkali-containing
structural
last
the
fundamental
alkali
first materials
repeatless in
systematic
few3-6.
D.1A1F3-D.3BaF2)-xRF. the
the
role
In
both
were
candidate
light
um)2.
the
paper, with
of
for
however,
but
reported
made
on ZrF4
strong
long-distance,
(a-10
been
are
based are
transmittance
modifier7*8. not
glasses
ultralow-loss.
glasses,
glasses
glasses
These
in
their
oxide
fluoride
1975.
will these
also
be made
on
glasses. reported
and
glass-forming
ability.
EXPERIMENTAL 2.1
Glass
The
compositions
preparation
the
present
Here
x ranges
from
0 Elsevier SciencePublishers Physics Publishing Division)
DO22-3D93/87/$03SD
(North-Holland
(lOD-x)(D.6ZrF4*0.1A1F3~D.3EJaF2)'xRF study.
0 to
B.V.
in 60,
0 to
45,
mol D to
have 35
been and
used
D to
30
Zhao Xiujiatt,
488
intervals
of
reagents
5 mol%
materials.
in
respectively
(NH4)2ZrFG, The
preheated
at
mixture
melt
were
Differential
cast
thermal
then
Li,
Na.
K and
Cs.
CsF
were
used
as
with melted
atmosphere
a brass
analysis of
KF and added
and
a nitrogen
made
and crysrollizorion
equaling
NaF,
materials 1 hour
thermal
DTA-30
R's
LiF.
into
were
mould
about at in
of
10 wt%
using
DTA in
The
an
pure
NH4HF2
for
was
20 minutes
electrically
heating
ZOO'C.
(OTA) the
analyzer.
glasses Powders
crystallization a heating
crystallization
powders
of
ANALYSIS
of
rate
range
occurred
574
urn were
at of
a heating
rate
of
674 urn (passing
LiF-containing
from
mainly
used
lO'C/min
through
200
with mesh)
1 to
from
glasses
are
in
a nitrogen
50 'C/min
the
surface
in
these
by using
the
Glass-forming
ability
The
glass-forming
ability
T g,
T,
and
temperatures, Fig.
studied
by
atmosphere.
glasses,
and
so
as samples.
was
calculated
formula
Tc - Tg
where
also
OF DTA DATA
3.1
-- Tm - Tc
Kgl T,
are
the
by
Hruby'
(1) glass
respectively.
transition,
They
are
crystallization
estimated
from
and
the
melting
DTA curve
as
shown
have
analyzed
in
1. 3.2
Kinetic
equations
Non-isothermal the
equations
where
o=
In
d (~p2)
depending
heating gas
on the
Kissinger-type
-$
Glass
rate
mechanism
formation
and
mE
= -m
Ozawa-type
RESULTS 4.1
crystallization
in
the
present
range
been
by
(2)
+ const
+ const
(=dT/dt), T and of
study
Sakka":
-+ln[-ln(l-x)]
constant,
and
non-isothermal obtained
by Matusita
ln
the R the
for
DTA data derived
ais
growth,
4.
of
B50-900°C
about
Extra starting
used. Non-isothermal
3.
raw for
under is
OTA measurements Shimadzu
of
/ Glass formation
for
BaF2,
45O'C
crucible
The
2.2
AlF3.
about
a platinum
furnace.
S. Sakka
E the Tp
the
activation
temperatures
crystallization. plots,
respectively.
Eqs.
energy and (2)
for
m and and
(3)
crystal n the are
parameters so-called
Zhoo Xiujion,
Temperature
containing
0
0
0
0
0
0
l
0 0 0
o 0 0
o 0 0
0 0 0
0 0 0
0 l 0 0
K system 0 0 Na system
0
0 0 0 0 l
10
Cs system
0
I
I
I
20
30
40
1
489
and crymdlizorion
0.81
0 0 0 I D
/ Glass formo~ion
("C)
Fig. 1 a glass
DTA curve of 15 mol% NaF.
S. Sokko
RF concentration
Li
I
I
50
60
system I
o-
70
0
(mol%)
10
20
30
40
RF concentration Fig. 2 Glass formation ranges of the alkali fluoride oglass @glass+crystal
The terms
glass of
formation
alkali
glass
formation
found
that
shown in terms concentration.
range glass
gl' of the
@crystal
ranges
fluoride
the
K
of
all
the
four
concentration. extends
to
formation
For
a LiF range
3 Tm as
are
shown
in
LiF-containing
concentration decreases
of
with
60
a function
RF concentration.
systems the
Fig. and
Tc-Tg
50 (mol%)
Fig.
2 in
system,
about
the
55 mol%.
increasing
It
is
size
of
alkali
T,
and
T,-Tg
around
the
ion. 4.2
Glass-forming
The
results
from
eq.
against
(1) the
concentration to the
lower
ability
of is
DTA are also
given
shown.
RF concentration. of
5-20
The
mol%.
RF concentrations
dependence
of
Kg1 on
in
Fig.
The with
the
Table
1.
Glass-forming
3 shows
the
plots
curves
for
Kg1 show
composition increasing
RF concentration
of
corresponding size
of is
alkali consistent
ability the
Kg,.
Kg1 estimated
a maximum to
the
ion. with
maximum
It
is that
RF shifts
found of
T,-T
that 9'
490
Zhao Xiujion.
Table
1.
OTA results 0.3BaF2)oxRF
and the glasses
Temperature co;,
x (mol%)
Tg
S. Sukko
values
K9l
c
Tm
0 glass 5 10 15 ;i
292
346
558
0.255
276 268 256 251 240
335 327 325 325 296
508 505 504 500 513
0.341 0.331 0.385 0.258 0.427
:i 40 45
226 220 216 209
281 275 268 261
490 492 492 491
0.256 0.261 0.232 0.226
:i K glass 5 10 ::
204 194
231 255
493 512
0.132 0.214
289 280 271 278
358 355 333 345
484 490 557 493
0.548 0.556 0.277 0.453
25 30
263 257
312 293
573 582
0.188 0.125
Li
4
/ Glass /ormarion
of
Kg1 of
and crysrollizorior~
(100-x)(0.6ZrF4-0.1A1F3~
x (mol%)
K9l
Na glass 5 10 :z
35 :z
Cs glass 5 10 15 ;:
283 271 267 257 252 245 238
342 342 342 332 326 308 288
460 455 458 458 457 452 472
0.500 0.628 0.647 0.595 0.565 0.438 0.272
295 293 279 266 262
365 378 342 326 297
480 552 551 547 508
0.609 0.489 0.341 0.271 0.166
I,,,,,,
I 1.55 103/Tp
(K-l)
Fig. 4 Ozawa-type plots for glasses. The numbers concentrations.
I 1.65
I
I 1.75
103/Tp
LiF-containing show LiF
Fig. 5 Kissinger-type plots containing glasses. show LiF concentrations.
I
I 1.85
(K-l)
for LiFThe numbers
I 1
Zlrao
In
the
lower
increases
is.
S. Srrkka
RF concentration
which
concentration That
Xiujion.
is
the
the
dependence
Glass /orntotton
region,
consistent
region,
/
Tm decreases
with
the
behaviour
of
of
Kg1
and ctytollizatiot~
as the
increase
in
Tm is
on the
not
Kgl,
RF concentration but
always
491
in
higher
consistent
RF concentration
is
RF with
mainly
Kg,.
determined
by
T,-Tg. 4.3
Non-isothermal
It
is
assumed
straight
line
heating
rate.
is
that
seen
mainly
when
against
the
plot
of
In
a versus
crystallization
4 shows
plots
the by
the
the
Fig. the
from
estimated
crystallization that
such
are
surface,
plots
straight the
assuming
for
The
RF concentration
based
in
does
some
lines.
activation
n=m=l.
l/Tp
mechanism of
the
energies
Fig.
of
(2)
change
gives
with
LiF-containing
Since
values
on eq.
not
glasses.
crystallization
for
crystal
given
in
,
@from
Fig.
10
20
It
occurs
growth
E are
a
the
Table
can
be
2 and
plotted
6. 4
600 Table
2.
(mzl%)
Values of E determined from Figs. 4 and 5 in LiF-containing glass'es.
_
E (kJ/mol) Fig.4 from
5
from
0 5 15 20 25
The
plots
lower for
507 464 304 329 418 5ao 384 331
of
heating
growth
those It
is
growth Fig.
in
7 that
Table
and
corresponding
to For
Fig.
3.
with
increasing
the
higher
Fig.
of 6 that
kinds
energy
of for
reaches up to
minimum LiF
a LiF of
shown
plots
in
are
the
Fig.
crystal a minimum
are
given
to
in
that
for
energies
Table
close.
2 and
a LiF
the
for It
decreases
of
than
seen
activation
energies
growth
concentration
larger
is
in
Fig.
6
l/Tp.
very
at
50
(mol%)
It
6. The
activation
plots
40
Fig. 6 energy for crystal LiF concentration glasses.
lines.
In o versus
E corresponds
concentrations
RF concentration.
are straight
these
plots
two
activation
increases
l/Tp give
30
concentration
Activation growth vs. LiF-containing
from
RF concentration, then
LiF
the
2 and the
2001 0
plots
from
from
the
UJ 300
versus
these determined
estimated
increasing mol%.
(a/Tp2)
determined seen
Fig.5 497 454 295 320 409 571 375 322
rates,
crystal
with
In
500
E 2400
is first
crystal also
concentration 30 mol%.
maximum 30 mol%.
The
seen
in
with of
15-20
composition
of K as cl1 E decreases
shown again
in
4.4
The
The
crystals
BaZr2F10
kind
and
mol% were LiF
5.
precipitated in
unknown
Li2ZrFb
glasses
crystals,
crystals,
with whereas
different
from
LiF
from
in
glasses
the
15 to
35 mol%
with
crystals
LiF
were
higher
precipitated
than in
35
lower
glasses.
DISCUSSION 5.1
Glass
on glass tends
formation
to
induce
favoring
for the
ionicity.
From
the
region.
first
will
decrease
in
shown
it
RF mainly
with
decreases the
size
region,
of
composition
total
Then
alkali
the
ion.
the
alkali-free
is
enough
high
glass-forming
is,
K
to ability
versus
RF
addition
of
91
lower
RF concentration
increases T,-Tg.
region,
T,-Tg As
shown
and in
in
the
the
the
higher
next
section,
dependence
in
RF to
RF concentration the
the
addition
of
crystallization
glasses.
alkali in
with
the
ion, the
increases,
corresponding
ionicity
ion.
RF concentration
the
That
RF
Rt
increasing
RF to
lower
effect,
of of
radius. of
of
the
limit
a maximum.
RF concentration,
ionicity
concentrations
glass
of
its size
RF concentration second
viscosity-temperature
increases
Kgl
total
the
mainly
same
show
mainly
modifies
increasing
the
in
the the
in
covalency liquid
ionicity with
addition
the
as glass
the
with
the
in
upper
decrease
RF concentration.
should
glass
range
the
where than
increasing
above,
temperature At
region
stronger
the
tendency
enhances
the
increasing
modifier.
generally
species
by
increases with
effects
character
be considered
will
ionicity
decrease glass
it the
be controlled
glass-forming
the
curves
alkali-free
the
of
effect
concentration
region
ions,
contradictory
ionic
modifier,
RF concentration
should
the
of
glass
will
two
high
simultaneously
RF may as
formation
effects
However, the
As
effect
increase
make
the
formation.
first
range two
will
glass
of
has 1)
polymerization
the
alkali
formation
glass
systems:
the
limit
ability modifier
2) the
glass
upper For
glass
glass
multicomponent
increasing
concentration is,
glass-forming
al.",
a recrystallization.
From
That
and
et
in
former, and
range
Cottrant
formation
glass
phase
to
modifier7*B.
in
crystals
other
According
of
of
precipitated
and order
is
Li
the to
assumed
of
in
glass
the
glass
of
of
alkali
increase
in
to
increase
ion, order
< K glass
< Cs glass. Then
to
lower
RF
because
the
rate
Li
with
RF concentration
crystallization.
Kg1 shifts
the
will
lower
< Na glass tends
maximum size
to
ionicity
system
the
increasing
total therefore,
glass
of
As
the
increase
< Na glass
< K
< Cs glass. 5.2 If
crystal
Activation the
crystal growth
energy
for
crystal
growth
growth
rate
is
diffusion-controlled,
E can
be
related
to
that
for
viscous
the flow
activation in
the
similar
energy
for
temperature
range.
The
fluorozirconates
is
generally,
E decreases
temperature
ranges
constant the
from
Tg,
This
means
has
a larger
the
the
dependence
the
the
that
of
concentration
increasing directly
related This
to
ZBL glasses.
discussion
may
The
above
compound
the
Li2ZrF6
has
assumed
that
be
also
suitable
controlled
for
crystal
may than
no
not 30
of
the
growth
for
will
Glass
is. et
decreases
for
other
alkali-containing
be
suitable
mol%,
for
because different
atom
decrease
its
of Li
Li
atom
with
that
increasing
the the
in
LiF crystalline
the
or
atom. If
this
These These
region
of
unknown
will
the
530
it
is
be a very
crystallization
region, LiF
Then
There the
LiF
crystals.
structure14.
Li
atom.
in
the ability.
with
BaZr2F10
be
glass-forming and modified
systems.
crystal
may
diffusion of
is
in
be
the
in
region
from
in
species
this
is
may
concentration.
glasses
in
and
ZBL
viscosity
LiF
LiF
glass
glass-forming
the
lower increasing
range
on
explained
the
alkali-free
al.13
the the
be
E with
increasing
Bansal
on
formation
studied
range,
with
glass-forming
with
increasing
appear the
around maximum The
ability
alkali-containing
size the shifts
dependence
K or
of
alkali
ion.
RF concentration to of
lower
and
fluoride
(0.6ZrF4~0.1AlF3~0.3BaF2)*xLi(Na.
ion.
that
LiF
can
rate
activation
energy
concentration.
CONCLUSIONS
were
to
the
growth
Therefore,
In
temperature
compound
diffusion
to
manner. crystal
on the mol%
energy
LiF
increases
range.
630
T,-Tg
is
diffusing
energy by
of
decreasing
fluorine
main
the
comparable
for
growth
activation
of
LiF
crystallizing
bridging
the
the
results
the
dependence.
addition
precipitated first
activation
is
6.
dependence
(Li2ZrF6)
mol% where
and
give
a different
energy
crystal
crystallization
of
the
larger
may
in
in
concentration
of
range,
to
discussion
concentrations
small
addition
temperature
correlated
molten
temperature
temperature
formation, the
are As
decreases
for
LiF
the the
glass with
Further
crystallization
which
glasses
activation
energy
that
the
most
temperature,
crystallization
small
value.
crystallization
decrease
in
agrees
all
same
viscosity-temperature
the
viscosity
ability.
the
where
the
means
its
Tg,
a smaller
activation
region,
in of
The
very
glasses
having in
of
are
the
different
region
modification
glasses
have
glass
the
viscosity
a function
temperature.
temperature
for
the
in
of
E is
E.
viscosities
the
i.e..
present
viscosity13
concentration
are
the
viscosity
concentration
LiF
of
transition
and
dependence
increasing
energy
glass
condition
by
with
activation
At
temperature
non-Arrhenian'*.
of
Cs)F.
of
Glass
formation
of
glass-forming
5-20
mol%.
The
RF concentration
kinetics
compositions
Maxima
RF concentrations
Kg1 on the
crystallization
systems
with
decreases
abilities
composition
Kg1 corresponding
increasing indicates
(100-x)
range
size that
Kg1
of
alkali is
mainly
determined
by Tc-Tg.
shows
the
that
temperature appears
Crystallization
addition
of
dependence in
the
kinetics
RF to
and
the
a minimum
composition
study
alkali-free of
the
corresponding
on LiF-containing
glass
modifies
activation
to
that
energy
of
glasses
the for
viscositycrystal
growth
Kg1 maximum.
ACKNOWLEDGEMENT This for
the
work
was
partially
Ministry
of
supported
Education,
by a Grant-in-Aid
Science
and
Culture,
P.Brun,
Mat.
for
Scientific
Japan
(Prof.
Research S.
Sakka.
No.
60430020). REFERENCES 1) M.Poulain, 2)
M.Poulain.
J.Siscavage
O.H.El-Bayoumi,
3) A.Lecoq
and
4)
J.Senegas, Solids 85
5)
P.L.Higby.
6)
Xiujian
7)
C.M.Baldwin
8)
M.Poulain,
9)
A.Hruby.
J.Lucas
and
J.
M.Poulain,
J.M.Reau. H.Aomi. (1986) 315. J.E.Shelby
Zhao
and and
Submitted
J.
Phys.
11)
J.F.Cottrant,
B.Dubois
12)
Hefang
J.D.Mackenzie.
Hu and
N.P.Bansal, (1985)
70
G.Brunton.
S.Sakka.
A.J.Bruce. 379. Acta
Cryst.
to
J.
(1981)
K.Matusita
14)
and
M.Suscavage.
S.Sakka.
293
Solids
Am.
Appl.
J.
Non-Cryst.
Ceram.
10 (1975) Solids
Phys.
Sot.
243.
73 (1985)
613.
101.
J.
M.Poulain.
J.
58
Non-Cryst.
(1985)
4142.
Solids. 62
(1979)
537.
279. (1972)
1187.
Bull.
Inst.
Chem.
J.Portier,
J.
R.H.Doremus
829
Bull.
Non-Cryst.
and
B 22
and
Res.
34 (1979)
P.Hagenmuller
J.D.Mackenzie.
Nature Czech.
and
J.
B.Bendow.
Non-Cryst.
10)
13)
and
(1973)
Mat.
Non-Cryst. and
2294.
Res., Res. Solids
C.T.Moynihan,
Kyoto
Univ.
Bull.
20
(1985)
54 (1983)
J.
20
(1981)
159.
203.
241.
Non-Cryst.
Solids
Solids 95 &96 (1987)
481
GLASS FORMATION
Xiujian
487 - 494
AND CRYSTALLIZATION
ZHAO and
Sumio
IN
ALKALI-CONTAINING
FLUORIDE
GLASSES
SAKKA
Institute for Chemical Research, Kyoto and Division of Molecular Engineering, Kyoto University, Sakyo-ku. Kyoto-shi
University, Uji-shi. Graduate School of 606. Japan
Kyoto-fu Engineering,
611
Glass formation range, glass-forming ability and crystallization kinetics were studied with alkali-containing fluoride systems of compositions (~DO-X)(D.~Z~F~~D.~A~F~~O.~B~F~)~~L~(N~, K or Cs)F. Glass formation range decreases with increasing size of alkali ion. Maximum of glass-forming ability is found around the alkali fluoride (RF) concentration of 5-20 mol%. The composition corresponding to the maximum shifts to lower RF concentrations with increasing size of alkali ion. The glass-forming ability appears to be mainly determined by the difference between crystallization and glass transition temperatures. Crystallization kinetics study shows that the maximum of glass-forming ability corresponds to a minimum of the activation energy of crystallization for glasses containing LiF.
1.
INTRODUCTION Heavy
a1.l
metal
in
waveguides
excellent
(-250
nm)
glasses
to
have
mid-IR
very
is
yet.
clear
In
this
Alkali of
the
glass
With the
2.
in
LiF-containing activation
of
glasses energy
R is
for
range
the
and
in
K or
the
glass
crystallization growth
range
be
related
is the
are
(loo-x)(0.6ZrFq.
discussion
to
systems
ability
of
to
glass
fluoride
compositions
and
on these
contrast
as
of
formation
for UV
fluoride
considered
glass-forming
Cs.
near
studies In
kinetics is
of
formation
et
systems
from
alkali-containing
of
Poulain
optical
communication
a number
can
glass
glasses Na.
Li.
ions
crystal
in
by
for
applications. on
(RF)
ions
fluoride
alkali
reported
length
years, and
studies
formation
where role
wave
ten
fluoride
alkali-containing
structural
last
the
fundamental
alkali
first materials
repeatless in
systematic
few3-6.
D.1A1F3-D.3BaF2)-xRF. the
the
role
In
both
were
candidate
light
um)2.
the
paper, with
of
for
however,
but
reported
made
on ZrF4
strong
long-distance,
(a-10
been
are
based are
transmittance
modifier7*8. not
glasses
ultralow-loss.
glasses,
glasses
glasses
These
in
their
oxide
fluoride
1975.
will these
also
be made
on
glasses. reported
and
glass-forming
ability.
EXPERIMENTAL 2.1
Glass
The
compositions
preparation
the
present
Here
x ranges
from
0 Elsevier SciencePublishers Physics Publishing Division)
DO22-3D93/87/$03SD
(North-Holland
(lOD-x)(D.6ZrF4*0.1A1F3~D.3EJaF2)'xRF study.
0 to
B.V.
in 60,
0 to
45,
mol D to
have 35
been and
used
D to
30
Zhao Xiujiatt,
488
intervals
of
reagents
5 mol%
materials.
in
respectively
(NH4)2ZrFG, The
preheated
at
mixture
melt
were
Differential
cast
thermal
then
Li,
Na.
K and
Cs.
CsF
were
used
as
with melted
atmosphere
a brass
analysis of
KF and added
and
a nitrogen
made
and crysrollizorion
equaling
NaF,
materials 1 hour
thermal
DTA-30
R's
LiF.
into
were
mould
about at in
of
10 wt%
using
DTA in
The
an
pure
NH4HF2
for
was
20 minutes
electrically
heating
ZOO'C.
(OTA) the
analyzer.
glasses Powders
crystallization a heating
crystallization
powders
of
ANALYSIS
of
rate
range
occurred
574
urn were
at of
a heating
rate
of
674 urn (passing
LiF-containing
from
mainly
used
lO'C/min
through
200
with mesh)
1 to
from
glasses
are
in
a nitrogen
50 'C/min
the
surface
in
these
by using
the
Glass-forming
ability
The
glass-forming
ability
T g,
T,
and
temperatures, Fig.
studied
by
atmosphere.
glasses,
and
so
as samples.
was
calculated
formula
Tc - Tg
where
also
OF DTA DATA
3.1
-- Tm - Tc
Kgl T,
are
the
by
Hruby'
(1) glass
respectively.
transition,
They
are
crystallization
estimated
from
and
the
melting
DTA curve
as
shown
have
analyzed
in
1. 3.2
Kinetic
equations
Non-isothermal the
equations
where
o=
In
d (~p2)
depending
heating gas
on the
Kissinger-type
-$
Glass
rate
mechanism
formation
and
mE
= -m
Ozawa-type
RESULTS 4.1
crystallization
in
the
present
range
been
by
(2)
+ const
+ const
(=dT/dt), T and of
study
Sakka":
-+ln[-ln(l-x)]
constant,
and
non-isothermal obtained
by Matusita
ln
the R the
for
DTA data derived
ais
growth,
4.
of
B50-900°C
about
Extra starting
used. Non-isothermal
3.
raw for
under is
OTA measurements Shimadzu
of
/ Glass formation
for
BaF2,
45O'C
crucible
The
2.2
AlF3.
about
a platinum
furnace.
S. Sakka
E the Tp
the
activation
temperatures
crystallization. plots,
respectively.
Eqs.
energy and (2)
for
m and and
(3)
crystal n the are
parameters so-called
Zhoo Xiujion,
Temperature
containing
0
0
0
0
0
0
l
0 0 0
o 0 0
o 0 0
0 0 0
0 0 0
0 l 0 0
K system 0 0 Na system
0
0 0 0 0 l
10
Cs system
0
I
I
I
20
30
40
1
489
and crymdlizorion
0.81
0 0 0 I D
/ Glass formo~ion
("C)
Fig. 1 a glass
DTA curve of 15 mol% NaF.
S. Sokko
RF concentration
Li
I
I
50
60
system I
o-
70
0
(mol%)
10
20
30
40
RF concentration Fig. 2 Glass formation ranges of the alkali fluoride oglass @glass+crystal
The terms
glass of
formation
alkali
glass
formation
found
that
shown in terms concentration.
range glass
gl' of the
@crystal
ranges
fluoride
the
K
of
all
the
four
concentration. extends
to
formation
For
a LiF range
3 Tm as
are
shown
in
LiF-containing
concentration decreases
of
with
60
a function
RF concentration.
systems the
Fig. and
Tc-Tg
50 (mol%)
Fig.
2 in
system,
about
the
55 mol%.
increasing
It
is
size
of
alkali
T,
and
T,-Tg
around
the
ion. 4.2
Glass-forming
The
results
from
eq.
against
(1) the
concentration to the
lower
ability
of is
DTA are also
given
shown.
RF concentration. of
5-20
The
mol%.
RF concentrations
dependence
of
Kg1 on
in
Fig.
The with
the
Table
1.
Glass-forming
3 shows
the
plots
curves
for
Kg1 show
composition increasing
RF concentration
of
corresponding size
of is
alkali consistent
ability the
Kg,.
Kg1 estimated
a maximum to
the
ion. with
maximum
It
is that
RF shifts
found of
T,-T
that 9'
490
Zhao Xiujion.
Table
1.
OTA results 0.3BaF2)oxRF
and the glasses
Temperature co;,
x (mol%)
Tg
S. Sukko
values
K9l
c
Tm
0 glass 5 10 15 ;i
292
346
558
0.255
276 268 256 251 240
335 327 325 325 296
508 505 504 500 513
0.341 0.331 0.385 0.258 0.427
:i 40 45
226 220 216 209
281 275 268 261
490 492 492 491
0.256 0.261 0.232 0.226
:i K glass 5 10 ::
204 194
231 255
493 512
0.132 0.214
289 280 271 278
358 355 333 345
484 490 557 493
0.548 0.556 0.277 0.453
25 30
263 257
312 293
573 582
0.188 0.125
Li
4
/ Glass /ormarion
of
Kg1 of
and crysrollizorior~
(100-x)(0.6ZrF4-0.1A1F3~
x (mol%)
K9l
Na glass 5 10 :z
35 :z
Cs glass 5 10 15 ;:
283 271 267 257 252 245 238
342 342 342 332 326 308 288
460 455 458 458 457 452 472
0.500 0.628 0.647 0.595 0.565 0.438 0.272
295 293 279 266 262
365 378 342 326 297
480 552 551 547 508
0.609 0.489 0.341 0.271 0.166
I,,,,,,
I 1.55 103/Tp
(K-l)
Fig. 4 Ozawa-type plots for glasses. The numbers concentrations.
I 1.65
I
I 1.75
103/Tp
LiF-containing show LiF
Fig. 5 Kissinger-type plots containing glasses. show LiF concentrations.
I
I 1.85
(K-l)
for LiFThe numbers
I 1
Zlrao
In
the
lower
increases
is.
S. Srrkka
RF concentration
which
concentration That
Xiujion.
is
the
the
dependence
Glass /orntotton
region,
consistent
region,
/
Tm decreases
with
the
behaviour
of
of
Kg1
and ctytollizatiot~
as the
increase
in
Tm is
on the
not
Kgl,
RF concentration but
always
491
in
higher
consistent
RF concentration
is
RF with
mainly
Kg,.
determined
by
T,-Tg. 4.3
Non-isothermal
It
is
assumed
straight
line
heating
rate.
is
that
seen
mainly
when
against
the
plot
of
In
a versus
crystallization
4 shows
plots
the by
the
the
Fig. the
from
estimated
crystallization that
such
are
surface,
plots
straight the
assuming
for
The
RF concentration
based
in
does
some
lines.
activation
n=m=l.
l/Tp
mechanism of
the
energies
Fig.
of
(2)
change
gives
with
LiF-containing
Since
values
on eq.
not
glasses.
crystallization
for
crystal
given
in
,
@from
Fig.
10
20
It
occurs
growth
E are
a
the
Table
can
be
2 and
plotted
6. 4
600 Table
2.
(mzl%)
Values of E determined from Figs. 4 and 5 in LiF-containing glass'es.
_
E (kJ/mol) Fig.4 from
5
from
0 5 15 20 25
The
plots
lower for
507 464 304 329 418 5ao 384 331
of
heating
growth
those It
is
growth Fig.
in
7 that
Table
and
corresponding
to For
Fig.
3.
with
increasing
the
higher
Fig.
of 6 that
kinds
energy
of for
reaches up to
minimum LiF
a LiF of
shown
plots
in
are
the
Fig.
crystal a minimum
are
given
to
in
that
for
energies
Table
close.
2 and
a LiF
the
for It
decreases
of
than
seen
activation
energies
growth
concentration
larger
is
in
Fig.
6
l/Tp.
very
at
50
(mol%)
It
6. The
activation
plots
40
Fig. 6 energy for crystal LiF concentration glasses.
lines.
In o versus
E corresponds
concentrations
RF concentration.
are straight
these
plots
two
activation
increases
l/Tp give
30
concentration
Activation growth vs. LiF-containing
from
RF concentration, then
LiF
the
2 and the
2001 0
plots
from
from
the
UJ 300
versus
these determined
estimated
increasing mol%.
(a/Tp2)
determined seen
Fig.5 497 454 295 320 409 571 375 322
rates,
crystal
with
In
500
E 2400
is first
crystal also
concentration 30 mol%.
maximum 30 mol%.
The
seen
in
with of
15-20
composition
of K as cl1 E decreases
shown again
in
4.4
The
The
crystals
BaZr2F10
kind
and
mol% were LiF
5.
precipitated in
unknown
Li2ZrFb
glasses
crystals,
crystals,
with whereas
different
from
LiF
from
in
glasses
the
15 to
35 mol%
with
crystals
LiF
were
higher
precipitated
than in
35
lower
glasses.
DISCUSSION 5.1
Glass
on glass tends
formation
to
induce
favoring
for the
ionicity.
From
the
region.
first
will
decrease
in
shown
it
RF mainly
with
decreases the
size
region,
of
composition
total
Then
alkali
the
ion.
the
alkali-free
is
enough
high
glass-forming
is,
K
to ability
versus
RF
addition
of
91
lower
RF concentration
increases T,-Tg.
region,
T,-Tg As
shown
and in
in
the
the
the
higher
next
section,
dependence
in
RF to
RF concentration the
the
addition
of
crystallization
glasses.
alkali in
with
the
ion, the
increases,
corresponding
ionicity
ion.
RF concentration
the
That
RF
Rt
increasing
RF to
lower
effect,
of of
radius. of
of
the
limit
a maximum.
RF concentration,
ionicity
concentrations
glass
of
its size
RF concentration second
viscosity-temperature
increases
Kgl
total
the
mainly
same
show
mainly
modifies
increasing
the
in
the the
in
covalency liquid
ionicity with
addition
the
as glass
the
with
the
in
upper
decrease
RF concentration.
should
glass
range
the
where than
increasing
above,
temperature At
region
stronger
the
tendency
enhances
the
increasing
modifier.
generally
species
by
increases with
effects
character
be considered
will
ionicity
decrease glass
it the
be controlled
glass-forming
the
curves
alkali-free
the
of
effect
concentration
region
ions,
contradictory
ionic
modifier,
RF concentration
should
the
of
glass
will
two
high
simultaneously
RF may as
formation
effects
However, the
As
effect
increase
make
the
formation.
first
range two
will
glass
of
has 1)
polymerization
the
alkali
formation
glass
systems:
the
limit
ability modifier
2) the
glass
upper For
glass
glass
multicomponent
increasing
concentration is,
glass-forming
al.",
a recrystallization.
From
That
and
et
in
former, and
range
Cottrant
formation
glass
phase
to
modifier7*B.
in
crystals
other
According
of
of
precipitated
and order
is
Li
the to
assumed
of
in
glass
the
glass
of
of
alkali
increase
in
to
increase
ion, order
< K glass
< Cs glass. Then
to
lower
RF
because
the
rate
Li
with
RF concentration
crystallization.
Kg1 shifts
the
will
lower
< Na glass tends
maximum size
to
ionicity
system
the
increasing
total therefore,
glass
of
As
the
increase
< Na glass
< K
< Cs glass. 5.2 If
crystal
Activation the
crystal growth
energy
for
crystal
growth
growth
rate
is
diffusion-controlled,
E can
be
related
to
that
for
viscous
the flow
activation in
the
similar
energy
for
temperature
range.
The
fluorozirconates
is
generally,
E decreases
temperature
ranges
constant the
from
Tg,
This
means
has
a larger
the
the
dependence
the
the
that
of
concentration
increasing directly
related This
to
ZBL glasses.
discussion
may
The
above
compound
the
Li2ZrF6
has
assumed
that
be
also
suitable
controlled
for
crystal
may than
no
not 30
of
the
growth
for
will
Glass
is. et
decreases
for
other
alkali-containing
be
suitable
mol%,
for
because different
atom
decrease
its
of Li
Li
atom
with
that
increasing
the the
in
LiF crystalline
the
or
atom. If
this
These These
region
of
unknown
will
the
530
it
is
be a very
crystallization
region, LiF
Then
There the
LiF
crystals.
structure14.
Li
atom.
in
the ability.
with
BaZr2F10
be
glass-forming and modified
systems.
crystal
may
diffusion of
is
in
be
the
in
region
from
in
species
this
is
may
concentration.
glasses
in
and
ZBL
viscosity
LiF
LiF
glass
glass-forming
the
lower increasing
range
on
explained
the
alkali-free
al.13
the the
be
E with
increasing
Bansal
on
formation
studied
range,
with
glass-forming
with
increasing
appear the
around maximum The
ability
alkali-containing
size the shifts
dependence
K or
of
alkali
ion.
RF concentration to of
lower
and
fluoride
(0.6ZrF4~0.1AlF3~0.3BaF2)*xLi(Na.
ion.
that
LiF
can
rate
activation
energy
concentration.
CONCLUSIONS
were
to
the
growth
Therefore,
In
temperature
compound
diffusion
to
manner. crystal
on the mol%
energy
LiF
increases
range.
630
T,-Tg
is
diffusing
energy by
of
decreasing
fluorine
main
the
comparable
for
growth
activation
of
LiF
crystallizing
bridging
the
the
results
the
dependence.
addition
precipitated first
activation
is
6.
dependence
(Li2ZrF6)
mol% where
and
give
a different
energy
crystal
crystallization
of
the
larger
may
in
in
concentration
of
range,
to
discussion
concentrations
small
addition
temperature
correlated
molten
temperature
temperature
formation, the
are As
decreases
for
LiF
the the
glass with
Further
crystallization
which
glasses
activation
energy
that
the
most
temperature,
crystallization
small
value.
crystallization
decrease
in
agrees
all
same
viscosity-temperature
the
viscosity
ability.
the
where
the
means
its
Tg,
a smaller
activation
region,
in of
The
very
glasses
having in
of
are
the
different
region
modification
glasses
have
glass
the
viscosity
a function
temperature.
temperature
for
the
in
of
E is
E.
viscosities
the
i.e..
present
viscosity13
concentration
are
the
viscosity
concentration
LiF
of
transition
and
dependence
increasing
energy
glass
condition
by
with
activation
At
temperature
non-Arrhenian'*.
of
Cs)F.
of
Glass
formation
of
glass-forming
5-20
mol%.
The
RF concentration
kinetics
compositions
Maxima
RF concentrations
Kg1 on the
crystallization
systems
with
decreases
abilities
composition
Kg1 corresponding
increasing indicates
(100-x)
range
size that
Kg1
of
alkali is
mainly
determined
by Tc-Tg.
shows
the
that
temperature appears
Crystallization
addition
of
dependence in
the
kinetics
RF to
and
the
a minimum
composition
study
alkali-free of
the
corresponding
on LiF-containing
glass
modifies
activation
to
that
energy
of
glasses
the for
viscositycrystal
growth
Kg1 maximum.
ACKNOWLEDGEMENT This for
the
work
was
partially
Ministry
of
supported
Education,
by a Grant-in-Aid
Science
and
Culture,
P.Brun,
Mat.
for
Scientific
Japan
(Prof.
Research S.
Sakka.
No.
60430020). REFERENCES 1) M.Poulain, 2)
M.Poulain.
J.Siscavage
O.H.El-Bayoumi,
3) A.Lecoq
and
4)
J.Senegas, Solids 85
5)
P.L.Higby.
6)
Xiujian
7)
C.M.Baldwin
8)
M.Poulain,
9)
A.Hruby.
J.Lucas
and
J.
M.Poulain,
J.M.Reau. H.Aomi. (1986) 315. J.E.Shelby
Zhao
and and
Submitted
J.
Phys.
11)
J.F.Cottrant,
B.Dubois
12)
Hefang
J.D.Mackenzie.
Hu and
N.P.Bansal, (1985)
70
G.Brunton.
S.Sakka.
A.J.Bruce. 379. Acta
Cryst.
to
J.
(1981)
K.Matusita
14)
and
M.Suscavage.
S.Sakka.
293
Solids
Am.
Appl.
J.
Non-Cryst.
Ceram.
10 (1975) Solids
Phys.
Sot.
243.
73 (1985)
613.
101.
J.
M.Poulain.
J.
58
Non-Cryst.
(1985)
4142.
Solids. 62
(1979)
537.
279. (1972)
1187.
Bull.
Inst.
Chem.
J.Portier,
J.
R.H.Doremus
829
Bull.
Non-Cryst.
and
B 22
and
Res.
34 (1979)
P.Hagenmuller
J.D.Mackenzie.
Nature Czech.
and
J.
B.Bendow.
Non-Cryst.
10)
13)
and
(1973)
Mat.
Non-Cryst. and
2294.
Res., Res. Solids
C.T.Moynihan,
Kyoto
Univ.
Bull.
20
(1985)
54 (1983)
J.
20
(1981)
159.
203.
241.
Non-Cryst.
Solids