- Email: [email protected]
Formation and optical absorption of Bi2S3 colloids in glasses
Journal of Non-Crysl;llline North-Holland. kmlerdanl
FORMATION
LEI
Solids 95 & 96 (1987)
601
AND OPTICAL
WEICUO
YIN
OF BiZS3
ABSORPTION
BAOZHONC
Institute
Shanghai
601 - 608
of
COLLOIDS
IN GLASSES
AND HLIANC XIHUAI
Ceramics,
Sinica,
Academia
Shanghai
200050,
China
By selgfting p5ase-separable glass system as the base glass and by introducand 5 ions as coloring agents ing Eli from BiZO, and ZnS respectively, we obLained a colored glass of SiO 43 0 -Al 0 -Na20 with semiconductor Bi S colloids as colorant. Optical a 8 sorp2?. ion 27o this glass is similar to t 63e Bi2S3 polycrystals. Effects of composition and heat treatment on the optical absorption of glasses are also studied. TEt4 photographs in the paper show the phase separation and Lhe formation of 81~5~ colloids in Na20-E203 phase when the glasses are heat-treated.
1.
INTRODUCTION Based
band
on
the
consideration
solid,
of
oration
selenium,
of
that
It
colorants
that
plays
From
in order then
oration
on, of
infrared
of
in
(3)
semiconductor main
basis is
for to
the
and oxidizing),
Cd!%
electron in and the
are
can
which
they
of Many with
slmllar
absorption with
same
col-
the
series
new
absorption
the
fluorence
glasses, inert
of
to
edges
revealed
the
and
relevent spectrum the
as
presence
have
a larger
0022-3093/87/$03.50 0 Elsevier Science Publishers (North-Holland Physics Publishing Division)
B.V.
are during
so small
that
and
to build
up the
theoretical
an reasonable
scheme
we advance
glass
glasses compounds
are
compounds
semiconductors as base
new filter
semiconductor
difficulties
with form
coloration”! on
colloids
TEM have
getting of
colorants
these
system
the
the
col-
coloration”.
accordance
and
in
evaporation
these
the
in
and of
glasses.
the
glass
several
optical
the
state”
research
semiconductor
show
defraction
remaining
of
of
col-
196Os,
“semi-conductor
“semiconductor (1)
energy
the
“colloidal
same optical
glasses
in
in
can
early
mechanism
made
of
of
not
phase,
guidance
with
colorants
dispersive
the
doped
the
separable
we successfully
the of
colloidal
the
experimental
and
mechanism:
the
traditional
the
the
determines mechanism in
not
the
further
the
production
phasephase
from
value
To overcome
introduce
it
difficulties
cause
be struck.
he called
the
X-ray,
glasses
ruby
show
colloids
which
the
both
decomposition
-melting,
order
studied
and
technological
oxidation,
not
glasses
coefficients
crystal.
range
and
and
made
under
glasses
(2)
role,
have
support the
temperature
The
main
crystals,
crystals. CdSe
the
authors
results size
definite
“semi-conductivity
glasses
short
anLimony
Lhe
glasses2--9,
filter
corresponding
and
to distinguish
many
these
experimental
its
is
the
sunlmarized
copper
concluded
oration”
that
Xi-huai
Huang
the
(lessdecomposing, themselves, to concentrate
solubility,
the
glass
glasses
can
that
evaporizing
and the facilitaing
to select colorants
in
the
forma-
tion
oF semiconductor
Formation
the
colloids. optical
and
In
the
absorption
present
paper
OF Bi2Sj
colloids
we report
in
the
resrarch
on
Na20-A1203-E1203-Si02
glass.
2.
EXPERIMENTAL 2.1
Preparation
and
1) Selection
heat
Na20-A1203-8203-Si02 glass
system
glass
possesses
study
it
High
For
6-Bh.
2)
in
lh,
Preparation
with
crucible
and
chemical at
melts
heat
Bi203
Furnance.
Glass For
Samples’
melts
were
SO-40min,
heat
poured
then
treatment
controlled
the
ZnS were
and
electric
we can
cleraly
were
H3E03 Furnance
plate,
mixed
at
and
cast
containing
fully
mixed
For
a steel
with
6-Flh
plate,
the
1420-
annealed
and in
glass
a silica
electric
a Harbour
annealed
and
cast
Batches
in
poured
at
stove. a electric
in
temperature
and
controller.
program
that
This
chemical
good
stove.
was processed
temperature
by
on
Al(OH)>
a Harbour
1400-142O’C
cooled
temperature(3-5’C/min),
of
at
so
Eli2S3 colloids
of and
melted
the
and
region.
colloids.
on a steel
poured
with
treatment
purity
1350-13L10°C,
500-52O’C
were
In this
forming
properties
Na2C03,
in
glass.
base
glass
properties
purity
cryclble
cooled
the
by semiconductor
chemical
then
as
large
in
UV-Lransmission
a Rh-Pt
Glass
For
place mechanical
caused
quartz,
melted
500-52O’C
a good
has
SiO2
and
was selected
take
Lechnological,
absorption
purity
1450?
doped
also
optical
the
together
at
a good
can
glass
base
system
separation
samples
of
of
glass
phase
durability,
treatment
preparation
and
strove, were
duration
Samples
were
the all
rising
rate
automatically with
cooled
the
stove. 2.2
Measurement
of
The absorption taining
and
glasses
measured
at
polished
with
room
of For
the
with
spectrometer
Philips OF base with
spectra
at
diFFerant
by
spectrometer
of
eroded
thin
glasses
and
and/or
W-5270
and
the
Bi2Sj
duration
conwere
samples
SV-50A,
transmission
through
in
1X HF solution
OF the
enough
For
size
were
a modulation
For
electron
the
and
replica
30s
in
were
and
beam
point
tech-
order
to
transmission
3mmXZOpm for
glasses(Face-scanning
EDAX 9100 glasses
base
lmm.
Samples to
of
temperatures
was made
were
Ar + ions
ESR spectra FE-lx
samples
replica
Microcompositions
deterimined
of
microstructure.
werebombardedby through.
temperature
a thickness
Samples
elucidate
transmission
heat-treated
TEN observation niqe.
Samples
to
penetrate
analysis)
were
instrument. determined
at
magnetic
Field
15’C of
with
X wave
100 Khz.
band
JES
3.
EXPERIMENTAL
3.1
Base
With
RESULTS
glass
the
substitution
of
A1203
64Si02(19-x)E1203(6+x)A120311Ns20 large ing
of
amount
at ‘1
bubble
1420-145O’C.
for
and
sand,
We can
get
glasses
and
good
tion
edges show
for
‘2,
Fig.2
two
shows
transition signals
may
glasses,
and
the
metal result
from the
the
8 for
ESR spectra or
in
with the
remaining
the
high
glasses
contain
viscosity
melL-
when
compositions.
following
‘3,
earth
UV-absorption
*l,
1850
2210
peaks
1910
and
*4.
UV-absorp-
1850-2500
are
8 for
*2 and
*l,
‘3
Between
of
and
ions
*2,
8.
positions
structural
the
al
glass
of
rare
glass
of
located
peaks,
1925
ions
so may
are
absorption
2190x
spectra
glasses
the
Nag0
*4 64Si0219B2036A120311Ns20
UV-absorption
all
of
glasses 11,
the
for
*2 64Si0220E12035A120311Ns20
*3 63Si0221E2036A120310Ns20 shows
are
glasses
64Si0221E12034A120311Ns20
Fig.1
or 8203
6203
64Si02(19+x)El2036A1203(11-x)Ns20
and
2235
8,
‘3.
As no magnetic
defects peaks.
during
added (or
1950
8
‘4.
1 v
were
the
8 and
active
glass-melting,
color
centers)
of
ESR the
2
3
1600
2100
1 4, I500
2600
Wavelength(i) Fig.1
UV-absorption the
3.2
Bi2S3
to black
show
(thick
of
IK
, I l I,, 4050
3050
Fig.2
ESR spectra
glass
base
containing
Experiments
spectra
I,
of
the
X I Ci’T
base
glass
glasses glass
that
sample)
*l,
f2,
*3,
*4 and
when heat-treated,
‘6
can
while
glass
10”s
have
be
*5,
struck
f7
yellow
from
and *8
show
eFfect
on
no
changes. also
Experiments phase
separation
glasses
are
the
content
(2)
Bi2S3
amount
of
Full of and
When
of
stripes
(this
Eli203
in
the
deposits and
ZnS are
(1)
that,
glass.
A1203
Bi
indicate
of
more
be
added.
1X ZnS is
may be related
batches, can
Zn2+ than
homogeneity obtained (3)
at
glasses
the
a strong added
to
the
the
batches,
the
to 81 3+ ions);
by decreasing
of
be improved.
glasses
bottom can
only
of
can crucible
be struck
when
large
by adding
604
Lb
reducing
agent
other
author’s
results
in
such
8s C4H406 lo.
resuts
to
be struck
temperature
duration
and
Si02 61.33 61.97 61.97 61.97
‘2’3
6.51
21.28 21.49 21.49 21.49 21.49 21.49 21.49 21.49
5.55 5.55 5.55 5.55 5.55 5.55 5.55
Fig.3,
4 and
different
heat
of
spectrum
Bi2S3
Fig.3,
From
S2-
and
in Bi3+
ions
increasing to
struck
and
treated.
In
glass
from
a high
and
in are
in Fig.9 the
glass
37.74%
Ei element In
glasses solubility,
of
beam on
3.89%
is
excessive
learn
we can concentrated and
at
in
the
in same
of
only
of
with with
glasses
the
glasses
high with
also,
treatment,
edges the
show doped
doped
heat
clearly
the
are
not
move
so sharp
visible
indicate
that
when
of
0.508%
heat-
accordingly
region.
We can
see
Bi
only
that and
this
means
elements
the
Bi,
identified.
be
their
that
in
S and 5.67%
focusing
by
S elements
black
the
which
content region
indicates
that
colloids. glasses
Na20-B203 they
can
and
colloids are
transmission).
Identified,
percents
glasses
infrared
and
Bi2S3
that
when
ldentlfied
be
by direcl
be
Na,
show
phase
can
Ei2S3
time
with
transmission
glasses
glasses to
dispersive
the
the
f7
the
glasses
and
while
replica)
in Fig.8
S can
0.206%
Al,
*4 and shows
treatment
absorption
Fig.9-11,
point
The weight
low.
heat
curves
(taken
glasses,
is
*2,
Fig.5
a “long-tail”.
in
Bi nor
glass
of
subjected
colloids
neither
1.0 0.50 -
regions,
the
by
Fig.8
black
Si,
summary
are
the
the
-
-
black,
are
Na20-B203
in
-
1.0
before
to
they
transmission
colloids
EDAX patterns
electron
that
shows
no Bi2S3
Fig.7(a)
-
0.75
near-infrared
yellow
taken
the
Na2S
.
see
and
increasing
1.0 1.0
curves
transmission
the
is
with
E12S3
C4tl606
respectively,
temperature
(Fig.7
grow
Ei2S3
0.20 0.50 0.50 0.50 0.50 0.50 -
when
polycrystals
shows
graphic
0.15 0.50 0.55 0.50 0.50 0.50 0.50 0.25
from
treatment
TEM photographs
deposit
10.88 10.99 10.99 10.99 10.99 10.99 10.99 10.99
and
to
+ LnO
glass
and
increases
containing
ZnS
12
contrast f
may be “burn-up”.
glasses
of
is
H2SCg)
temperatures,
colorants
color
transmission
visible
wavelength, Bi2S3
the
temperatures
no changes
heat
longer
as the
the
high of
Bi203
6 we can
the
are
show
at
Na20
polycrystals
4 and
transmission
Bi3+
6 show treatment
this
Na2S,
2115 + H20Cg)--*
damage
compositions
A1203
61.97 61.97 61.97 61.97
the
melling,
of
Calculated NO.
sulphur
(5)
colloids in glasws
containing
batches
reaction
the of
lo.
er al. / Bi,S,
for
(4)
evaporation
the
difficult
Weipo
are phase
combine
heat-treated in
to
which
Form
the they
Bi2S3
colorants
have
compound,
a greater
resulting
in
605
f60 l&!Tc-l 2
g$ 50 ‘lo
+
3
4
30
20 IO
6
Fig. glass
3.
7
15h;
10 12 14 16 18 Wavelength,x103 IAl
Transmission
with temperatures treatment;
for
6
curves
of
20
No.
0
22
2
Fig. 5. Transmission Bi2SJ polycrystals
different heat treatment l--Without heat Z--72O'C for 15h; 3--740%
4--
76O’C
for
12 3 4 wavelength. x104 IA)
5
spectrum (0.60 mm)
of
15h
100 90
1
I.
I
Fig. glass
6. Transmission with different
curves of No.7 heat treatment
temperatures
l--Without 2--76O’C 3--780%
Fig. glass
4.
Transmission with different
curves heat
temperatures
l--Without 2--74O’C 3--75O’C 4--7309 5--780%
for for for for
heat treatment; 15h; 15h; 20h;
10h.
of
No.3
treatment
heat for for
treatment
6h 10h
I Fig.
11.
EDAX pattern black SDOt.
of
the
Lei Weiguo et al. / Bi,.S, colloidr
606
(a)
Without
(c)
Heat
heat
treatment
treatment,
at
600x
780%
30000x
For
(b)
ah,
in ghses
Heat treatment 10000x
fig. 8. sample
KM photograph showing of glass microstructure
Heat treatment 20000x
Fig.
EDAX pattern scanning
fig.
of
face-
10.
74O'C
TEM photograph
Fig. 7. changes
9.
at
at
of-
78O'C
EDAX pattern black spot
For
the
For
of
the
flh,
ah,
in
change
the
similar
4.
results
curves
in photochromic
Bando 11
glasses.
of
has
also
obtained
glasses.
DISCUSSION
4.1
Optical
Based that
the
origin
free
changes
which
the
“long-tail”
absorption
edge
cause
Bi2Sj
(10
Preparation
technology
preparation
of
glass)
is
agent)
in glass
based
on
is
are
do
and
Inspired
to
lower
structure,
large
the
of
4.3
by
deviation
Ei2S3
for
may
phase
amount
will of
place
take
easy
to
get
the
in
inspiration. of
colorant
of
to
due
semiconductor
chemical and
one
in chemical
colloids
can
nucleate thing of
industry,
of
potential be promoted.
colorants
we can
phase
differ
system,
and
we should
collect
separation
phase
phase
the
of
melted
the
collected.
easy
the
at when
in
decomposition
be
glass
coloration
important
As a result
properties
the
be concentrated,
and
them,
photochromic the
supersaturation in
most
colorants
process
(or in
colorants
of
the
concentrating
and
a small
quantity
are
to
due
resulting
remaining
photochromic
colorants dissolve
matrix
oxidization
to
(including
of
colorants
prepartion,
this
for
glass
solubility
glass
and
extraction
the
the
glass
of
separation,
from
the
the
other’s,
concentrating
in
difference,
this
clearly
Fig.7
and
colorant
of
shows
function. Concentrating
of
odynamic
rule,
mony
glasses.
analyse
red
a
a excessive
a layer
Secondly,
has
structural
with
with
it
and
and
temperature
ratio
temperature,
the
evaporation,
structure
formation
this
from
and
foundation
we put
one
the
deposit
practical
colorants
composition, when
high
spectrum.
the
high,
the the
by
dispersive a
temperature,
that,
glass-melting,
lays
with
be sufficient Turn
to avoid
during
of
reasons,
sharp,
region,
system
colored
that
at
requires
must up.
conclusion
glass
of
fact
varies
heat-treated This
grow
at
orthorhomic
stoichiometric
the
very
infrared
12
semiconductor
the
temperature,
glass
the formation
the
following
the
1s not
near
absorption
from
The
glass.
the
to
to
related
polycrystal
the
by wt)
4.2
glass
at
to
due
“long-tail”.
the
high
arrive
is
crystal
Ei2S3
belongs
influences
rata
directly
glass
of
in
in Bi2S3
also,
further
Bi/S
we can
may be of
absorption
place
content,
results absorption
optical
carrier
take
glass
colloids.
of
the
strong
of
of
semiconductor
The
of
experimental
change
firstly,
01
absorption
on
the
Bi2S3
in
transmission
of
some
colorants
we can
other
It
make
is
also
experimental
(or use
impurities)
of
it
useful results
in to
the
by phase
preparation
understand and
facts.
this
separation of rule
is
selenium to explain
a thermand
antiand
way
is
It has
a good
way
a M. P lower
leaving
to
than
inLroduce 685’C,
a Eli excessive
ZnS is
to
during
Some authors
it
is
easy
, and
Zn
to
+ ZnS,
not
by
with
decompose
Bi2S3
Bi2S3,
rising
temperature,
compound.
difficult
evaporation
by Bi203
colorants and
13
decompose
glass-melting reported
due
that
2+
2n
struck14,
others
reported
that
glasses.
Further
research
on
10”s
its
to
strength
glasses 2+
2n
in
S 2- ions 3,14 .
prevent
field
glass
red
function
can
large
containing
selenium the
2+
were could
difficult
to
made with
be
these
from
colored
2”
glasses
be 2+
free
IS
needed.
5.
CONCLUSION
1) For
the
separable
from
ants
time
first
glass
as
Bi203
the
and
glasses
logical
procedures
similar are
industry
Bi2S3 and
colored
glass
introducing
Bi
we also
technological
selecting
by
3+
and
prepared
S2-
semiconductor
other
procedures,
so
phase as color-
ions
that
these
techno-
effective.
2) The technological the
glass
ZnS respectively,
using
colored
we obtained base
in
procedures
production
of
these
this
kinds
paper
are
guiding
of
Function
for
OF glasses.
REFERENCES 1)
Huang
2)
Infrared
J.
Xi-huai, group,
3)
Infrared
4)
Chou
Yu-hua
5)
Wang
Shi-zhuo,
6)
2hu
group, and
l(2)
(1962)
98.
New Inorganic
Chinese
Materials,
2(l)
(1973)
9.
New Inorganic
Ya-juan,
Materials,
5(l)
(1977)
7)
Zheng
8)
Toriumi
Cue-pei,
9)
Wen Shu-lin,
10)
W. A.
Silicate
Sot.
4(l)
Guang-zhi,
J.
Chinese
Silicate
Sot.
lO(2)
11)
Y. Eiando,
R.
Kiryama,
12)
.I.
Black,
E.
M.
13)
H.
J.
Tress,
14)
N.
N.
Eobkova,
15)
F.
G. West-Oram,
et
Koohoo
Jin-wei,
J.
Glass,
Coloured
J.
Glass
Techn.
Smeklo Glass
Glass
Tech.
3(B)
(1983)
(1965) (1982) 738.
11.
4(1985)
5.W 50-1192.
Sci.
Mater.
al.,
Solids, Phys.
3(5)
(1962)
i Keramika,
Letters,
4 (1985)
568.
(1955).
Non-Cryst.
Tech”.
Optica,
Acta
Sheffield
et
Conwell
al., al.,
et
Tokkyo Feng
Weyl,
Chinese
He Yu-yong
Akihiko,
1.
J.
Liangen
Sheng
Sot.
Xi-huai,
Huang Yang
Silicate
Chem. 176.
3 (1983)
17 (1976)
18 (1975) Solids,
90.
1517.
119. 2 (1957)
240.
66. 190.
FORMATION
LEI
Solids 95 & 96 (1987)
601
AND OPTICAL
WEICUO
YIN
OF BiZS3
ABSORPTION
BAOZHONC
Institute
Shanghai
601 - 608
of
COLLOIDS
IN GLASSES
AND HLIANC XIHUAI
Ceramics,
Sinica,
Academia
Shanghai
200050,
China
By selgfting p5ase-separable glass system as the base glass and by introducand 5 ions as coloring agents ing Eli from BiZO, and ZnS respectively, we obLained a colored glass of SiO 43 0 -Al 0 -Na20 with semiconductor Bi S colloids as colorant. Optical a 8 sorp2?. ion 27o this glass is similar to t 63e Bi2S3 polycrystals. Effects of composition and heat treatment on the optical absorption of glasses are also studied. TEt4 photographs in the paper show the phase separation and Lhe formation of 81~5~ colloids in Na20-E203 phase when the glasses are heat-treated.
1.
INTRODUCTION Based
band
on
the
consideration
solid,
of
oration
selenium,
of
that
It
colorants
that
plays
From
in order then
oration
on, of
infrared
of
in
(3)
semiconductor main
basis is
for to
the
and oxidizing),
Cd!%
electron in and the
are
can
which
they
of Many with
slmllar
absorption with
same
col-
the
series
new
absorption
the
fluorence
glasses, inert
of
to
edges
revealed
the
and
relevent spectrum the
as
presence
have
a larger
0022-3093/87/$03.50 0 Elsevier Science Publishers (North-Holland Physics Publishing Division)
B.V.
are during
so small
that
and
to build
up the
theoretical
an reasonable
scheme
we advance
glass
glasses compounds
are
compounds
semiconductors as base
new filter
semiconductor
difficulties
with form
coloration”! on
colloids
TEM have
getting of
colorants
these
system
the
the
col-
coloration”.
accordance
and
in
evaporation
these
the
in
and of
glasses.
the
glass
several
optical
the
state”
research
semiconductor
show
defraction
remaining
of
of
col-
196Os,
“semi-conductor
“semiconductor (1)
energy
the
“colloidal
same optical
glasses
in
in
can
early
mechanism
made
of
of
not
phase,
guidance
with
colorants
dispersive
the
doped
the
separable
we successfully
the of
colloidal
the
experimental
and
mechanism:
the
traditional
the
the
determines mechanism in
not
the
further
the
production
phasephase
from
value
To overcome
introduce
it
difficulties
cause
be struck.
he called
the
X-ray,
glasses
ruby
show
colloids
which
the
both
decomposition
-melting,
order
studied
and
technological
oxidation,
not
glasses
coefficients
crystal.
range
and
and
made
under
glasses
(2)
role,
have
support the
temperature
The
main
crystals,
crystals. CdSe
the
authors
results size
definite
“semi-conductivity
glasses
short
anLimony
Lhe
glasses2--9,
filter
corresponding
and
to distinguish
many
these
experimental
its
is
the
sunlmarized
copper
concluded
oration”
that
Xi-huai
Huang
the
(lessdecomposing, themselves, to concentrate
solubility,
the
glass
glasses
can
that
evaporizing
and the facilitaing
to select colorants
in
the
forma-
tion
oF semiconductor
Formation
the
colloids. optical
and
In
the
absorption
present
paper
OF Bi2Sj
colloids
we report
in
the
resrarch
on
Na20-A1203-E1203-Si02
glass.
2.
EXPERIMENTAL 2.1
Preparation
and
1) Selection
heat
Na20-A1203-8203-Si02 glass
system
glass
possesses
study
it
High
For
6-Bh.
2)
in
lh,
Preparation
with
crucible
and
chemical at
melts
heat
Bi203
Furnance.
Glass For
Samples’
melts
were
SO-40min,
heat
poured
then
treatment
controlled
the
ZnS were
and
electric
we can
cleraly
were
H3E03 Furnance
plate,
mixed
at
and
cast
containing
fully
mixed
For
a steel
with
6-Flh
plate,
the
1420-
annealed
and in
glass
a silica
electric
a Harbour
annealed
and
cast
Batches
in
poured
at
stove. a electric
in
temperature
and
controller.
program
that
This
chemical
good
stove.
was processed
temperature
by
on
Al(OH)>
a Harbour
1400-142O’C
cooled
temperature(3-5’C/min),
of
at
so
Eli2S3 colloids
of and
melted
the
and
region.
colloids.
on a steel
poured
with
treatment
purity
1350-13L10°C,
500-52O’C
were
In this
forming
properties
Na2C03,
in
glass.
base
glass
properties
purity
cryclble
cooled
the
by semiconductor
chemical
then
as
large
in
UV-Lransmission
a Rh-Pt
Glass
For
place mechanical
caused
quartz,
melted
500-52O’C
a good
has
SiO2
and
was selected
take
Lechnological,
absorption
purity
1450?
doped
also
optical
the
together
at
a good
can
glass
base
system
separation
samples
of
of
glass
phase
durability,
treatment
preparation
and
strove, were
duration
Samples
were
the all
rising
rate
automatically with
cooled
the
stove. 2.2
Measurement
of
The absorption taining
and
glasses
measured
at
polished
with
room
of For
the
with
spectrometer
Philips OF base with
spectra
at
diFFerant
by
spectrometer
of
eroded
thin
glasses
and
and/or
W-5270
and
the
Bi2Sj
duration
conwere
samples
SV-50A,
transmission
through
in
1X HF solution
OF the
enough
For
size
were
a modulation
For
electron
the
and
replica
30s
in
were
and
beam
point
tech-
order
to
transmission
3mmXZOpm for
glasses(Face-scanning
EDAX 9100 glasses
base
lmm.
Samples to
of
temperatures
was made
were
Ar + ions
ESR spectra FE-lx
samples
replica
Microcompositions
deterimined
of
microstructure.
werebombardedby through.
temperature
a thickness
Samples
elucidate
transmission
heat-treated
TEN observation niqe.
Samples
to
penetrate
analysis)
were
instrument. determined
at
magnetic
Field
15’C of
with
X wave
100 Khz.
band
JES
3.
EXPERIMENTAL
3.1
Base
With
RESULTS
glass
the
substitution
of
A1203
64Si02(19-x)E1203(6+x)A120311Ns20 large ing
of
amount
at ‘1
bubble
1420-145O’C.
for
and
sand,
We can
get
glasses
and
good
tion
edges show
for
‘2,
Fig.2
two
shows
transition signals
may
glasses,
and
the
metal result
from the
the
8 for
ESR spectra or
in
with the
remaining
the
high
glasses
contain
viscosity
melL-
when
compositions.
following
‘3,
earth
UV-absorption
*l,
1850
2210
peaks
1910
and
*4.
UV-absorp-
1850-2500
are
8 for
*2 and
*l,
‘3
Between
of
and
ions
*2,
8.
positions
structural
the
al
glass
of
rare
glass
of
located
peaks,
1925
ions
so may
are
absorption
2190x
spectra
glasses
the
Nag0
*4 64Si0219B2036A120311Ns20
UV-absorption
all
of
glasses 11,
the
for
*2 64Si0220E12035A120311Ns20
*3 63Si0221E2036A120310Ns20 shows
are
glasses
64Si0221E12034A120311Ns20
Fig.1
or 8203
6203
64Si02(19+x)El2036A1203(11-x)Ns20
and
2235
8,
‘3.
As no magnetic
defects peaks.
during
added (or
1950
8
‘4.
1 v
were
the
8 and
active
glass-melting,
color
centers)
of
ESR the
2
3
1600
2100
1 4, I500
2600
Wavelength(i) Fig.1
UV-absorption the
3.2
Bi2S3
to black
show
(thick
of
IK
, I l I,, 4050
3050
Fig.2
ESR spectra
glass
base
containing
Experiments
spectra
I,
of
the
X I Ci’T
base
glass
glasses glass
that
sample)
*l,
f2,
*3,
*4 and
when heat-treated,
‘6
can
while
glass
10”s
have
be
*5,
struck
f7
yellow
from
and *8
show
eFfect
on
no
changes. also
Experiments phase
separation
glasses
are
the
content
(2)
Bi2S3
amount
of
Full of and
When
of
stripes
(this
Eli203
in
the
deposits and
ZnS are
(1)
that,
glass.
A1203
Bi
indicate
of
more
be
added.
1X ZnS is
may be related
batches, can
Zn2+ than
homogeneity obtained (3)
at
glasses
the
a strong added
to
the
the
batches,
the
to 81 3+ ions);
by decreasing
of
be improved.
glasses
bottom can
only
of
can crucible
be struck
when
large
by adding
604
Lb
reducing
agent
other
author’s
results
in
such
8s C4H406 lo.
resuts
to
be struck
temperature
duration
and
Si02 61.33 61.97 61.97 61.97
‘2’3
6.51
21.28 21.49 21.49 21.49 21.49 21.49 21.49 21.49
5.55 5.55 5.55 5.55 5.55 5.55 5.55
Fig.3,
4 and
different
heat
of
spectrum
Bi2S3
Fig.3,
From
S2-
and
in Bi3+
ions
increasing to
struck
and
treated.
In
glass
from
a high
and
in are
in Fig.9 the
glass
37.74%
Ei element In
glasses solubility,
of
beam on
3.89%
is
excessive
learn
we can concentrated and
at
in
the
in same
of
only
of
with with
glasses
the
glasses
high with
also,
treatment,
edges the
show doped
doped
heat
clearly
the
are
not
move
so sharp
visible
indicate
that
when
of
0.508%
heat-
accordingly
region.
We can
see
Bi
only
that and
this
means
elements
the
Bi,
identified.
be
their
that
in
S and 5.67%
focusing
by
S elements
black
the
which
content region
indicates
that
colloids. glasses
Na20-B203 they
can
and
colloids are
transmission).
Identified,
percents
glasses
infrared
and
Bi2S3
that
when
ldentlfied
be
by direcl
be
Na,
show
phase
can
Ei2S3
time
with
transmission
glasses
glasses to
dispersive
the
the
f7
the
glasses
and
while
replica)
in Fig.8
S can
0.206%
Al,
*4 and shows
treatment
absorption
Fig.9-11,
point
The weight
low.
heat
curves
(taken
glasses,
is
*2,
Fig.5
a “long-tail”.
in
Bi nor
glass
of
subjected
colloids
neither
1.0 0.50 -
regions,
the
by
Fig.8
black
Si,
summary
are
the
the
-
-
black,
are
Na20-B203
in
-
1.0
before
to
they
transmission
colloids
EDAX patterns
electron
that
shows
no Bi2S3
Fig.7(a)
-
0.75
near-infrared
yellow
taken
the
Na2S
.
see
and
increasing
1.0 1.0
curves
transmission
the
is
with
E12S3
C4tl606
respectively,
temperature
(Fig.7
grow
Ei2S3
0.20 0.50 0.50 0.50 0.50 0.50 -
when
polycrystals
shows
graphic
0.15 0.50 0.55 0.50 0.50 0.50 0.50 0.25
from
treatment
TEM photographs
deposit
10.88 10.99 10.99 10.99 10.99 10.99 10.99 10.99
and
to
+ LnO
glass
and
increases
containing
ZnS
12
contrast f
may be “burn-up”.
glasses
of
is
H2SCg)
temperatures,
colorants
color
transmission
visible
wavelength, Bi2S3
the
temperatures
no changes
heat
longer
as the
the
high of
Bi203
6 we can
the
are
show
at
Na20
polycrystals
4 and
transmission
Bi3+
6 show treatment
this
Na2S,
2115 + H20Cg)--*
damage
compositions
A1203
61.97 61.97 61.97 61.97
the
melling,
of
Calculated NO.
sulphur
(5)
colloids in glasws
containing
batches
reaction
the of
lo.
er al. / Bi,S,
for
(4)
evaporation
the
difficult
Weipo
are phase
combine
heat-treated in
to
which
Form
the they
Bi2S3
colorants
have
compound,
a greater
resulting
in
605
f60 l&!Tc-l 2
g$ 50 ‘lo
+
3
4
30
20 IO
6
Fig. glass
3.
7
15h;
10 12 14 16 18 Wavelength,x103 IAl
Transmission
with temperatures treatment;
for
6
curves
of
20
No.
0
22
2
Fig. 5. Transmission Bi2SJ polycrystals
different heat treatment l--Without heat Z--72O'C for 15h; 3--740%
4--
76O’C
for
12 3 4 wavelength. x104 IA)
5
spectrum (0.60 mm)
of
15h
100 90
1
I.
I
Fig. glass
6. Transmission with different
curves of No.7 heat treatment
temperatures
l--Without 2--76O’C 3--780%
Fig. glass
4.
Transmission with different
curves heat
temperatures
l--Without 2--74O’C 3--75O’C 4--7309 5--780%
for for for for
heat treatment; 15h; 15h; 20h;
10h.
of
No.3
treatment
heat for for
treatment
6h 10h
I Fig.
11.
EDAX pattern black SDOt.
of
the
Lei Weiguo et al. / Bi,.S, colloidr
606
(a)
Without
(c)
Heat
heat
treatment
treatment,
at
600x
780%
30000x
For
(b)
ah,
in ghses
Heat treatment 10000x
fig. 8. sample
KM photograph showing of glass microstructure
Heat treatment 20000x
Fig.
EDAX pattern scanning
fig.
of
face-
10.
74O'C
TEM photograph
Fig. 7. changes
9.
at
at
of-
78O'C
EDAX pattern black spot
For
the
For
of
the
flh,
ah,
in
change
the
similar
4.
results
curves
in photochromic
Bando 11
glasses.
of
has
also
obtained
glasses.
DISCUSSION
4.1
Optical
Based that
the
origin
free
changes
which
the
“long-tail”
absorption
edge
cause
Bi2Sj
(10
Preparation
technology
preparation
of
glass)
is
agent)
in glass
based
on
is
are
do
and
Inspired
to
lower
structure,
large
the
of
4.3
by
deviation
Ei2S3
for
may
phase
amount
will of
place
take
easy
to
get
the
in
inspiration. of
colorant
of
to
due
semiconductor
chemical and
one
in chemical
colloids
can
nucleate thing of
industry,
of
potential be promoted.
colorants
we can
phase
differ
system,
and
we should
collect
separation
phase
phase
the
of
melted
the
collected.
easy
the
at when
in
decomposition
be
glass
coloration
important
As a result
properties
the
be concentrated,
and
them,
photochromic the
supersaturation in
most
colorants
process
(or in
colorants
of
the
concentrating
and
a small
quantity
are
to
due
resulting
remaining
photochromic
colorants dissolve
matrix
oxidization
to
(including
of
colorants
prepartion,
this
for
glass
solubility
glass
and
extraction
the
the
glass
of
separation,
from
the
the
other’s,
concentrating
in
difference,
this
clearly
Fig.7
and
colorant
of
shows
function. Concentrating
of
odynamic
rule,
mony
glasses.
analyse
red
a
a excessive
a layer
Secondly,
has
structural
with
with
it
and
and
temperature
ratio
temperature,
the
evaporation,
structure
formation
this
from
and
foundation
we put
one
the
deposit
practical
colorants
composition, when
high
spectrum.
the
high,
the the
by
dispersive a
temperature,
that,
glass-melting,
lays
with
be sufficient Turn
to avoid
during
of
reasons,
sharp,
region,
system
colored
that
at
requires
must up.
conclusion
glass
of
fact
varies
heat-treated This
grow
at
orthorhomic
stoichiometric
the
very
infrared
12
semiconductor
the
temperature,
glass
the formation
the
following
the
1s not
near
absorption
from
The
glass.
the
to
to
related
polycrystal
the
by wt)
4.2
glass
at
to
due
“long-tail”.
the
high
arrive
is
crystal
Ei2S3
belongs
influences
rata
directly
glass
of
in
in Bi2S3
also,
further
Bi/S
we can
may be of
absorption
place
content,
results absorption
optical
carrier
take
glass
colloids.
of
the
strong
of
of
semiconductor
The
of
experimental
change
firstly,
01
absorption
on
the
Bi2S3
in
transmission
of
some
colorants
we can
other
It
make
is
also
experimental
(or use
impurities)
of
it
useful results
in to
the
by phase
preparation
understand and
facts.
this
separation of rule
is
selenium to explain
a thermand
antiand
way
is
It has
a good
way
a M. P lower
leaving
to
than
inLroduce 685’C,
a Eli excessive
ZnS is
to
during
Some authors
it
is
easy
, and
Zn
to
+ ZnS,
not
by
with
decompose
Bi2S3
Bi2S3,
rising
temperature,
compound.
difficult
evaporation
by Bi203
colorants and
13
decompose
glass-melting reported
due
that
2+
2n
struck14,
others
reported
that
glasses.
Further
research
on
10”s
its
to
strength
glasses 2+
2n
in
S 2- ions 3,14 .
prevent
field
glass
red
function
can
large
containing
selenium the
2+
were could
difficult
to
made with
be
these
from
colored
2”
glasses
be 2+
free
IS
needed.
5.
CONCLUSION
1) For
the
separable
from
ants
time
first
glass
as
Bi203
the
and
glasses
logical
procedures
similar are
industry
Bi2S3 and
colored
glass
introducing
Bi
we also
technological
selecting
by
3+
and
prepared
S2-
semiconductor
other
procedures,
so
phase as color-
ions
that
these
techno-
effective.
2) The technological the
glass
ZnS respectively,
using
colored
we obtained base
in
procedures
production
of
these
this
kinds
paper
are
guiding
of
Function
for
OF glasses.
REFERENCES 1)
Huang
2)
Infrared
J.
Xi-huai, group,
3)
Infrared
4)
Chou
Yu-hua
5)
Wang
Shi-zhuo,
6)
2hu
group, and
l(2)
(1962)
98.
New Inorganic
Chinese
Materials,
2(l)
(1973)
9.
New Inorganic
Ya-juan,
Materials,
5(l)
(1977)
7)
Zheng
8)
Toriumi
Cue-pei,
9)
Wen Shu-lin,
10)
W. A.
Silicate
Sot.
4(l)
Guang-zhi,
J.
Chinese
Silicate
Sot.
lO(2)
11)
Y. Eiando,
R.
Kiryama,
12)
.I.
Black,
E.
M.
13)
H.
J.
Tress,
14)
N.
N.
Eobkova,
15)
F.
G. West-Oram,
et
Koohoo
Jin-wei,
J.
Glass,
Coloured
J.
Glass
Techn.
Smeklo Glass
Glass
Tech.
3(B)
(1983)
(1965) (1982) 738.
11.
4(1985)
5.W 50-1192.
Sci.
Mater.
al.,
Solids, Phys.
3(5)
(1962)
i Keramika,
Letters,
4 (1985)
568.
(1955).
Non-Cryst.
Tech”.
Optica,
Acta
Sheffield
et
Conwell
al., al.,
et
Tokkyo Feng
Weyl,
Chinese
He Yu-yong
Akihiko,
1.
J.
Liangen
Sheng
Sot.
Xi-huai,
Huang Yang
Silicate
Chem. 176.
3 (1983)
17 (1976)
18 (1975) Solids,
90.
1517.
119. 2 (1957)
240.
66. 190.