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Effect of adsorbents coated with titanium dioxide on the photocatalytic degradation of propoxur
Chtmqhere, Vol. 38, No. 3, pp. 617-627, 1999 Q 1998 Elsevier Science Ltd. All rights reserved W5-6535/99/ $ - see front matter
Pergamon
PII: SO0456535(98)00204-S
EFFECT OF ADSORBENTS COATED WITH TITANIUM DIOXIDE ON THE PHOTOCATALYTIC DEGRADATION OF PROPOXUR Ming-Chun
Lu ‘,
Jong-Nan
Cheu*, and Kuo-Tai Chang3
1. Department of Environmental Engineering and Heulth Chia Nan College of Pharmacy and Science Tainan, Taiwan 71710, ROC 2. Institute of Environmental Engineering National Chiao Tung University Hsinchu, Taiwan 30039, ROC (Received in Germany 13 February 1998; accepted 15 May 1998)
ABSTRACT Photocatalytic
oxidation
of pesticides
in aqueous media irradiated
of research.
Therefore,
the treatment
technology
titanium dioxide coated on the supports was performed oxidizing
in this research.
propoxur
for degradation
such as activated
Results
show
because of its adsorption
agent.
than that with Ti02IGAC complexing can improve the photocatalytic
is the best complexing
The others follow the sequence: rate of propoxur
But the mineralization
01998
using
with plain TiOz
agent
for
plain TiOz > is higher than
rate of propoxur with plain TiOz is lower
it can be concluded
Elsevier
(an insecticide)
carbon, zeolite, brick, quartz and glass beads.
properities.
agent. However,
efficiency
of propoxur
that GACiTiOl
glass beads > zeolite > brick > quartz. The degradation that with TiOz/GAC complexing
by UV light is a rapidly growing field
Science Ltd.
that using GAC as the support
All rights reserved
KEY WORDS
Photocatalytic
oxidation;
supported titanium dioxide; propoxur;
insecticide
INTRODUCTION
Most pesticides
are non-selective;
addition to applying pesticides, considered. pesticides.
Photocatalytic Studies
have
they are also harmful
the pollution
oxidation shown
that
prevention
is a promising illumination
to ecological of pesticides
technology
of semiconductor 617
systems
as well. Therefore.
used in our environment in treating powders
wastewater in aqueous
in
has to be containing solutions
618 containing
organic compounds
TiOz catalyzed
and oxygen induces oxidative
the oxidation
of organic pollutants
equal to or greater than the band-gap
energy
electronic
solution
processes,
reactor
design,
decomposition
in the presence
of UV radiation
The quantum efficiency composition,
[I-S].
of organic compounds
at photon energies
of the process
the organic
substrate.
is influenced
light intensity
by and
surface interactions.
In the last few years, much attention has been devoted to the heterogeneous fixed-bed
reactors
reaction
is initiated
adsorbability efficiency
[3,6,7].
It is agreed that the critical
with hydroxyl
of the pollutants
Matthews
on suitable
[8] suggested
reaction.
adsorbents
inner
surface
to concentrate
agent in dilute aqueous
of a glass
tube.
behavior,
reaction [3-51. However,
indicating
zeolite,
brick.
of pesticides
reaction. Propoxur,
an insecticide,
the
factor in evaluating
the
efficiency,
photocatalyst
(Germany). San-Yu
with TiOz coated on the
of pesticides
follows
may play an important
(Millipore)
the Langmuir-
role in the oxidation
the reaction occurs, at the surface or in the bulk, the
glass
with titanium beads
dioxide
expression
[ 1 I].
Therefore.
coated on supports.
to investigate
the
characteristics
such as of the
was used as a test chemical.
AND METHODS
P25, 50 m*/g, 30 nm mean particle
The supports,
Company
surface.
with TiOl / activated
a herbicide,
Propoxur was obtained from Bayer Company with purity of 96.3%. The photocatalyst, study was Degussa
it may load
scaling up of the process.
was investigated
oxidation
process and
[l-3].
in the
Therefore,
on the
form as the Langmuir-Hinshelwood
quartz
oxidized
with
property of TiOl.
it was noted that wherever
is to study the photocatalytic
MATERIAL
pollutants
oxidation
Kato et al.. [IO] also used the porous alumina
that adsorption
this research
photocatalytic
surface
is an important
of propyzamine.
The photocatalytic
have the same analytical
carbon,
compounds
the decomposition the
solution.
oxidation
rate reactions
activated
surface
the photomineralization
studies, photocatalytic
Hinshelwood-type
on the photocatalyst
To promote
ceramic as the supporter to study the photocatalytic
In our previous
step of organic
that the use of TiOz coated on sand permits economic
Uchida et al., [9] demonstrated carbon complexing
produced
onto the photocatalyst
of the photocatalytic
photocatalyst
radicals
photocatalytic
Ti02 , used in this
from the Degussa
Company
activated carbon, zeolite. brick. quartz and glass beads. were obtained from the
(Taiwan).
and has a resistivity
without further purification.
size obtained
The water used for experiments greater than 18 MO/cm.
was purified
All other chemicals
by a Milli-Q/R0
system
used are of reagent grade
619 The supports were coated with TiOz by preparing minutes),
adding supports
to the sonicated
a TiOz suspension
suspension
in 100 ml water (sonicated
and evaporating
The amounts of TiOz and supports added in this procedure
depended
to dryness in an oven at 100 “c’.
on the experimental
coated supports were then heated at 550 “C for half an hour to produce the complexing
The photocatalytic
reactor is shown in Fig. 1. The reaction
was conducted
vessel with a quartz cover: the volume of reaction mixture was I liter. shorter wavelength
of IJV light.
The cut-off wavelengths
w low pressure
mercury lamps with a major emission
conditions.
The
agents.
in a i.2-liter
double-jacked
Quartz cover was required for the
for quartz are less than 200 nm.
254 nm light can pass through the cover to excite the TiOz.
for a few
The UV radiator was composed
Therefore. by three 10
at 254 nm (Sankyo Ltd., Japan) and was located
above the reactor.
?
0.
-
i
agnetic Stirrer
k+M Gas
Flow Meter
Fig. I, Photocatalytic
For all experimental
runs performed
During experiments,
the reactant solution
reactor used in this study
in this study. the pH of the reacting mixture was ad.justed initially. was agitated continuously
with a magnetic
stirrer and oxygen
(99.9 % purity) was bubbled into the solutions at a constant flow of 50 mlimin to insure oxygen saturation. The samples
were taken from the solution
HPLC (Waters LC module
1). total organic carbon (TOC) was detected
Model 2001), and surface area was determined
Potassium
ferrioxalate
with certain time intervals.
solution
Propoxur
was analyzed
with a
with a TOC analyzer (ASTKO
with a ASAP 2000 BET analyzer.
was used to measure the photon flux in the reactor. The quantum yield
(QY) can be defined as the ratio of the number of molecules on reaction with TiOl - free actinometry
solutions
quantum yield for ferrous ion formation
in the ferrioxalate
reacting to that the photons supplied.
Based
for the reactor. the flux rate was 7.2 ‘* I OeJ Mimin if the solution
is taken
to be 1.28
1121.
620
RESULTS
Photocatalytic
Choosing
AND DISCUSSION
degradation
of propoxur with different complexing
a proper support with a better ability of adsorption
since the support can concentrate g TiOz coated were immersed was also dispersed
organic chemicals
agents
can improve the photocatalytic
on its surface.
Since 3g complexing
in aqueous solutions to start the photocatalytic
efficiency
agent with 0.15
reaction, 0.15 g plain TiOz
in the reaction solution.
Table 1.
Surface areas of coated and uncoated supports
Support and Complexing
agent*
Surface Area (m*/g)
Plain TiOz
50
GAC
902
Coated GAC
745
Quartz
4.90
Coated Quartz
4.57
Zeolite
8.90
Coated Zeolite
4.95
Glass Beads
5.70
Coated Glass Beads
2.95
*: 1 g support was coated with 0.05g of Ti02
Table 1 lists the surface areas of supports coated and uncoated Ti02. The coating process eliminated surface areas of complexing supports. comparing
As shown
agent. The extent of surface area reduction depended
in Fig.2,
GAC/
TiO2 is the best complexing
the surface areas among the complexing
factor affecting on the propoxur
except
disappearance
GAC,
in this reaction
coated
with TiOa
did not improve
system. The reason is that the illumination
to find the proper support
for improving
surface area of GAC induces not only propoxur
By
agent of glass beads has a low surface area, but
the efficiency
agents except GAC/ Ti02. the efficiency
of propoxur
area was reduced when TiOl
was coated on the support surface and the supports can not adsorb propoxur this study is
removal.
of
agents, it is obvious that surface area is not the only
removal. The complexing
the supports
on the characteristics
agent for propoxur
the propoxur removal with glass/ Ti02 is high than that with other complexing Clearly,
the
efficiently.
of propoxur
but also TiOl adsorbs on GAC.
However,
removal.
In fact. TiOl
since
The large is a fine
621 particle that can disperse efficiency
of quantum
mentioned
above,
experiments,
in the bulk solution,
yield because
the GAC
but if coated on the supporter
of surface area reduction.
is still worthy
investigating
surface, will result in a low
Based on the the experimental
in more
details.
Thus.
resulted
in the following
GAC was chosen as the medium.
0.8
0.6 t
Fig.2
Propoxur removal after 60 min illumination Experimental complexing
conditions:
with different-wmplexing
[propoxur]=4.78x10‘4
agents
M: pHo=4;
agent, 3g
Effect of support diameter
To evaluate the effect of support size on propoxur study. diameters
oxidized,
Fig. 3 shows the time course of propoxur of GAC/ TiOz
disappearance. GACI TiOl
complexing
However,
agents.
The smaller
of GAC were used in this
in the photocatalytic
reaction
GACi TiOl diameter.
over various
the faster propoxur
it is difficult to separate the amount of propoxur adsorbed and oxidized on the
surface because the disappearance
the same time.
removal
several diameters
Therefore,
we compared
of propoxur
is attributed
the propoxur remainings
to oxidation
in the GAC/ TiOl
and adsorption
solutions with and Table 2
without UV illumination
to find the effect of GAC diameter on the disappearance
of propoxur.
indicates
of GAC diameter
with and without
the influence
illumination.
on the disappearance
of propoxur
in
UV
622 In general, the rate of propoxur UV illumination oxidation TiOz
because
disappearance
with UV illumination
GAC is an excellent
adsorbent
rate. Thus, UV light can not make a significant
solutions.
However,
according
is slightly higher than that without
resulting
in a higher
effect on the propoxur
to Table 2, it is proved that oxidation
adsorption removal
in the GACi
reaction really happened
its rate was much lower than that of adsorption.
-0-l
0-2Omesh
Effect of GAC diameter on the photocatalytic
oxidation
0.6 -
Time (mitt)
Fig.3
Experimental complexing
Table 2
Effect of
conditions:
[propoxur]=4.78x10-4
of propoxur
M; pHa=4;
agent, 3g
GAC diameter on the adosrption
and oxidation of propoxur*
Propoxur remaining(%)
Diameter
mesh
mm
70-40
0.21-0.42
2.5
1.2
40-25
0.42-0.707
8.6
8.1
25-20
0.707-0.841
11.5
8.3
20-10
0.841-2
31
20
>lO
>2
39.9
40
*Propoxur
remainings
without illumination
are compared at 15 min of reaction time.
rate than
with illumination
, and
623 Effect of Ti02 loading
TiOz loading is another important rate increases
with increasing
blocked by catalyst itself.
factor for propoxur
the TiOz loading
However,
In this experiment,
oxidation
of propoxur.
induces the increase of oxidation
rate.
the rate will be reduced because UV light is
four kinds of TiOJGAC
0.2g and 0.25g TiO2 were coated on lg GAC, separately. the photocatalytic
With plain TiOz , the photocatalytic
oxidation.
Increasing
Fig.4 indicates the effect of TiOs loading on
the amount of TiOz coated on the GAC surface
However, the results shows that the oxidation
0.2 g TiO2 can almost perform as well as that with 0.25 g TiO2 the reason that
the illumination
010
and adsorption
As GAC is an excellent the adsorption complexing
020
oxidation
[propoxur]=4.78x10‘4
agent, lg; illumination
of propoxur
M; pHa=4;
time, 5 hr
of propoxur on the TiOzIGAC surface
adsorbent,
and oxidation
conditions:
0 25
loading (g)
Effect of TiOz loading on the photocatalytic Experimental
Oxidation
The present instance is assumed to be
06
Ti02
complexing
rate with 0.15 and
area do not increase due to a higher catalyst concentration.
0 05
Fig. 4
were prepared; O.OSg, 0. I g, 0.15g.
therefore,
the disappearance
reaction; propoxur
agent surface and then
oxidized.
and its oxidation According
of propoxur
in the solution resulted from
intermediates
were concentrated
on the
to this characteristics
of the complexing
agent,
624 it was found that the disappearance adsorption.
In this experiment.
and then we hardly distinguished For this reason, the adsorption
Fig.5 shows the propoxur
of propoxur
the oxidation
rate on the complexing
of propoxur on the complexing
remaining
complexing
experiment
during the adsorption
than that of oxidation. process.
described
agent for three hours.
phase is attributed to oxidation
phase was mainly
attributed
to
agent surface can not be measured
the amount of propoxur oxidized and adsorbed in the combined reaction.
propoxur adsorbed on the surface of complexing photodegradation
from the aqueous
agent surface was furthur studied.
reaction.
It was found that the amount
agent reached a saturation
after 3 hours.
below were carried out with a preadsorption
It is assumed that the disappearance
with a preadsorption
The reduced amount of propoxur
of propoxur
of propoxur
oxidation
of propoxur
from the aqueous phase is assumed
the
on the
from the aqueous
process because the rate of adsorption
Fig.5 also shows the photocatalytic
Therefore,
of
is much higher
with a preadsorption
to be resulted from the
oxidation reaction.
m
Fig.5 Adsorption Experimental complexing
Comparison
of photocatalytic
To compare the catalytic GAC and dispersing
an Tme(min) and photocatalytic conditions:
oxidation
M; pHo=4;
agent, 1g
reactions onto the surfaces of plain Ti02 and Ti02/GAC
activity of plain TiOz and TiO$GAC.
directly
of propoxur
[propoxur]=8,6xlO‘”
in the solution,
respectively.
0.25 g ‘Ii01 was used for coating on lg
In the TiOziGAC
system,
1 g complexing
625 agent was immersed
in a solution containing
for saturating the complexing photocatalytic
reaction.
The initial concentration
the initial propoxur
oxidation
followed a first-order
solution
of propoxur
was 4.78X lOAM.
In the plain TiOz
was also 4.78X 10e4M. In these two reaction
systems,
propoxur
kinetic behavior. Table 3 lists the kinetic data of propoxur oxidation.
oxidation rate of propoxur with plain TiOz But the mineralization
reaction
agent surface. After three hours, the UV light was turned on to initiate the
solution.
complexing
9.56X 10e4M propoxur to proceed the preadsorption
rate of propoxur
is slightly higher than that with TiOz /GAC compiexing with plain TiOz is somewhat
The agent.
lower than that with TiO$GAC
agent.
Table 3
Rate constants of propoxur oxidation
Catalyst
Rate constant( 1Ihr) Mineralization
Oxidation
TiOziGAC
0.024
0.096
TiOz
0.018
0.102
Without preadsorption
process,
higher than that containing
propoxur
removal
rate in the solution
plain the TiO2 because
containing
GAC is an excellent
TiOz/GAC
adsorbent
was much
that can adsorb
propoxur on its surface in a short period of time. From the HPLC analysis, there were less intermediates found in the TiOIlGAC
system.
It is assumed
adsorbed onto the surface of complexing the reaction remained
the concentration
propoxur
of intermediates
intermediates conclusion,
are oxidized the complexing
as the target substrate
In the plain TiO2 system. the intermediates
agent.
of solution-phase
of a dilute concentration
dissolution
intermediates.
radicals
occurs
very fast as compared
to the suspended
into solution
produced
in
TiO2 surfaces.
of collection
phase onto the complexing
on the GAC can not ultilize
propoxur
and intermediates
and dissolved
propoxur
and
when they collide with TiOz
of degradation agent. as TiO2
all the photons
because
of dissolved
The use of plain ‘TiOz allows the
due to low the adsorbability,
agent has a large capability
and
of the adsorbed
with the collision
further to give a variety of other intermediates
from the solution
TiOl supported for degrading
were
of propyzamide
In this study. the supply
reactor with plain TiO2 can be almost absorbed by the photocatalyst reactor.
in this system
supports can ehhance the rate of mineralization
to the GAC/ TiOz interface
propoxur
formed
in the aqueous phase that can be detected by TOC analysis. Trimoto et d.[ 121 have
also reported that the use of adsorbent reduce
that the intermediates
intermediates
The photons dispersed
entering
TiOr is concentrated
as well
entering
completely
In
the
in the
the reactor to produce on the surface of 1 g
626 GAC
However.
the oxidation
efficiency
with GAC/ TiOz is almost as that with plain Ti02 even the
GACi TiO2 system utlized less amount of photons. support can improve the photocatalytic
efficiency
Therefore,
it can be concluded
that using GAC as the
and it is necessary to optimum light utlization
for GAC/
TiO2 system.
CONCLUSIONS
The rates of photocatalytic supports.
TiOzlGAC
oxidation
of propoxur
is the best complexing
properties.
The others follow the sequence:
degradation
rate of propoxur
However,
the mineralization
complexing associated
agent.
agent for oxidizing
rate of propoxur coated
on the blunt
with plain TiO2
Therefore,
because
of its adsorption
supports
eliminates
the problem
of the decomposition
efficiency
design
to permit
optimum
of filtration The use of
for the pollutants.
in TiO2 /GAC system is due to the small illumination
the reactor
agent.
TiO2 is lower than that with TiOz/GAC
but the reaction rate is mass transfer limited.
TiO2 coated on the GAC permits the promotion efficiency
propoxur
of TiO2 coated
is higher than that with TiO2 /GAC complexing with suspended
with the use of catalyst suspensions
chief loss of quantum
in the presence
aked Ti02 > glass beads > zeolite > brick > quartz. The
with plain TiOz
The catalyst
have been determined
light adsorbed
The
area comparing by TiO2 /GAC is
necessary.
ACKNOWLEDGMENT
This research was supported
by the National Science Council, Republic of China (Grant NSC 85-221 I-E-
009-015)
REFERENCES
1, A.
L.
Pruden
trichloroethylene 2. E. M. Pelizzetti, degradation
and
D.
F.
Ollis,
Photoassisted
in water, J. Cutal. 82,404-417 M. C. Minero,
catalysis:
the
degradation
(1983).
C. V. Pramauro,
of atrazine and other s-triazine
heterogeneous
herbicide,
P. E. Zerbinati
and M. L. Tosato,
Photocatalytic
Envion. Sci. Technol. 24, 1559-l 565 (1990).
of
627 3. M. C. Lu, G. D. Roam, J. N. Chen, and C. P. Huang, Factors affecting the photocatalytic dichlorvos
over titanium
dioxide supported
on glass, J. Photochem.
Photobiol.
degradation
of
A: Chem. 76. 103-l 10
(1993). 4. M. C. Lu. G. D. Roam, J. N. Chen, and C. P. Huang, Photocatalytic
oxidation
presence of hydrogen peroxide and ferrous ion, CVut.Sci. Tech., 30,29-38 5. M. C. Lu, G. D. Roam, J. N. Chen, and C. P. Huang, Photocatalytic aqueous media with illuminated
degradation
Development
and Optimization
of 4-chlorophenol,
7. X. Fu, L. A. Clark, Q. Yang and M. A. Anderson,
(1994).
mineralization
of toxic wastes in
of a Ti02-coated
fiber-optic
TiOz on sand,
Photooxidative
degradation
cable
Environ. Sci. Technol. 29. 2974-2981 (1996). Enhanced
photocatalytic
performance
based binary metal oxides: TiOz/SiOz and TiOziZrOl, Environ. Sci. Technol. 30.647-653 8. R. W. Matthews,
in the
titanium dioxide, Chem. Eng. Comm.. 139, l-13 (1995).
6. N. J. Peill and M. R. Hoffmann, reactor: photocatalytic
of dichlorvos
of coloured organics
of titanina(1995).
in water using supported
catalysts.
Wut. Res. 25, 1169- 1176 (1993).
9. H. Uichida, S. Itoh and H. Yoneyama,
Photocatalytic
decomposition
of propyzamineusing
TiOz support
on activated carbon, Chemistry Letters, 1995- 1998 (1993). 10. K. Kato, Photocatalytic
property of TiOz anchored on porous alumina ceramic support by the alkoxide
method, Journal of the Ceramic Society ofJapan, 1 1, C. S. Turchi and D. F. Ollis, Photocatalytic
Int. Ed., 101,240-244
Degradation
(1993).
of Organic Water Contaminants:
Mechanism
Involving Hydroxyl Radical Attack, J. Catal.. 122, 178-192 (1990). 12. J. N. Demas. W. D. Bowman, yield of ferrioxalate
actnometer
E. F. Zalewski.
and R. A. Velapoldi,
Determination
with electrically
calibrated
J. Phys. Chem. 85, 2766-2771
radiometer,
of the quantum
(1981). 13. T. Trimoto,
S. Ito.
S.
Kuwabata
and H. Yoneyama.
Titanium Dioxide Loading on Photocatalytic 1275-1281 (1996).
Degradation
Effects of Adsorbents of Propyzamide.
Used as Supports
for
Environ. Sci. Technol. 30.
Pergamon
PII: SO0456535(98)00204-S
EFFECT OF ADSORBENTS COATED WITH TITANIUM DIOXIDE ON THE PHOTOCATALYTIC DEGRADATION OF PROPOXUR Ming-Chun
Lu ‘,
Jong-Nan
Cheu*, and Kuo-Tai Chang3
1. Department of Environmental Engineering and Heulth Chia Nan College of Pharmacy and Science Tainan, Taiwan 71710, ROC 2. Institute of Environmental Engineering National Chiao Tung University Hsinchu, Taiwan 30039, ROC (Received in Germany 13 February 1998; accepted 15 May 1998)
ABSTRACT Photocatalytic
oxidation
of pesticides
in aqueous media irradiated
of research.
Therefore,
the treatment
technology
titanium dioxide coated on the supports was performed oxidizing
in this research.
propoxur
for degradation
such as activated
Results
show
because of its adsorption
agent.
than that with Ti02IGAC complexing can improve the photocatalytic
is the best complexing
The others follow the sequence: rate of propoxur
But the mineralization
01998
using
with plain TiOz
agent
for
plain TiOz > is higher than
rate of propoxur with plain TiOz is lower
it can be concluded
Elsevier
(an insecticide)
carbon, zeolite, brick, quartz and glass beads.
properities.
agent. However,
efficiency
of propoxur
that GACiTiOl
glass beads > zeolite > brick > quartz. The degradation that with TiOz/GAC complexing
by UV light is a rapidly growing field
Science Ltd.
that using GAC as the support
All rights reserved
KEY WORDS
Photocatalytic
oxidation;
supported titanium dioxide; propoxur;
insecticide
INTRODUCTION
Most pesticides
are non-selective;
addition to applying pesticides, considered. pesticides.
Photocatalytic Studies
have
they are also harmful
the pollution
oxidation shown
that
prevention
is a promising illumination
to ecological of pesticides
technology
of semiconductor 617
systems
as well. Therefore.
used in our environment in treating powders
wastewater in aqueous
in
has to be containing solutions
618 containing
organic compounds
TiOz catalyzed
and oxygen induces oxidative
the oxidation
of organic pollutants
equal to or greater than the band-gap
energy
electronic
solution
processes,
reactor
design,
decomposition
in the presence
of UV radiation
The quantum efficiency composition,
[I-S].
of organic compounds
at photon energies
of the process
the organic
substrate.
is influenced
light intensity
by and
surface interactions.
In the last few years, much attention has been devoted to the heterogeneous fixed-bed
reactors
reaction
is initiated
adsorbability efficiency
[3,6,7].
It is agreed that the critical
with hydroxyl
of the pollutants
Matthews
on suitable
[8] suggested
reaction.
adsorbents
inner
surface
to concentrate
agent in dilute aqueous
of a glass
tube.
behavior,
reaction [3-51. However,
indicating
zeolite,
brick.
of pesticides
reaction. Propoxur,
an insecticide,
the
factor in evaluating
the
efficiency,
photocatalyst
(Germany). San-Yu
with TiOz coated on the
of pesticides
follows
may play an important
(Millipore)
the Langmuir-
role in the oxidation
the reaction occurs, at the surface or in the bulk, the
glass
with titanium beads
dioxide
expression
[ 1 I].
Therefore.
coated on supports.
to investigate
the
characteristics
such as of the
was used as a test chemical.
AND METHODS
P25, 50 m*/g, 30 nm mean particle
The supports,
Company
surface.
with TiOl / activated
a herbicide,
Propoxur was obtained from Bayer Company with purity of 96.3%. The photocatalyst, study was Degussa
it may load
scaling up of the process.
was investigated
oxidation
process and
[l-3].
in the
Therefore,
on the
form as the Langmuir-Hinshelwood
quartz
oxidized
with
property of TiOl.
it was noted that wherever
is to study the photocatalytic
MATERIAL
pollutants
oxidation
Kato et al.. [IO] also used the porous alumina
that adsorption
this research
photocatalytic
surface
is an important
of propyzamine.
The photocatalytic
have the same analytical
carbon,
compounds
the decomposition the
solution.
oxidation
rate reactions
activated
surface
the photomineralization
studies, photocatalytic
Hinshelwood-type
on the photocatalyst
To promote
ceramic as the supporter to study the photocatalytic
In our previous
step of organic
that the use of TiOz coated on sand permits economic
Uchida et al., [9] demonstrated carbon complexing
produced
onto the photocatalyst
of the photocatalytic
photocatalyst
radicals
photocatalytic
Ti02 , used in this
from the Degussa
Company
activated carbon, zeolite. brick. quartz and glass beads. were obtained from the
(Taiwan).
and has a resistivity
without further purification.
size obtained
The water used for experiments greater than 18 MO/cm.
was purified
All other chemicals
by a Milli-Q/R0
system
used are of reagent grade
619 The supports were coated with TiOz by preparing minutes),
adding supports
to the sonicated
a TiOz suspension
suspension
in 100 ml water (sonicated
and evaporating
The amounts of TiOz and supports added in this procedure
depended
to dryness in an oven at 100 “c’.
on the experimental
coated supports were then heated at 550 “C for half an hour to produce the complexing
The photocatalytic
reactor is shown in Fig. 1. The reaction
was conducted
vessel with a quartz cover: the volume of reaction mixture was I liter. shorter wavelength
of IJV light.
The cut-off wavelengths
w low pressure
mercury lamps with a major emission
conditions.
The
agents.
in a i.2-liter
double-jacked
Quartz cover was required for the
for quartz are less than 200 nm.
254 nm light can pass through the cover to excite the TiOz.
for a few
The UV radiator was composed
Therefore. by three 10
at 254 nm (Sankyo Ltd., Japan) and was located
above the reactor.
?
0.
-
i
agnetic Stirrer
k+M Gas
Flow Meter
Fig. I, Photocatalytic
For all experimental
runs performed
During experiments,
the reactant solution
reactor used in this study
in this study. the pH of the reacting mixture was ad.justed initially. was agitated continuously
with a magnetic
stirrer and oxygen
(99.9 % purity) was bubbled into the solutions at a constant flow of 50 mlimin to insure oxygen saturation. The samples
were taken from the solution
HPLC (Waters LC module
1). total organic carbon (TOC) was detected
Model 2001), and surface area was determined
Potassium
ferrioxalate
with certain time intervals.
solution
Propoxur
was analyzed
with a
with a TOC analyzer (ASTKO
with a ASAP 2000 BET analyzer.
was used to measure the photon flux in the reactor. The quantum yield
(QY) can be defined as the ratio of the number of molecules on reaction with TiOl - free actinometry
solutions
quantum yield for ferrous ion formation
in the ferrioxalate
reacting to that the photons supplied.
Based
for the reactor. the flux rate was 7.2 ‘* I OeJ Mimin if the solution
is taken
to be 1.28
1121.
620
RESULTS
Photocatalytic
Choosing
AND DISCUSSION
degradation
of propoxur with different complexing
a proper support with a better ability of adsorption
since the support can concentrate g TiOz coated were immersed was also dispersed
organic chemicals
agents
can improve the photocatalytic
on its surface.
Since 3g complexing
in aqueous solutions to start the photocatalytic
efficiency
agent with 0.15
reaction, 0.15 g plain TiOz
in the reaction solution.
Table 1.
Surface areas of coated and uncoated supports
Support and Complexing
agent*
Surface Area (m*/g)
Plain TiOz
50
GAC
902
Coated GAC
745
Quartz
4.90
Coated Quartz
4.57
Zeolite
8.90
Coated Zeolite
4.95
Glass Beads
5.70
Coated Glass Beads
2.95
*: 1 g support was coated with 0.05g of Ti02
Table 1 lists the surface areas of supports coated and uncoated Ti02. The coating process eliminated surface areas of complexing supports. comparing
As shown
agent. The extent of surface area reduction depended
in Fig.2,
GAC/
TiO2 is the best complexing
the surface areas among the complexing
factor affecting on the propoxur
except
disappearance
GAC,
in this reaction
coated
with TiOa
did not improve
system. The reason is that the illumination
to find the proper support
for improving
surface area of GAC induces not only propoxur
By
agent of glass beads has a low surface area, but
the efficiency
agents except GAC/ Ti02. the efficiency
of propoxur
area was reduced when TiOl
was coated on the support surface and the supports can not adsorb propoxur this study is
removal.
of
agents, it is obvious that surface area is not the only
removal. The complexing
the supports
on the characteristics
agent for propoxur
the propoxur removal with glass/ Ti02 is high than that with other complexing Clearly,
the
efficiently.
of propoxur
but also TiOl adsorbs on GAC.
However,
removal.
In fact. TiOl
since
The large is a fine
621 particle that can disperse efficiency
of quantum
mentioned
above,
experiments,
in the bulk solution,
yield because
the GAC
but if coated on the supporter
of surface area reduction.
is still worthy
investigating
surface, will result in a low
Based on the the experimental
in more
details.
Thus.
resulted
in the following
GAC was chosen as the medium.
0.8
0.6 t
Fig.2
Propoxur removal after 60 min illumination Experimental complexing
conditions:
with different-wmplexing
[propoxur]=4.78x10‘4
agents
M: pHo=4;
agent, 3g
Effect of support diameter
To evaluate the effect of support size on propoxur study. diameters
oxidized,
Fig. 3 shows the time course of propoxur of GAC/ TiOz
disappearance. GACI TiOl
complexing
However,
agents.
The smaller
of GAC were used in this
in the photocatalytic
reaction
GACi TiOl diameter.
over various
the faster propoxur
it is difficult to separate the amount of propoxur adsorbed and oxidized on the
surface because the disappearance
the same time.
removal
several diameters
Therefore,
we compared
of propoxur
is attributed
the propoxur remainings
to oxidation
in the GAC/ TiOl
and adsorption
solutions with and Table 2
without UV illumination
to find the effect of GAC diameter on the disappearance
of propoxur.
indicates
of GAC diameter
with and without
the influence
illumination.
on the disappearance
of propoxur
in
UV
622 In general, the rate of propoxur UV illumination oxidation TiOz
because
disappearance
with UV illumination
GAC is an excellent
adsorbent
rate. Thus, UV light can not make a significant
solutions.
However,
according
is slightly higher than that without
resulting
in a higher
effect on the propoxur
to Table 2, it is proved that oxidation
adsorption removal
in the GACi
reaction really happened
its rate was much lower than that of adsorption.
-0-l
0-2Omesh
Effect of GAC diameter on the photocatalytic
oxidation
0.6 -
Time (mitt)
Fig.3
Experimental complexing
Table 2
Effect of
conditions:
[propoxur]=4.78x10-4
of propoxur
M; pHa=4;
agent, 3g
GAC diameter on the adosrption
and oxidation of propoxur*
Propoxur remaining(%)
Diameter
mesh
mm
70-40
0.21-0.42
2.5
1.2
40-25
0.42-0.707
8.6
8.1
25-20
0.707-0.841
11.5
8.3
20-10
0.841-2
31
20
>lO
>2
39.9
40
*Propoxur
remainings
without illumination
are compared at 15 min of reaction time.
rate than
with illumination
, and
623 Effect of Ti02 loading
TiOz loading is another important rate increases
with increasing
blocked by catalyst itself.
factor for propoxur
the TiOz loading
However,
In this experiment,
oxidation
of propoxur.
induces the increase of oxidation
rate.
the rate will be reduced because UV light is
four kinds of TiOJGAC
0.2g and 0.25g TiO2 were coated on lg GAC, separately. the photocatalytic
With plain TiOz , the photocatalytic
oxidation.
Increasing
Fig.4 indicates the effect of TiOs loading on
the amount of TiOz coated on the GAC surface
However, the results shows that the oxidation
0.2 g TiO2 can almost perform as well as that with 0.25 g TiO2 the reason that
the illumination
010
and adsorption
As GAC is an excellent the adsorption complexing
020
oxidation
[propoxur]=4.78x10‘4
agent, lg; illumination
of propoxur
M; pHa=4;
time, 5 hr
of propoxur on the TiOzIGAC surface
adsorbent,
and oxidation
conditions:
0 25
loading (g)
Effect of TiOz loading on the photocatalytic Experimental
Oxidation
The present instance is assumed to be
06
Ti02
complexing
rate with 0.15 and
area do not increase due to a higher catalyst concentration.
0 05
Fig. 4
were prepared; O.OSg, 0. I g, 0.15g.
therefore,
the disappearance
reaction; propoxur
agent surface and then
oxidized.
and its oxidation According
of propoxur
in the solution resulted from
intermediates
were concentrated
on the
to this characteristics
of the complexing
agent,
624 it was found that the disappearance adsorption.
In this experiment.
and then we hardly distinguished For this reason, the adsorption
Fig.5 shows the propoxur
of propoxur
the oxidation
rate on the complexing
of propoxur on the complexing
remaining
complexing
experiment
during the adsorption
than that of oxidation. process.
described
agent for three hours.
phase is attributed to oxidation
phase was mainly
attributed
to
agent surface can not be measured
the amount of propoxur oxidized and adsorbed in the combined reaction.
propoxur adsorbed on the surface of complexing photodegradation
from the aqueous
agent surface was furthur studied.
reaction.
It was found that the amount
agent reached a saturation
after 3 hours.
below were carried out with a preadsorption
It is assumed that the disappearance
with a preadsorption
The reduced amount of propoxur
of propoxur
of propoxur
oxidation
of propoxur
from the aqueous phase is assumed
the
on the
from the aqueous
process because the rate of adsorption
Fig.5 also shows the photocatalytic
Therefore,
of
is much higher
with a preadsorption
to be resulted from the
oxidation reaction.
m
Fig.5 Adsorption Experimental complexing
Comparison
of photocatalytic
To compare the catalytic GAC and dispersing
an Tme(min) and photocatalytic conditions:
oxidation
M; pHo=4;
agent, 1g
reactions onto the surfaces of plain Ti02 and Ti02/GAC
activity of plain TiOz and TiO$GAC.
directly
of propoxur
[propoxur]=8,6xlO‘”
in the solution,
respectively.
0.25 g ‘Ii01 was used for coating on lg
In the TiOziGAC
system,
1 g complexing
625 agent was immersed
in a solution containing
for saturating the complexing photocatalytic
reaction.
The initial concentration
the initial propoxur
oxidation
followed a first-order
solution
of propoxur
was 4.78X lOAM.
In the plain TiOz
was also 4.78X 10e4M. In these two reaction
systems,
propoxur
kinetic behavior. Table 3 lists the kinetic data of propoxur oxidation.
oxidation rate of propoxur with plain TiOz But the mineralization
reaction
agent surface. After three hours, the UV light was turned on to initiate the
solution.
complexing
9.56X 10e4M propoxur to proceed the preadsorption
rate of propoxur
is slightly higher than that with TiOz /GAC compiexing with plain TiOz is somewhat
The agent.
lower than that with TiO$GAC
agent.
Table 3
Rate constants of propoxur oxidation
Catalyst
Rate constant( 1Ihr) Mineralization
Oxidation
TiOziGAC
0.024
0.096
TiOz
0.018
0.102
Without preadsorption
process,
higher than that containing
propoxur
removal
rate in the solution
plain the TiO2 because
containing
GAC is an excellent
TiOz/GAC
adsorbent
was much
that can adsorb
propoxur on its surface in a short period of time. From the HPLC analysis, there were less intermediates found in the TiOIlGAC
system.
It is assumed
adsorbed onto the surface of complexing the reaction remained
the concentration
propoxur
of intermediates
intermediates conclusion,
are oxidized the complexing
as the target substrate
In the plain TiO2 system. the intermediates
agent.
of solution-phase
of a dilute concentration
dissolution
intermediates.
radicals
occurs
very fast as compared
to the suspended
into solution
produced
in
TiO2 surfaces.
of collection
phase onto the complexing
on the GAC can not ultilize
propoxur
and intermediates
and dissolved
propoxur
and
when they collide with TiOz
of degradation agent. as TiO2
all the photons
because
of dissolved
The use of plain ‘TiOz allows the
due to low the adsorbability,
agent has a large capability
and
of the adsorbed
with the collision
further to give a variety of other intermediates
from the solution
TiOl supported for degrading
were
of propyzamide
In this study. the supply
reactor with plain TiO2 can be almost absorbed by the photocatalyst reactor.
in this system
supports can ehhance the rate of mineralization
to the GAC/ TiOz interface
propoxur
formed
in the aqueous phase that can be detected by TOC analysis. Trimoto et d.[ 121 have
also reported that the use of adsorbent reduce
that the intermediates
intermediates
The photons dispersed
entering
TiOr is concentrated
as well
entering
completely
In
the
in the
the reactor to produce on the surface of 1 g
626 GAC
However.
the oxidation
efficiency
with GAC/ TiOz is almost as that with plain Ti02 even the
GACi TiO2 system utlized less amount of photons. support can improve the photocatalytic
efficiency
Therefore,
it can be concluded
that using GAC as the
and it is necessary to optimum light utlization
for GAC/
TiO2 system.
CONCLUSIONS
The rates of photocatalytic supports.
TiOzlGAC
oxidation
of propoxur
is the best complexing
properties.
The others follow the sequence:
degradation
rate of propoxur
However,
the mineralization
complexing associated
agent.
agent for oxidizing
rate of propoxur coated
on the blunt
with plain TiO2
Therefore,
because
of its adsorption
supports
eliminates
the problem
of the decomposition
efficiency
design
to permit
optimum
of filtration The use of
for the pollutants.
in TiO2 /GAC system is due to the small illumination
the reactor
agent.
TiO2 is lower than that with TiOz/GAC
but the reaction rate is mass transfer limited.
TiO2 coated on the GAC permits the promotion efficiency
propoxur
of TiO2 coated
is higher than that with TiO2 /GAC complexing with suspended
with the use of catalyst suspensions
chief loss of quantum
in the presence
aked Ti02 > glass beads > zeolite > brick > quartz. The
with plain TiOz
The catalyst
have been determined
light adsorbed
The
area comparing by TiO2 /GAC is
necessary.
ACKNOWLEDGMENT
This research was supported
by the National Science Council, Republic of China (Grant NSC 85-221 I-E-
009-015)
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