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Ion-exchangeable layered niobates as photocatalysts
Catalysis Today, 16 (1993)479-466 Elsevier SciencePublishers B.V., Amsterdam
lon-exchangeable
K. Domen, and
Y.
layered
Ebina,
479
niobates
T.
Sekine,
as photocatalysts
A. Tanakaa,
J. Kondo,
C. Hirose
Research
Laboratory
of Technology,
aNikon
1-10-l
Co.,
of Resources
4259
Utilization,
Tokyo
Nagatsuta,
Midori-ku,
Yokohama
Asamizodai,
Sagamihara
228,
Institute 227,
Japan
Japan
Abstract Silica
pillared-niohates
layered
perovskite,
swelling
as
reagents.
expanded
by
m*/g
obtained
was
was
ca.
used.
The
revealed
and that
when
the
with
BET
the
with
proton-exchanged
photocatalytic
precursor
of these
silica
of the
original It was
derivative.
pillared-niobates
spacing
of 'ca. 200
intercalated
those
ions
interlayer area
activities
compared
a, so called,
alkylammonium
surface
an octylammonium
were the
from
by using
photocatalytic
silica
characteristic
prepared
A product
1.2 nm and
pillared-niobates KCazNb3010
were
KCazNbaOlo,
showed
a high
and
activity.
1. INTRODUCTION Recently niobates instance, metal HZ
we
02
reaction
found
that
interlayer from
that
(A
that
quantum
the
water
to
For
Ni Hz0
or Pt into
10 % under
steady
catalysts,
it was
were
of which
photocatalysts
ultrafine
decomposes
In these
molecules
mechanism
of conventional
up
layered
activities.
with
spaces
efficiency [l-33.
intercalated
ion-exchangeable
loaded
interlayer
condition
spaces,
some
photocatalytic
K, Rb)
q
at the
at high
state
found
interesting
A4Nbs017
particles
and
have
exhibit
was such
decomposed very
at
different
as TiOz.
OQZO-5861/93/$6.00 0 1993Elsevier SciencePublishers B.V. All rights reserved.
the
480 Another in the metal are
example
of
layered
family
of
layered
cations
at
the
generally
perovskite
interlayer
formulated
M = di
or trivalent
equals
to the
thickness
accumulation
A schematic
number
structure
In a concentrated metal
cations
replaced The at
by
Hi
ions
H+-exchanged the
are
family nm)
r51.
example,
however, and
the
activity layered
the
light
proved
to
we
compounds
only
visible
length which
region
(>
ultraviolet
to have light
seems
a
irradiation
of water
introduce
catalyst
of
into
suitable to be
In this we
preparation
of a pillaredperovskite
type
KCazNbs 010
because
to prepare
photocatalytic been
some
decomposition
in the
for
was
as a starting
material easy
sites
c-axis
molecules
photocatalytic
niobate. chosen
was
modification
oxidation
therefore,
examined
an overall
the
absorb
structure.
water
in visible
02 under
1.
to be
layer
reasons
is that
compounds
and
possible
the
the
RbPbzNb301o
Hz
further
indispensable. study,
materials
in Figure
intercalate
of
i.e.
direction.
100 % of alkali
are
as a result One
niobate
To accomplish OZ,
and
nm
to
photoresponse
most
to evolve
reduction
and
spaces - 0.2
almost
of n
sheet,
in c-axis
degradating
is known
number
macroanion
space
compounds
(A = alkaline The
unit
found
alkaline
These
3 is represented
q
without
exhibit
For
potential
NbOs
solution,
in these
while
photons.
and
0.1
interested
this 400
by
niobate
of the
are
contains
[4].
cation).
interlayer
form
inter-layer
increases
metal
of n
the
which
space
of the
acidic
at
photocatalysts
as A(Mn-lNbnOsn+l)
metal,
the
niobate
studied
although ultraviolet
it was and
the
activity in detail
it absorbed photons.
had [43,
only
0
A
.
M
@
NbOs
Figure 1. Schematic structure of a layered perovskite, AM2Nb&,.
HP
481 2. EXPERIMENTAL
KCazNbs01o
was
prepared
stoichiometric
mixture
10 h in air.
Photocatalytic
closed
gas
reaction
3. RESULTS
3.1.
of KzCO~,
circulation The
cell.
AND
in a platinum and
CaC03
reactions
system detail
with
was
an
crucible NbzOs
were inner
described
from at
1473
carried
out
irradiation
previously
a K for in a type
111.
DISCUSSION
Preparation
and
characterization
of
silica
pillared-
KCazNb3010
The
procedure
pillared-niobate This
1.
except
the
treatment.
adopted from
the
KCazNbaOlo
is following repetition
for
the of
KCa2Nb3010
preparation precursor
method
tetraethyl was
reported
of
is shown by
in Scheme
Landis
orthosilicate
ion-exchanged
silica
et al. [61
(TEOS)
in an aqueous
HN03
IKCazNb-JOlol
P t-
,t-
5M HNOJ aq. Stirring for 72 h at r.t.
C8H1,NHz/ heptane Reflux for 24 h
Si(OEt), Stirring for 72 h at SOT
Si(OEt)4:(CsH~,NHJ)CazNbjOlo
I L
/+Calcination
for 4 h
,
Silica pillared-(C~H~7NH3)Ca2NbjOlo Scheme 1. Preparation of Silica pillared-niobate.
28 I degree Figure 2. XRD pattern of modified KCa2Nb3010.
solution
(5 N) to substitute The degree
temperature.
H+ for K* ions for 72 h at room
of ion exchange
was more than 90 % which was determined analysis
of R+ concentration
The X-ray diffraction Figure
The c-axis
2(a).
the hydration
eluted
(XRD) pattern
into the aqueous af HCazNb3Olo
length was estimated
of the interlayer
was then swelLed
by a long-chain
to be 1.57 nm HCa2&bsOlo
alkylammonium
ion in heptane.
of the sample swelled
shown in Figure
2(b) which
by octyl~mmonium
shows the expanded
This sample was treated
c-axis
twice as mentioned
By this treatment
to intercalate
space
TEOS is expected
filled with alkyf-chains
The final pillared-niobate K for 9 h in air, only once,
was produced
same with that of HCazNbsO ~0 which of intercalated spacing.
into the ions.
by calcination
suggested
at 773
was carried
length after calcinetion
at
above.
of ammonium
When the TEOS treatment
the c-axis
is length of
in a neat TEOS solution
353 K for 72 h, which was repeated interlayer
solution.
is shown in
space occurred.
The XRD pattern 3.26 nm.
by this treatment
by atomic absorption
out
was almost
the
that the amount
TEOS was too small to expand the interlayer
Repeating
good reproducibility
the TEOS treatment for preparing
twice resulted
in a
the pillared-niobate.
Table 1 Comparison of c-axis lengths and BET surface areas of some pillared-niobates.
precursor
c-axis length
(nm)
surface area
before celcination
after Cal&nation
KVb~~)~a2Nb3010
3.26
2.93
200
G&$bSH3~Ca2Nb3010
3.92
3.36
180
5.00
4.31
50
After
the
calcination
was
thoroughly
burnt
was
diminished
by
octylammonium than was
that
to
to
the
silica
873
K and
the
collapsed
at
nm comparing sample When K,
respectively.
at the
K.
the
c-axis
of Thus,
all
the
samples
lengths
and
the
using and
after
the
measured of
the
that
volume
length
shows
the
although
atomic
temperature
surface
the
the
the of
in the
c-axis
the
alkylammonium The of
before
surface with
area the
This
increase
suggests
silica-pillared increse
length
of Si/Nb
ions.
and
BET
of the
increases.
were
Table 2 The composition of silica pillared-niobates
between
alkyl Table
2
determined 15 and
25 %
determined by EDX K
Si
Nb
Ca
GHl~dCm~dh
0.16
1.0
0.54
0.05
WdkdH3)Ca2~3010
0.22
1.0
0.70
0.07
(GsH37NJJ3)Ca2~3Olo
0.23
1.0
0.65
0.08
precursor
1
of
samples
silica-pillared-niobates
ratios
was
of alkyl-chain
77 K decreased
with
at
In Table areas
different
length for
indicates
to sinter
below.
of pillared-niobates.
decreases
composition The
at
of micropores
spaces
chane
EDX.
length
the
both
nm
completely
octadecilammmonium
However,
NZ adsorption
c-axis
the
with ions
calcination. by
interlayer
by
increased
1.36
were
This
was
BET
three
by
lengths
calcination
nm which
temperature
begins
pillar
described
prepared
ammonium
c-axis
interlayer
dodecil,
length
the
silica
ions,
intercalated
longer
973
pillared-niobates
c-axis
was
alkylammonium 2.93
of the
calcination
nm,
K for
octy1,
but
the
1.47
pillar
was
to that
K or
773
i.e.
length
or
structure 973
4 h, by which
c-axis
873
2.50
that
is shown
0.33
K for
the
intercalated
increased
at
773
of HCazNbaOlo.
decreased
fixed
at out,
484 which
increased X-ray
with
photoelectron
silica-pillared extent
of the
latter
sample.
observed that
but
of Ca
silica-
the
pillared
niobate
surface in the
aqueous
activity
In Table
methanol
intercalate
activity
water
solution at
the
are
very
the
low
for
was
of the
comparing
with
those
product
niobates
niobates and from
an
does
reaction
rate of Hz evolution / prnol*ti’ precursor
alone
Pt-loadedC)
KCazNbJ 010
14
100
HCazNb3 010
2200
8700
500
10800
-
9700
pillared-niobate
CsHlTNH3
pillared-niobate
C12H25NH3
pillared-niobate
C1sH3,NH3
not
occurs
Table 3 Comparison of rates of Hz evolution from an aqueous methanol solution a) catalystb)
of
niobate.
As KCazNb3010 the
for
segregation
of KCazNbs010
space,
for
preferentially
of Hz evolution
listed.
interlayer
to Nb
those
silica-pillared
rates
the was
of Ca and
silica-pillared
of
the
Si peak
same
silica
space
with
3, the
surface
no noticeable
but
of
the
niobate
was
and
to examine
intensities
that
interlayer
in comparison
HCazNbsOlo .
on
almost
occurred
photocatalytic
examined
were
indicates
Photocatalytic
were
intensity the
of HCazNb301o
measured
silica
Actually
This
The
of
signal
silica
on the
(XPS)
also
a silica-pillared
or Nb.
incorporated
were
segregation On
length.
spectra
niobate
HCatNb3Olo.
3.2
the c-axis
6600
a) CHsOH 50 ml + Hz0 300 ml, b) catalyst 1 g, Hg lamp (450 W) c) 0.1 wt%
485 only
at the
activity
external
of
HCanNb3Olo,
surface,
it.
When
the
activity
to
water.
is a typical
layered
lower any
that
silica
spaces. however,
the
to poison
activity,
Pt was
activity
to be a catalyst the
The
catalyst
is attached
When
for
by
onto
the
Hz evolution
between
is shown
in Table
HCazNb3010, when
methanol
than
two
As
are
rate
replaced
by ethanol
it was
in the
cases
sites interlayer
of
Pt
and
the
decreased
of magnitude
exhibit
is known
is considered
compared.
and
silica
rates For
lower
by
1-propanol
evolution ratesa) / pmol=h-’ HCazNbjO1ob’
pillared-niobate CSHI~NH~
MeOH
4670
8100
EtOH
384
5500
PrOH
43
1100
BuOH
30
1060
a) Pt 0.1 wt% loaded b) &-exchange degree > 95%
of Hz
drastically
Table 4 Dependence of Hz evolution rates from several alcohol solutions on KCazNb3Olo and silica pillared-niobate. alcohol
rather
sheet.
HCazNbsOlo
of HZ evolution
the
orders
alcohols
not
the
silica
4 where
from
pillared-catalyst,
on a niobate
difference
several
at
as
was
catalytic
sheets silica
site,
sites
A remarkable
from
does
the
completely.
pillared-niobate evolution
Pt-loading
silica
i.e.
of
as well
of HZ evolution
niobate
recovered
orders
rate without
low
ions,
ion-exchangeable
As
on
very H+
of
it blocks
loaded
HZ evolution
three
of methanol
of HCazNb3010.
photocatalytic
when
by
behavior
[4].
pillared-niobate than
the
replaced
intercalation
photocatalysts
silica
explains
were
increased
magni.t~tde due This
the
which
Ii+ ions
more and
l-
486 This
butanol. on
the
species
the
of
difficult other
although
these
for
of HZ
an aqueous
alcohol
silica
than
the
alcohols
for
attributed
to
the
pillaring.
silica
In summary, KCa2Nb3010
solution
effect spacing
which
30 times
longer the
with
comparing
was
attributed the
HZ
with to
of the
alkyl
pronounced rate
for
silica
increase
chains
should
spacing
for
rate
alkyl
longer
be to
Hz
even
chains
HCazNb3010. the
due
of
from
activity
evolution
intercalation
from
This
prepared
longer
On
chain.
less
higher
is
structural
evolution
interlayer
high
of alcohols
facilitated
the
photocatalytic
rather
extent
alkyl
HCazNb3010.
with of
HZ
activity
intercalation
is much
pillared-niobate
or butanol
of pillaring
for
a good
It showed
as propanol
was
that
silica
to the
the
longer
Actually
increase
exhibited
evolution. an aqueous
the
with
activity
solution
pillared-niobate
i.e.
pillared-niobate
remains.
butanol
activity
is attributed
evolution
it still
of photocatalytic
alcohols,
for the
hand,
dependence
dependence
of alcohols
intercalation more
strong
in such
This interlayer
of those
alcohols.
4. REFERENCES 1 2 3 4 5 6
A. Kudo, K. Sayama, A. Tanaka, K. Asakura, K. Domen, K. Maruya and T. Onishi, J. Catal., 120 (1989) 337. K. Sayama, A. Tanaka, K. Domen, K. Maruya and T. Onishi, J. Catal., 124 (1990) 541. K. Sayama, A. Tanaka, K. Domen, K.Maruya and T. Onishi, J. Phys. Chem., 95 (1991) 1345. K. Domen, J. Yoshimura, T. Sekine, A. Tanaka and T. Onishi, Catal. Lett., 4 (1990) 339. J. Yoshimura, Y. Ebina, A. Tanaka, J. Kondo and K. Domen, J. Phys. Chem., accepted for publication. M. E. Landis, B. A. Aufdembrink, P. Chu, I. D. Johnson, G. W. Kirker and M. K. Rubin, J. Am. Chem. Sot., 113 (1991) 3189.
lon-exchangeable
K. Domen, and
Y.
layered
Ebina,
479
niobates
T.
Sekine,
as photocatalysts
A. Tanakaa,
J. Kondo,
C. Hirose
Research
Laboratory
of Technology,
aNikon
1-10-l
Co.,
of Resources
4259
Utilization,
Tokyo
Nagatsuta,
Midori-ku,
Yokohama
Asamizodai,
Sagamihara
228,
Institute 227,
Japan
Japan
Abstract Silica
pillared-niohates
layered
perovskite,
swelling
as
reagents.
expanded
by
m*/g
obtained
was
was
ca.
used.
The
revealed
and that
when
the
with
BET
the
with
proton-exchanged
photocatalytic
precursor
of these
silica
of the
original It was
derivative.
pillared-niobates
spacing
of 'ca. 200
intercalated
those
ions
interlayer area
activities
compared
a, so called,
alkylammonium
surface
an octylammonium
were the
from
by using
photocatalytic
silica
characteristic
prepared
A product
1.2 nm and
pillared-niobates KCazNb3010
were
KCazNbaOlo,
showed
a high
and
activity.
1. INTRODUCTION Recently niobates instance, metal HZ
we
02
reaction
found
that
interlayer from
that
(A
that
quantum
the
water
to
For
Ni Hz0
or Pt into
10 % under
steady
catalysts,
it was
were
of which
photocatalysts
ultrafine
decomposes
In these
molecules
mechanism
of conventional
up
layered
activities.
with
spaces
efficiency [l-33.
intercalated
ion-exchangeable
loaded
interlayer
condition
spaces,
some
photocatalytic
K, Rb)
q
at the
at high
state
found
interesting
A4Nbs017
particles
and
have
exhibit
was such
decomposed very
at
different
as TiOz.
OQZO-5861/93/$6.00 0 1993Elsevier SciencePublishers B.V. All rights reserved.
the
480 Another in the metal are
example
of
layered
family
of
layered
cations
at
the
generally
perovskite
interlayer
formulated
M = di
or trivalent
equals
to the
thickness
accumulation
A schematic
number
structure
In a concentrated metal
cations
replaced The at
by
Hi
ions
H+-exchanged the
are
family nm)
r51.
example,
however, and
the
activity layered
the
light
proved
to
we
compounds
only
visible
length which
region
(>
ultraviolet
to have light
seems
a
irradiation
of water
introduce
catalyst
of
into
suitable to be
In this we
preparation
of a pillaredperovskite
type
KCazNbs 010
because
to prepare
photocatalytic been
some
decomposition
in the
for
was
as a starting
material easy
sites
c-axis
molecules
photocatalytic
niobate. chosen
was
modification
oxidation
therefore,
examined
an overall
the
absorb
structure.
water
in visible
02 under
1.
to be
layer
reasons
is that
compounds
and
possible
the
the
RbPbzNb301o
Hz
further
indispensable. study,
materials
in Figure
intercalate
of
i.e.
direction.
100 % of alkali
are
as a result One
niobate
To accomplish OZ,
and
nm
to
photoresponse
most
to evolve
reduction
and
spaces - 0.2
almost
of n
sheet,
in c-axis
degradating
is known
number
macroanion
space
compounds
(A = alkaline The
unit
found
alkaline
These
3 is represented
q
without
exhibit
For
potential
NbOs
solution,
in these
while
photons.
and
0.1
interested
this 400
by
niobate
of the
are
contains
[4].
cation).
interlayer
form
inter-layer
increases
metal
of n
the
which
space
of the
acidic
at
photocatalysts
as A(Mn-lNbnOsn+l)
metal,
the
niobate
studied
although ultraviolet
it was and
the
activity in detail
it absorbed photons.
had [43,
only
0
A
.
M
@
NbOs
Figure 1. Schematic structure of a layered perovskite, AM2Nb&,.
HP
481 2. EXPERIMENTAL
KCazNbs01o
was
prepared
stoichiometric
mixture
10 h in air.
Photocatalytic
closed
gas
reaction
3. RESULTS
3.1.
of KzCO~,
circulation The
cell.
AND
in a platinum and
CaC03
reactions
system detail
with
was
an
crucible NbzOs
were inner
described
from at
1473
carried
out
irradiation
previously
a K for in a type
111.
DISCUSSION
Preparation
and
characterization
of
silica
pillared-
KCazNb3010
The
procedure
pillared-niobate This
1.
except
the
treatment.
adopted from
the
KCazNbaOlo
is following repetition
for
the of
KCa2Nb3010
preparation precursor
method
tetraethyl was
reported
of
is shown by
in Scheme
Landis
orthosilicate
ion-exchanged
silica
et al. [61
(TEOS)
in an aqueous
HN03
IKCazNb-JOlol
P t-
,t-
5M HNOJ aq. Stirring for 72 h at r.t.
C8H1,NHz/ heptane Reflux for 24 h
Si(OEt), Stirring for 72 h at SOT
Si(OEt)4:(CsH~,NHJ)CazNbjOlo
I L
/+Calcination
for 4 h
,
Silica pillared-(C~H~7NH3)Ca2NbjOlo Scheme 1. Preparation of Silica pillared-niobate.
28 I degree Figure 2. XRD pattern of modified KCa2Nb3010.
solution
(5 N) to substitute The degree
temperature.
H+ for K* ions for 72 h at room
of ion exchange
was more than 90 % which was determined analysis
of R+ concentration
The X-ray diffraction Figure
The c-axis
2(a).
the hydration
eluted
(XRD) pattern
into the aqueous af HCazNb3Olo
length was estimated
of the interlayer
was then swelLed
by a long-chain
to be 1.57 nm HCa2&bsOlo
alkylammonium
ion in heptane.
of the sample swelled
shown in Figure
2(b) which
by octyl~mmonium
shows the expanded
This sample was treated
c-axis
twice as mentioned
By this treatment
to intercalate
space
TEOS is expected
filled with alkyf-chains
The final pillared-niobate K for 9 h in air, only once,
was produced
same with that of HCazNbsO ~0 which of intercalated spacing.
into the ions.
by calcination
suggested
at 773
was carried
length after calcinetion
at
above.
of ammonium
When the TEOS treatment
the c-axis
is length of
in a neat TEOS solution
353 K for 72 h, which was repeated interlayer
solution.
is shown in
space occurred.
The XRD pattern 3.26 nm.
by this treatment
by atomic absorption
out
was almost
the
that the amount
TEOS was too small to expand the interlayer
Repeating
good reproducibility
the TEOS treatment for preparing
twice resulted
in a
the pillared-niobate.
Table 1 Comparison of c-axis lengths and BET surface areas of some pillared-niobates.
precursor
c-axis length
(nm)
surface area
before celcination
after Cal&nation
KVb~~)~a2Nb3010
3.26
2.93
200
G&$bSH3~Ca2Nb3010
3.92
3.36
180
5.00
4.31
50
After
the
calcination
was
thoroughly
burnt
was
diminished
by
octylammonium than was
that
to
to
the
silica
873
K and
the
collapsed
at
nm comparing sample When K,
respectively.
at the
K.
the
c-axis
of Thus,
all
the
samples
lengths
and
the
using and
after
the
measured of
the
that
volume
length
shows
the
although
atomic
temperature
surface
the
the
the of
in the
c-axis
the
alkylammonium The of
before
surface with
area the
This
increase
suggests
silica-pillared increse
length
of Si/Nb
ions.
and
BET
of the
increases.
were
Table 2 The composition of silica pillared-niobates
between
alkyl Table
2
determined 15 and
25 %
determined by EDX K
Si
Nb
Ca
GHl~dCm~dh
0.16
1.0
0.54
0.05
WdkdH3)Ca2~3010
0.22
1.0
0.70
0.07
(GsH37NJJ3)Ca2~3Olo
0.23
1.0
0.65
0.08
precursor
1
of
samples
silica-pillared-niobates
ratios
was
of alkyl-chain
77 K decreased
with
at
In Table areas
different
length for
indicates
to sinter
below.
of pillared-niobates.
decreases
composition The
at
of micropores
spaces
chane
EDX.
length
the
both
nm
completely
octadecilammmonium
However,
NZ adsorption
c-axis
the
with ions
calcination. by
interlayer
by
increased
1.36
were
This
was
BET
three
by
lengths
calcination
nm which
temperature
begins
pillar
described
prepared
ammonium
c-axis
interlayer
dodecil,
length
the
silica
ions,
intercalated
longer
973
pillared-niobates
c-axis
was
alkylammonium 2.93
of the
calcination
nm,
K for
octy1,
but
the
1.47
pillar
was
to that
K or
773
i.e.
length
or
structure 973
4 h, by which
c-axis
873
2.50
that
is shown
0.33
K for
the
intercalated
increased
at
773
of HCazNbaOlo.
decreased
fixed
at out,
484 which
increased X-ray
with
photoelectron
silica-pillared extent
of the
latter
sample.
observed that
but
of Ca
silica-
the
pillared
niobate
surface in the
aqueous
activity
In Table
methanol
intercalate
activity
water
solution at
the
are
very
the
low
for
was
of the
comparing
with
those
product
niobates
niobates and from
an
does
reaction
rate of Hz evolution / prnol*ti’ precursor
alone
Pt-loadedC)
KCazNbJ 010
14
100
HCazNb3 010
2200
8700
500
10800
-
9700
pillared-niobate
CsHlTNH3
pillared-niobate
C12H25NH3
pillared-niobate
C1sH3,NH3
not
occurs
Table 3 Comparison of rates of Hz evolution from an aqueous methanol solution a) catalystb)
of
niobate.
As KCazNb3010 the
for
segregation
of KCazNbs010
space,
for
preferentially
of Hz evolution
listed.
interlayer
to Nb
those
silica-pillared
rates
the was
of Ca and
silica-pillared
of
the
Si peak
same
silica
space
with
3, the
surface
no noticeable
but
of
the
niobate
was
and
to examine
intensities
that
interlayer
in comparison
HCazNbsOlo .
on
almost
occurred
photocatalytic
examined
were
indicates
Photocatalytic
were
intensity the
of HCazNb301o
measured
silica
Actually
This
The
of
signal
silica
on the
(XPS)
also
a silica-pillared
or Nb.
incorporated
were
segregation On
length.
spectra
niobate
HCatNb3Olo.
3.2
the c-axis
6600
a) CHsOH 50 ml + Hz0 300 ml, b) catalyst 1 g, Hg lamp (450 W) c) 0.1 wt%
485 only
at the
activity
external
of
HCanNb3Olo,
surface,
it.
When
the
activity
to
water.
is a typical
layered
lower any
that
silica
spaces. however,
the
to poison
activity,
Pt was
activity
to be a catalyst the
The
catalyst
is attached
When
for
by
onto
the
Hz evolution
between
is shown
in Table
HCazNb3010, when
methanol
than
two
As
are
rate
replaced
by ethanol
it was
in the
cases
sites interlayer
of
Pt
and
the
decreased
of magnitude
exhibit
is known
is considered
compared.
and
silica
rates For
lower
by
1-propanol
evolution ratesa) / pmol=h-’ HCazNbjO1ob’
pillared-niobate CSHI~NH~
MeOH
4670
8100
EtOH
384
5500
PrOH
43
1100
BuOH
30
1060
a) Pt 0.1 wt% loaded b) &-exchange degree > 95%
of Hz
drastically
Table 4 Dependence of Hz evolution rates from several alcohol solutions on KCazNb3Olo and silica pillared-niobate. alcohol
rather
sheet.
HCazNbsOlo
of HZ evolution
the
orders
alcohols
not
the
silica
4 where
from
pillared-catalyst,
on a niobate
difference
several
at
as
was
catalytic
sheets silica
site,
sites
A remarkable
from
does
the
completely.
pillared-niobate evolution
Pt-loading
silica
i.e.
of
as well
of HZ evolution
niobate
recovered
orders
rate without
low
ions,
ion-exchangeable
As
on
very H+
of
it blocks
loaded
HZ evolution
three
of methanol
of HCazNb3010.
photocatalytic
when
by
behavior
[4].
pillared-niobate than
the
replaced
intercalation
photocatalysts
silica
explains
were
increased
magni.t~tde due This
the
which
Ii+ ions
more and
l-
486 This
butanol. on
the
species
the
of
difficult other
although
these
for
of HZ
an aqueous
alcohol
silica
than
the
alcohols
for
attributed
to
the
pillaring.
silica
In summary, KCa2Nb3010
solution
effect spacing
which
30 times
longer the
with
comparing
was
attributed the
HZ
with to
of the
alkyl
pronounced rate
for
silica
increase
chains
should
spacing
for
rate
alkyl
longer
be to
Hz
even
chains
HCazNb3010. the
due
of
from
activity
evolution
intercalation
from
This
prepared
longer
On
chain.
less
higher
is
structural
evolution
interlayer
high
of alcohols
facilitated
the
photocatalytic
rather
extent
alkyl
HCazNb3010.
with of
HZ
activity
intercalation
is much
pillared-niobate
or butanol
of pillaring
for
a good
It showed
as propanol
was
that
silica
to the
the
longer
Actually
increase
exhibited
evolution. an aqueous
the
with
activity
solution
pillared-niobate
i.e.
pillared-niobate
remains.
butanol
activity
is attributed
evolution
it still
of photocatalytic
alcohols,
for the
hand,
dependence
dependence
of alcohols
intercalation more
strong
in such
This interlayer
of those
alcohols.
4. REFERENCES 1 2 3 4 5 6
A. Kudo, K. Sayama, A. Tanaka, K. Asakura, K. Domen, K. Maruya and T. Onishi, J. Catal., 120 (1989) 337. K. Sayama, A. Tanaka, K. Domen, K. Maruya and T. Onishi, J. Catal., 124 (1990) 541. K. Sayama, A. Tanaka, K. Domen, K.Maruya and T. Onishi, J. Phys. Chem., 95 (1991) 1345. K. Domen, J. Yoshimura, T. Sekine, A. Tanaka and T. Onishi, Catal. Lett., 4 (1990) 339. J. Yoshimura, Y. Ebina, A. Tanaka, J. Kondo and K. Domen, J. Phys. Chem., accepted for publication. M. E. Landis, B. A. Aufdembrink, P. Chu, I. D. Johnson, G. W. Kirker and M. K. Rubin, J. Am. Chem. Sot., 113 (1991) 3189.