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The conversion of 2-propanol over chrysotile
361
Applied Catalysis, 10 (1984) 361-368 Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
THE CONVERSION
Sadakatsu
SUZUKI and Yoshio
Department Tokyo
OF 2-PROPANOL
of Chemical
OVER CHRYSOTILE
ON0
Engineering,
Tokyo
Institute
of Technology,
Meguro-ku,
152, Japan.
(Received
3 January
1984, accepted
12 March
1984)
ABSTRACT Layered magnesium silicates with chrysotile structure were synthesized under hydrothermal conditions from the alkaline gels containing magnesium and silicon sources with varying ratio of Na20/Si02. The morphology and the thermal stability of the synthesized materials were characterized by electron microscopy, X-ray diffraction analysis, thermal analysis and surface area measurement. The conversion of 2-propanol (dehydration and dehydrogenation) was carried out over the materials in order to clarify the acid-base character of their surfaces, which were found to depend greatly on the Na20/Si02 ratio of the starting gel.
INTRODUCTION Chrysotile
Mg3(OH)4Si205
under hydrothermal and silicon
sources
from alkaline
active
Such applications
metal cations,
or part of the Mg(I1) Robson depended
like Ni(II),
that the physical
on the pH or on the Na20/Si02
2.5 and 2.0, and between
a change
is to examine
chrysotile reaction
centers,
Co(II) and Al(III),
in place of all
form of the synthesized
chrysotile
gel. Thus, thick wall
from gels with Na20/Si02
materials
in physical
properties
ratios between
while thin flakes were formed
and dehydrogenation
with changing
for 2-propanol
[4,53. Cracking
by
of isopropylbenzene
structure
was tested over
Na20/Si02
ratios. The
character
of the surfaces,
proceed
0 1984 Elsevier Science Publishers B.V.
crystal
conversion
for the acid-base of alcohols
is accompanied
The aim of the present work
from gels with varying
should give a good diagnosis
respectively
properties
activity
synthesized
form of a crystal
of the material.
in catalytic
Thus, catalytic
0166-9834/84/$03.00
by
could be obtained
1.5 and lower.
the change
since dehydration
for a
were reviewed
active materials
2.0 and 1.5, respectively,
that the change
in the surface
of chrysotile.
magnesium
with its high
or as a support
of the material
ratio of the starting
tubes and thin wall tubes were produced
It is expected
together
in the structure.
[3] reported
at ratios of about
and can be synthesized
or gel containing
structure
may be useful as a catalyst
species.
Swift [23. It is also known that catalytically by incorporating
silicate
solution
[I]. Because of its defined
surface area, chrysotile catalytically
is a layered magnesium
conditions
over acidic and basic was also examined.
362 EXPERIMENTAL The various
physical
the literature
[1,3]. Sodium metasilicate
mol) were dissolved magnesium
into water.
chloride
H20/Si02
forms of chrysotile
crystals
(0.15 mol) with stirring.
added.
was added an aqueous
Water was further
ratio to 65. The pH of the resulting
in an autoclave
(0 - 0.2
solution
of the
gel ranged from 7 to 13, depending
The resultant
mixture
and heated at 543 K for 24 h. After cooling,
determined
by the BET method.
thermal
analysis
was then placed
the insoluble
and dried at 383 K. The surface area of the produced Differential
to
added to adjust
was washed
were made with Shimadzu
according
(0.1 mol) and sodium hydroxide
To this solution
upon the amount of sodium hydroxide
were prepared
materials
product was
and thermogravimetry
TG-200, DT-POB and DTG-20 instruments, raising the temper-1 . Electron micrographs and X-ray diffraction patterns
ature at a rate of 5 K min were taken with JEOL-200cx The reactions was placed benzene)
and Phillips
were carried
PW/Oll instruments,
out in a continuous
in a reactor of silica tubing.
was delivered
by a motor-driven
The reactant syringe
respectively.
flow reactor.
The catalyst
(2-propanol
or isopropyl-
to be vaporized
in a preheating -1 (W/F) were 44 g h mol
zone of the reactor containing quartz. The contact times -1 and 78 g h mol for the reaction of 2-propanol and isopropylbenzene, Products
RESULTS
were analyzed
respectively.
by gas chromatography.
AND DISCUSSION
Physical
forms of chrysotile
Electron
micrographs
shape of the products starting tubular
(1 g)
of some of the products greatly
gel, in agreement crystals
with the description
100 - 300
the tubular
shape became obscure
ratio over 1.6 and below
chrysotile,
respectively,
The specific materials
in reference
amorphous.
from gels with Na20/Si02
[3]. At Na20/Si02
= 2,
As the Na20/Si02
ratio
l(b) and (c)). At a Na20/SiD2 The products
1.5 will be called
after the designation
1. The physical
(or the pH) of the
l(a). The outer and inner diameters
(Figures
surface area of the products
obtained
ratio
and 50 - 70 A, respectively.
ratio of 1.13, the product was apparently Na20/Si02
are shown in Figure
on the Na20/Si02
were formed as shown in Figure
of the tubes were decreased,
depended
tube-type
by Robson
paralleled
from gels with
and flake-type
[3].
morphology.
For the
ratio 1.0 - 1.1, the specific with
ratio.
area was about 130 m2 g-1.
For tube-type
chrysotile,
the specific
The values were in good agreement The change diffraction
in the structure
patterns
line became weaker
of the materials
respectively.
ratio increased,
The trend was particularly to diffraction
This indicates
ratios.
by X-ray every diffraction
significant
in the lines
from the (020) and the
that significant
in the piling of the layers at higher Na20/Si02
Na20/Si02
[3].
was also evidenced
(Figure 2). As the Na20/Si02
and broader.
at 2e = 12.1 and 24.4", which correspond (004) planes,
surface
with those in reference
increasing
surface
area was about 400 m ' g-I. The surface area decreased
irregularity
occurs
363
(a)
(b)
FIGURE
1
Electron
ratio of (a) 2.00,
micrographs
of chrysotiles
(b) 1.50 and (c) 1.38.
prepared
from gels with Na20/Si02
364
b
A
C
-
10
FIGURE 2
20
FIGURE 3
30 “29
X-ray diffraction
SiO2 ratio of (a) 2.00,
300
patterns
Thermogravimetric (a) tube-type
(b) flake-type
I
I
40 50 I degree
I
60
of chrysotile
70
prepared
from gels with Na,O/
(b) 1.75 and (c) 1.13
500 700 900 Temparature I K
chrysotile;
I
1
I
chrysotile
300
1100
analysis chrysotile prepared
500
900 700 Temparaturc I K
and differential prepared
thermal
1100
analysis
from gel with Na20/SiOp
from gel with Na20/Si02
of = 2.00,
= 1.13,
e
10 FIGURE 4
X-ray diffraction
temperatures; (d) calcined
20
30
pattern
(a) as prepared,
40 50 028 /degree of tube-type
(b) calcined
at 973 K, (e) calcined
60
70
chrysotile
calcined
at 773 K, (c) calcined
at 1073 K and (f) calcined
at various
at 873 K,
at 1173 K.
365 Thermal
stability
The results materials
of thermogravimetric
prepared
and thermal
from gels with Na20/Si02
differential
analyses
of the
ratio of 2.00 and 1.13 are shown
Figure
3. The tube-type
chrysotile
change
of the structure
occurs at 1050 K. In the case of the flake-type
dehydration
proceeds
calcination
temperature
pattern
was in conformity
was kept in an electric
As shown in Figure 4, calcination indicating
partial dehydration
disappearance
range indicating
of the tube-type with results
furnace
at 773 K decreased
of the crystal.
of all the diffraction calcined
of the thermal
the intensity
Calcination
indicative
lines,
over 973 K showed
of 2-propanol
ratios was carried
conversion
of 2-propanol
the conversion different.
out at 453
was obtained
With the flake-type product
samples.
flake-type
over samples
of new
to forsterite
materials
samples
cannot
above,
to a difference
than with the tube-type
Figure 6 shows the temperature
was observed
of both acidic
not mean thattherewere activity
by differences
in the surface
differs
between
in surface
structure
of the
of Z-propanol
[4,5]. Thus, the results
proceed shown in
samples. of 2-propanol
increased
conversion
with reaction
at all temperatures
over tube-
temperature.
studied,
confirming
The the
and basic sites.
The fact that dehydration
dehydrogenation
of the
sites exist on the surfcae of the flake-
dependence
The total conversion
area of the materials
and dehydrogenation
that much more acidic
of acetone
while for the
activity
the large difference
be explained
sites and basic sites, respectively
type chrysotile.
were also
exclusively
at 453 K shows that dehydration
It is known that dehydration
type samples
occurred
gel is low. Since the surface
area and should be ascribed
Figure 5 indicated
The products
is higher when the Na20/Si02
and flake-type
over acidic
samples.
dehydration
5, 100%
samples at 513 K. In contrast,
was formed with about 40% selectivity
at most by a factor of three, as described
materials.
from gels with different
and 513 K. As shown in Figure
for flake-type
samples,
(acetone)
The conversion
ratio of the starting
activity.
that the formation
prepared
was only 5 - 7% for the tube-type
the dehydration
presence
dehydration.
of 2-propanol
The conversion
formation
temperatures.
at 873 K led to
had taken place. Most of the new peaks were ascribed
tube-type
analyses.
of each line,
of complete
of materials
tube-type
with
for 12 h at designated
substance(s)
Na20/Si02
an inhomogeneous
chrysotile
The patterns
Conversion
chrysotile,
material.
in X-ray diffraction
The chrysotile
between 800 and 900 K and further
over a much wider temperature
nature of the flake-type The change
is dehydrated
in
no
exclusively
occurred
over flake-type
basic sites over flake-type
of the materials
To check this possibility,
samples,
could be masked
poisoning
materials,
might
since the
by high dehydration
of the acidic
sites by pyridine
366
s
. 60
Na20
FIGURE 5
Dependence
starting
of Z-propanol
gels; reaction
temperature
100
-
80
-
<60
1.5
I SiO2
conversion (0)
on the Na2O/SiO2
513 K and (A)
ratio of the
453 K.
-
9
e40
-
20
-
O-
500 600 700 Reaction Temparature I K
FIGURE 6
Dependence
of 2-propanol
tube-type
chrysotile
(0)
conversion
total conversion,
on the reaction
(0)
temperature
propene yield,
(A)
over
acetone
yield.
was attempted
as shown in Figure 7. The reaction
pure2-propanol.
100% conversion
After 2 h, pyridine
was added to the feed. The conversion
decreased
gradually,
expected.
At the same time, acetone
indicating
sites exist also on the surface absence
was started
of dehydrogenation
at 633 K by feeding
to propene and to diisopropylether
to dehydration
that acidic sites contribute started
to be formed.
of the flake-type
activity
products
to dehydration,
as
This implies that basic
materials,
is due to its masking
was observed.
and the apparent
by the very high activity
for dehydration.
Cracking
of isopropylbenzene
The activities
of various
chrysotile
materials
for isopropylbenzene
cracking
367
stream h5
3
Time on
FIGURE 7
Effect of pyridine
over flake-type
addition
I
on the conversion
chrysotile.
Experimental
under reaction
conditions
to propene
and acetone
data is in the text. Reaction
temperature
633 K.
were examined
since the reaction conversions obtained
of isopropylbenzene
cracking
did not proceed
from gels with Na20/Si02 conformity Bronsted
over Brdnsted
acid sites. The initial
were 23, 18 and 11% for the flake-type
from the gels with Na20/Si02
In contrast,
of W/F = 78 g mol h -I, 573 K, 101 kPa,
was known to proceed
ratio of 1.06, 1.13 and 1.38, respectively. over any of the tube-type
materials
ratio of 1.63, 1.30 and 2.00. These results
with the results
materials
of dehydration
of Z-propanol.
acid sites exist only on the flake-type
obtained
are in good
It is concluded
that
chrysotile.
Origin of acidic and basic sites It is clear that the surface acidic
of chrysotile
sites, but has a basic character.
of chrysotile the surface character
has no Brdnsted
should resemble
acidity
anions
It is expected
structure
those of silica or magnesium from a partially
have a nucleophilic
tendency
similar
has few.
that the ideal crystal
since all the OH groups
of the surface may originate
where oxygen
with tubular
(SiOH and MgOH) on
hydroxide.
The basic
dehydroxylated
MgOH layer,
to those on magnesium
oxide. The high acidity chrysotile
and basic character on the details amorphous cation similar
of flake-type
structure.
materials
[61, although
of the preparation
the extent method.
mixed oxides was considered
in an oxide structure structures
(flake-type).
could come from incompleteness
It is known that amorphous
depends
of the
has both acidic
on the ratio of MgO/SiO*
The origin
to be related
of another
could be formed
silica-magnesia
of the acidity to incorporation
metal cation
in the ill-defined
of the of a metal
[7]. It is conceivable structure
and
that
of chrysotile
368 REFERENCES 1 2 3 4 5 6 7
W. Nell, H. Hirscher and W. Syberts, Kolloid Z., 157 (1958) 1. H.E. Swift, in "Advanced materials in Catalysis", J.J. Burton and R.L. Garten, Eds., Academic Press, New York and London, (1977) 230. H.E. Robson, US Patent 3,804,701; 3,852,165. G.V. Krylov, in "Catalysis by Nonmetals", Academic Press, New York (1970) 116. T. Yashima, H. Suzuki and N. Hara, J. Catal., 33 (1974) 486. H. Niiyama and E. Echigoya, Bull. Chem. Sot. Japan, 45 (1972) 938. K. Tanabe, T. Sumiyoshi, K. Shibata, T. Kiyoura and J. Kitagasa, Bull. Chem. Sot. Japan, 47 (1974) 1064.
Applied Catalysis, 10 (1984) 361-368 Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
THE CONVERSION
Sadakatsu
SUZUKI and Yoshio
Department Tokyo
OF 2-PROPANOL
of Chemical
OVER CHRYSOTILE
ON0
Engineering,
Tokyo
Institute
of Technology,
Meguro-ku,
152, Japan.
(Received
3 January
1984, accepted
12 March
1984)
ABSTRACT Layered magnesium silicates with chrysotile structure were synthesized under hydrothermal conditions from the alkaline gels containing magnesium and silicon sources with varying ratio of Na20/Si02. The morphology and the thermal stability of the synthesized materials were characterized by electron microscopy, X-ray diffraction analysis, thermal analysis and surface area measurement. The conversion of 2-propanol (dehydration and dehydrogenation) was carried out over the materials in order to clarify the acid-base character of their surfaces, which were found to depend greatly on the Na20/Si02 ratio of the starting gel.
INTRODUCTION Chrysotile
Mg3(OH)4Si205
under hydrothermal and silicon
sources
from alkaline
active
Such applications
metal cations,
or part of the Mg(I1) Robson depended
like Ni(II),
that the physical
on the pH or on the Na20/Si02
2.5 and 2.0, and between
a change
is to examine
chrysotile reaction
centers,
Co(II) and Al(III),
in place of all
form of the synthesized
chrysotile
gel. Thus, thick wall
from gels with Na20/Si02
materials
in physical
properties
ratios between
while thin flakes were formed
and dehydrogenation
with changing
for 2-propanol
[4,53. Cracking
by
of isopropylbenzene
structure
was tested over
Na20/Si02
ratios. The
character
of the surfaces,
proceed
0 1984 Elsevier Science Publishers B.V.
crystal
conversion
for the acid-base of alcohols
is accompanied
The aim of the present work
from gels with varying
should give a good diagnosis
respectively
properties
activity
synthesized
form of a crystal
of the material.
in catalytic
Thus, catalytic
0166-9834/84/$03.00
by
could be obtained
1.5 and lower.
the change
since dehydration
for a
were reviewed
active materials
2.0 and 1.5, respectively,
that the change
in the surface
of chrysotile.
magnesium
with its high
or as a support
of the material
ratio of the starting
tubes and thin wall tubes were produced
It is expected
together
in the structure.
[3] reported
at ratios of about
and can be synthesized
or gel containing
structure
may be useful as a catalyst
species.
Swift [23. It is also known that catalytically by incorporating
silicate
solution
[I]. Because of its defined
surface area, chrysotile catalytically
is a layered magnesium
conditions
over acidic and basic was also examined.
362 EXPERIMENTAL The various
physical
the literature
[1,3]. Sodium metasilicate
mol) were dissolved magnesium
into water.
chloride
H20/Si02
forms of chrysotile
crystals
(0.15 mol) with stirring.
added.
was added an aqueous
Water was further
ratio to 65. The pH of the resulting
in an autoclave
(0 - 0.2
solution
of the
gel ranged from 7 to 13, depending
The resultant
mixture
and heated at 543 K for 24 h. After cooling,
determined
by the BET method.
thermal
analysis
was then placed
the insoluble
and dried at 383 K. The surface area of the produced Differential
to
added to adjust
was washed
were made with Shimadzu
according
(0.1 mol) and sodium hydroxide
To this solution
upon the amount of sodium hydroxide
were prepared
materials
product was
and thermogravimetry
TG-200, DT-POB and DTG-20 instruments, raising the temper-1 . Electron micrographs and X-ray diffraction patterns
ature at a rate of 5 K min were taken with JEOL-200cx The reactions was placed benzene)
and Phillips
were carried
PW/Oll instruments,
out in a continuous
in a reactor of silica tubing.
was delivered
by a motor-driven
The reactant syringe
respectively.
flow reactor.
The catalyst
(2-propanol
or isopropyl-
to be vaporized
in a preheating -1 (W/F) were 44 g h mol
zone of the reactor containing quartz. The contact times -1 and 78 g h mol for the reaction of 2-propanol and isopropylbenzene, Products
RESULTS
were analyzed
respectively.
by gas chromatography.
AND DISCUSSION
Physical
forms of chrysotile
Electron
micrographs
shape of the products starting tubular
(1 g)
of some of the products greatly
gel, in agreement crystals
with the description
100 - 300
the tubular
shape became obscure
ratio over 1.6 and below
chrysotile,
respectively,
The specific materials
in reference
amorphous.
from gels with Na20/Si02
[3]. At Na20/Si02
= 2,
As the Na20/Si02
ratio
l(b) and (c)). At a Na20/SiD2 The products
1.5 will be called
after the designation
1. The physical
(or the pH) of the
l(a). The outer and inner diameters
(Figures
surface area of the products
obtained
ratio
and 50 - 70 A, respectively.
ratio of 1.13, the product was apparently Na20/Si02
are shown in Figure
on the Na20/Si02
were formed as shown in Figure
of the tubes were decreased,
depended
tube-type
by Robson
paralleled
from gels with
and flake-type
[3].
morphology.
For the
ratio 1.0 - 1.1, the specific with
ratio.
area was about 130 m2 g-1.
For tube-type
chrysotile,
the specific
The values were in good agreement The change diffraction
in the structure
patterns
line became weaker
of the materials
respectively.
ratio increased,
The trend was particularly to diffraction
This indicates
ratios.
by X-ray every diffraction
significant
in the lines
from the (020) and the
that significant
in the piling of the layers at higher Na20/Si02
Na20/Si02
[3].
was also evidenced
(Figure 2). As the Na20/Si02
and broader.
at 2e = 12.1 and 24.4", which correspond (004) planes,
surface
with those in reference
increasing
surface
area was about 400 m ' g-I. The surface area decreased
irregularity
occurs
363
(a)
(b)
FIGURE
1
Electron
ratio of (a) 2.00,
micrographs
of chrysotiles
(b) 1.50 and (c) 1.38.
prepared
from gels with Na20/Si02
364
b
A
C
-
10
FIGURE 2
20
FIGURE 3
30 “29
X-ray diffraction
SiO2 ratio of (a) 2.00,
300
patterns
Thermogravimetric (a) tube-type
(b) flake-type
I
I
40 50 I degree
I
60
of chrysotile
70
prepared
from gels with Na,O/
(b) 1.75 and (c) 1.13
500 700 900 Temparature I K
chrysotile;
I
1
I
chrysotile
300
1100
analysis chrysotile prepared
500
900 700 Temparaturc I K
and differential prepared
thermal
1100
analysis
from gel with Na20/SiOp
from gel with Na20/Si02
of = 2.00,
= 1.13,
e
10 FIGURE 4
X-ray diffraction
temperatures; (d) calcined
20
30
pattern
(a) as prepared,
40 50 028 /degree of tube-type
(b) calcined
at 973 K, (e) calcined
60
70
chrysotile
calcined
at 773 K, (c) calcined
at 1073 K and (f) calcined
at various
at 873 K,
at 1173 K.
365 Thermal
stability
The results materials
of thermogravimetric
prepared
and thermal
from gels with Na20/Si02
differential
analyses
of the
ratio of 2.00 and 1.13 are shown
Figure
3. The tube-type
chrysotile
change
of the structure
occurs at 1050 K. In the case of the flake-type
dehydration
proceeds
calcination
temperature
pattern
was in conformity
was kept in an electric
As shown in Figure 4, calcination indicating
partial dehydration
disappearance
range indicating
of the tube-type with results
furnace
at 773 K decreased
of the crystal.
of all the diffraction calcined
of the thermal
the intensity
Calcination
indicative
lines,
over 973 K showed
of 2-propanol
ratios was carried
conversion
of 2-propanol
the conversion different.
out at 453
was obtained
With the flake-type product
samples.
flake-type
over samples
of new
to forsterite
materials
samples
cannot
above,
to a difference
than with the tube-type
Figure 6 shows the temperature
was observed
of both acidic
not mean thattherewere activity
by differences
in the surface
differs
between
in surface
structure
of the
of Z-propanol
[4,5]. Thus, the results
proceed shown in
samples. of 2-propanol
increased
conversion
with reaction
at all temperatures
over tube-
temperature.
studied,
confirming
The the
and basic sites.
The fact that dehydration
dehydrogenation
of the
sites exist on the surfcae of the flake-
dependence
The total conversion
area of the materials
and dehydrogenation
that much more acidic
of acetone
while for the
activity
the large difference
be explained
sites and basic sites, respectively
type chrysotile.
were also
exclusively
at 453 K shows that dehydration
It is known that dehydration
type samples
occurred
gel is low. Since the surface
area and should be ascribed
Figure 5 indicated
The products
is higher when the Na20/Si02
and flake-type
over acidic
samples.
dehydration
5, 100%
samples at 513 K. In contrast,
was formed with about 40% selectivity
at most by a factor of three, as described
materials.
from gels with different
and 513 K. As shown in Figure
for flake-type
samples,
(acetone)
The conversion
ratio of the starting
activity.
that the formation
prepared
was only 5 - 7% for the tube-type
the dehydration
presence
dehydration.
of 2-propanol
The conversion
formation
temperatures.
at 873 K led to
had taken place. Most of the new peaks were ascribed
tube-type
analyses.
of each line,
of complete
of materials
tube-type
with
for 12 h at designated
substance(s)
Na20/Si02
an inhomogeneous
chrysotile
The patterns
Conversion
chrysotile,
material.
in X-ray diffraction
The chrysotile
between 800 and 900 K and further
over a much wider temperature
nature of the flake-type The change
is dehydrated
in
no
exclusively
occurred
over flake-type
basic sites over flake-type
of the materials
To check this possibility,
samples,
could be masked
poisoning
materials,
might
since the
by high dehydration
of the acidic
sites by pyridine
366
s
. 60
Na20
FIGURE 5
Dependence
starting
of Z-propanol
gels; reaction
temperature
100
-
80
-
<60
1.5
I SiO2
conversion (0)
on the Na2O/SiO2
513 K and (A)
ratio of the
453 K.
-
9
e40
-
20
-
O-
500 600 700 Reaction Temparature I K
FIGURE 6
Dependence
of 2-propanol
tube-type
chrysotile
(0)
conversion
total conversion,
on the reaction
(0)
temperature
propene yield,
(A)
over
acetone
yield.
was attempted
as shown in Figure 7. The reaction
pure2-propanol.
100% conversion
After 2 h, pyridine
was added to the feed. The conversion
decreased
gradually,
expected.
At the same time, acetone
indicating
sites exist also on the surface absence
was started
of dehydrogenation
at 633 K by feeding
to propene and to diisopropylether
to dehydration
that acidic sites contribute started
to be formed.
of the flake-type
activity
products
to dehydration,
as
This implies that basic
materials,
is due to its masking
was observed.
and the apparent
by the very high activity
for dehydration.
Cracking
of isopropylbenzene
The activities
of various
chrysotile
materials
for isopropylbenzene
cracking
367
stream h5
3
Time on
FIGURE 7
Effect of pyridine
over flake-type
addition
I
on the conversion
chrysotile.
Experimental
under reaction
conditions
to propene
and acetone
data is in the text. Reaction
temperature
633 K.
were examined
since the reaction conversions obtained
of isopropylbenzene
cracking
did not proceed
from gels with Na20/Si02 conformity Bronsted
over Brdnsted
acid sites. The initial
were 23, 18 and 11% for the flake-type
from the gels with Na20/Si02
In contrast,
of W/F = 78 g mol h -I, 573 K, 101 kPa,
was known to proceed
ratio of 1.06, 1.13 and 1.38, respectively. over any of the tube-type
materials
ratio of 1.63, 1.30 and 2.00. These results
with the results
materials
of dehydration
of Z-propanol.
acid sites exist only on the flake-type
obtained
are in good
It is concluded
that
chrysotile.
Origin of acidic and basic sites It is clear that the surface acidic
of chrysotile
sites, but has a basic character.
of chrysotile the surface character
has no Brdnsted
should resemble
acidity
anions
It is expected
structure
those of silica or magnesium from a partially
have a nucleophilic
tendency
similar
has few.
that the ideal crystal
since all the OH groups
of the surface may originate
where oxygen
with tubular
(SiOH and MgOH) on
hydroxide.
The basic
dehydroxylated
MgOH layer,
to those on magnesium
oxide. The high acidity chrysotile
and basic character on the details amorphous cation similar
of flake-type
structure.
materials
[61, although
of the preparation
the extent method.
mixed oxides was considered
in an oxide structure structures
(flake-type).
could come from incompleteness
It is known that amorphous
depends
of the
has both acidic
on the ratio of MgO/SiO*
The origin
to be related
of another
could be formed
silica-magnesia
of the acidity to incorporation
metal cation
in the ill-defined
of the of a metal
[7]. It is conceivable structure
and
that
of chrysotile
368 REFERENCES 1 2 3 4 5 6 7
W. Nell, H. Hirscher and W. Syberts, Kolloid Z., 157 (1958) 1. H.E. Swift, in "Advanced materials in Catalysis", J.J. Burton and R.L. Garten, Eds., Academic Press, New York and London, (1977) 230. H.E. Robson, US Patent 3,804,701; 3,852,165. G.V. Krylov, in "Catalysis by Nonmetals", Academic Press, New York (1970) 116. T. Yashima, H. Suzuki and N. Hara, J. Catal., 33 (1974) 486. H. Niiyama and E. Echigoya, Bull. Chem. Sot. Japan, 45 (1972) 938. K. Tanabe, T. Sumiyoshi, K. Shibata, T. Kiyoura and J. Kitagasa, Bull. Chem. Sot. Japan, 47 (1974) 1064.