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Enhancement of photocatalytic activity of TiO2 by immobilization on activated carbon for degradation of pharmaceuticals
Accepted Manuscript Title: Enhancement of photocatalytic activity of TiO2 by immobilization on activated carbon for degradation of pharmaceuticals Author: Mohamed Gar Alalm Ahmed Tawfik Shinichi Ookawara PII: DOI: Reference:
S2213-3437(16)30102-6 http://dx.doi.org/doi:10.1016/j.jece.2016.03.023 JECE 1025
To appear in: Received date: Revised date: Accepted date:
23-12-2015 12-3-2016 12-3-2016
Please cite this article as: Mohamed Gar Alalm, Ahmed Tawfik, Shinichi Ookawara, Enhancement of photocatalytic activity of TiO2 by immobilization on activated carbon for degradation of pharmaceuticals, Journal of Environmental Chemical Engineering http://dx.doi.org/10.1016/j.jece.2016.03.023 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
1 2
Enhancement of photocatalytic activity of TiO2 by immobilization on activated carbon for degradation of pharmaceuticals
3
Mohamed Gar Alalma* [email protected], [email protected], b c [email protected], Ahmed Tawfik , Shinichi Ookawara
4 5 6 7 8 9 10 11 12 13
a
Department of Public Works Engineering, Faculty of Engineering, Mansoura University, Mansoura, 35516, Egypt b
Department of Environmental Engineering, School of Energy, Environmental, Chemical and Petrochemical,, Egypt-Japan University of Science and Technology (E-Just), New Borg El Arab City, 21934, Alexandria, Egypt c
Department of Chemical Engineering, Graduate School of Science and Engineering, Tokyo Institute of Technology, O-okayama, Meguro-ku, Tokyo 1528552, Japan *
Corresponding author. Tel. fax. +2-03-4599520
14
1
15
Abstract
16
This work evaluates the photocatalytic activity of bare TiO2 and TiO2 immobilized
17
on activated carbon (TiO2/AC) for degradation of pharmaceuticals. Four selected
18
pharmaceuticals namely amoxicillin, ampicillin, diclofenac, and paracetamol were
19
oxidized using solar irradiation. The TiO2/AC composite was prepared by a
20
temperature impregnation method. Characterization of TiO2/AC by Brunauer–
21
Emmett–Teller (BET) analysis, Fourier transforms infrared spectroscopy (FTIR),
22
and scanning electron microscope (SEM) revealed successful immobilization of
23
TiO2 particles on activated carbon. Amoxicillin and ampicillin were completely
24
degraded by TiO2/AC, while 89% of amoxicillin and 83% of ampicillin were
25
removed by bare TiO2. Likely, TiO2/AC attained higher removal of diclofenac
26
(85%) and paracetamol (70%) as compared to bare TiO2. Amortization and
27
operating costs of full scale solar photocatalytic reactor were estimated. It was
28
found that TiO2/AC is more economic.
29
Keywords: Solar; photocatalytic; pharmaceuticals; TiO2; TiO2/AC
30
2
31
1. Introduction
32
The pharmaceutical industrial facilities produce various products which are used
33
for human and animal medications [1]. Unfortunately, wastewater generated from
34
pharmaceutical industries contains non-biodegradable organics such as drugs and
35
antibiotics which are ineffectively removed by conventional wastewater treatment
36
systems [2–4]. Therefore, treatment of pharmaceutical wastewater is urgently
37
needed for prior treatment before being released into water streams in order to
38
avoid
39
pharmaceuticals are not only found in pharmaceutical industrial wastewater but
40
also low concentrations of different pharmaceuticals were detected in municipal
41
wastewater, surface water and ground water [5,6]. Among all the pharmaceutical
42
compounds that may be harmful to the environment, scientists expressed serious
43
concerns about antibiotics and drugs because of their high consumption rate in
44
both veterinary and human medication [7,8]. In addition, the widespread presence
45
of antibiotics in low concentration leads to development of antibiotic resistant
46
bacteria [9].
47
Biological treatment is preferable due to its low cost. However, the presence of
48
toxic and bio-recalcitrant chemicals detracts the viability of biological treatment
49
process for treatment of pharmaceutical wastewater [10,11]. Advanced oxidation
50
processes (AOPs) have been realized as particularly efficient technologies for
51
treatment of toxic wastewater and non-biodegradable organics [12–14]. In AOPs
52
powerful reactive species like hydroxyl radicals (•OH) are generated by specific
53
chemical reactions in aqueous solutions [15]. Hydroxyl radicals are able to destroy
54
the most resistant organic molecules and break them down into relatively less
55
persistent organics and end products such as CO2 and H2O [16]. Among AOPs,
56
heterogeneous photocatalysis using artificial ultraviolet (UV) light source or solar
57
irradiation has been recognized to be effective for the degradation of several types
serious
environmental
problems.
Researchers
have
found
that
3
58
of
59
pharmaceuticals [17]. In heterogeneous UV/TiO2 processes, ultraviolet light (λ<
60
400nm) is utilized as an energy source and TiO2 acts as a semiconductor photo-
61
catalyst[18–20]. Nano-scale TiO2 is distinctive with big surface area, good particle
62
size distribution, high chemical stability, and the possibility of using sunlight as a
63
source of irradiation [12]. In photocatalysis process, the photons with energies
64
higher than the band-gap energy cause excitation of valence band (VB) electrons
65
which then enhance the reaction of TiO2 with organic molecules [21]. Illumination
66
of the catalyst active sites with sufficient energy produces positive holes (h+) in the
67
valence band and in electrons (e-) in the conduction band. The positive holes
68
oxidize either the organic pollutants or H2O to induce hydroxyl radicals [7,22].
69
Many researchers investigated immobilization of TiO2 nano particles on different
70
support materials to improve the photocatalytic activity and make the separation of
71
treated effluent more effective [23–25]. Coating surfaces with TiO2 has relatively
72
low improvement on photocatalytic reaction because of the low particles
73
dispersion and limited mass transfer between the pollutants molecules and the
74
catalyst [26,27]. Catalysts can be more effective and easily separated from the
75
effluent if they are supported on adsorbent surface such as powdered activated
76
carbon (PAC) [28–30]. Activated carbon (AC) has no photocatalytic activity but it
77
certainly enhances the photocatalytic reaction between TiO2 and the contaminants
78
due to the adsorption of pollutants on its surface [31,32]. Increased adsorption
79
contributes to higher concentration of contaminants around TiO2 active sites [33].
80
Activated carbon has a good developed pore structure, very large surface area, and
81
high adsorption capacity. Therefore, it is widely used as an adsorbent for organic
82
and inorganic pollutants [34]. The AC in the TiO2/AC catalyst would act as a
83
reaction station where organic molecules are adsorbed before transferring to the
84
decomposition center [32,35]. Many researchers used Langmuir–Hinshelwood
persistent
organics
such
as
phenolic
compounds,
pesticides,
and
4
85
model to describe the kinetics of photocatalytic degradation of different organics in
86
aqueous solutions [36]. The model basically relates the rate of degradation (r) and
87
concentration of substrate (C) in water at reaction time (t) [37].
88
The main objective of this investigation is to assess the efficiency of solar
89
photocatalytic oxidation process using TiO2 versus TiO2/AC for degradation of
90
pharmaceuticals. Two antibiotics namely amoxicillin and ampicillin and two
91
prevalent drugs (diclofenac and paracetamol) were used as model substrates.
92
TiO2/AC catalyst characterization was carried out and factors affecting on the
93
photo degradation process such as pH and catalyst loading were extensively
94
studied. Furthermore, the pseudo-first order kinetic reaction was tested according
95
to the Langmuir–Hinshelwood model.
96 97
2. Materials and methods
98
2.1 Chemicals
99
Amoxicillin, ampicillin, paracetamol, and diclofenac were purchased from Glaxo
100
Smith Kline. The TiO2 and powdered activated carbon (AC) with bulk density of
101
0.37 g/cm3 in Nano scale was obtained form from Acros and Adwic respectively.
102
2.2 Catalyst preparation
103
Immobilization of TiO2 on activated carbon (AC) was executed according to the
104
high temperature impregnation method described by El-Sheikh et al [38]. A slurry
105
of 20 g TiO2 was heated and stirred with 300 ml of distilled water at a temperature
106
of 70˚C. AC was added with a ratio of TiO2 being 1:2 respectively. The mixture
107
was continuously stirred for 120 minutes at a temperature of 70˚ C. The dark black
108
color of AC and white color of TiO2 were observed at the beginning at which the
109
mixture was gradually changed into a gray color. This observation implies that the
5
110
interaction between AC and TiO2 certainly occurred. The mixture was settled for
111
15 minutes and then the supernatant was decanted and the precipitate was dried in
112
the oven at a temperature of 200˚ C for 12 hrs.
113
2.3 Photocatalysis experiments
114
Photocatalysis experiments were carried out using a solar reactor equipped with
115
compound parabolic collectors (CPCs). The reactor was placed at the city of Borg
116
Alarab, Egypt (Latitude 30°52’, Longitude 29°35’). The reactor consists of six
117
borosilicate tubes (0.36 m2) with a diameter of 2.5 cm and a length of 75 cm
118
mounted on curved polished aluminum sheets with radius of curvature 9.2 cm. The
119
module was fed with pharmaceutical mixtures in a closed cycle. The feed stock of
120
pharmaceuticals solution was continuously circulated in a closed cycle in the
121
module. A schematic diagram of the experimental set-up is shown in Fig 1. The
122
reactor was initially fed with 4 L of a pharmaceutical solution (50 mg/l) for a
123
period of 210 minutes. The first 30 minutes was used to assess the adsorption
124
process without illumination and 180 minutes for photocatalytic process. TiO2 or
125
TiO2/AC were used as catalysts. Effects of pH values, TiO2 and TiO2/AC dosage
126
were investigated. The pH value of the mixture was changed from 3 to 10 using
127
H2SO4, and NaOH (50%). TiO2 and TiO2/AC dosages varied from 0.2 to 0.8 and
128
from 0.4 to 1.6 g/L respectively. The solar irradiation was measured by Met, one
129
Portable Weather Station (Model Number 466A). The normalized illumination
130
time (t30w) was used to compare between photo-catalytic experiments instead of
131
exposure time (t). The normalized illumination time was calculated by the
132
following equations [16,39]:
133
t30w,n t30w,n1 tn UV / 30 Vi / Vt
(4)
134
6
135
tn tn – tn1
136
Where tn : contact time, UV : average solar ultraviolet radiation (W/m2) measured
137
during ∆tn, t30W : the normalized illumination time, which refers to a constant solar
138
UV power of 30W/m2 (typical solar UV power on a perfectly sunny day around
139
noon), Vt : the total reactor volume and Vi : the total irradiated volume.
140
2.4 Analytical methods
141
The concentrations of pharmaceuticals were quantified by Shimadzu HPLC using
142
C-18 phenomenex reverse phase column, degasser (20A5), pump (LC-20AT), and
143
prominences Diode Array Detector (SPD-M20A). The samples were filtered by
144
micro syringe filters (0.2 µm). The mobile phase was (60:40) 0.025M KH2PO4
145
buffer solution in ultrapure water and acetonitrile. The flow rate was 0.50 mL/min
146
and the temperature was 60˚C. For characterization of TiO2 deposition on activated
147
carbon, FTIR spectra were recorded on a VERTEX 70 spectrometer over the wave
148
number range 3800-400 cm-1 using KBr pellets for sample preparation. Scanning
149
electron microscope (SEM) images were taken with a JEOL 611. Pore size and
150
surface area of the catalyst were determined by Brunauer–Emmett–Teller (BET)
151
analysis using Belsorp-max automated apparatus using liquid N2 adsorption at a
152
temperature of 77 K.
153
2.5 Kinetic study
154
The model of Langmuir–Hinshelwood was used to relate the rate of degradation (r)
155
and concentration of substrate (C) in water at reaction time t. The model can be
156
expressed by the following equation [40];
157
r
dC Kr Kad C dt 1 Kad C
(2)
(3)
7
158
Where kr : the rate constant and Kad : the adsorption equilibrium constant. In the
159
process of photocatalysis when the adsorption is relatively weak like and/or the
160
reactant concentration is low, Equation (3) can be simplified to the pseudo- first
161
order kinetics with an apparent first-order rate constant kapp [36]:
162
C ln 0 Kr Kad t Kappt C
163
Where C0: is the initial concentration of pharmaceuticals.
(4)
164 165
3. Results and discussion
166
3.1 Characterization of TiO2/AC
167
The results of Brunauer–Emmett–Teller (BET) analysis for AC and TiO2/AC are
168
summarized in Table. 1. The specific surface area of AC was decreased from
169
1325.23 to 849.2 m2/g by impregnation of TiO2 into its surface, which certainly
170
attributed to the deposition of TiO2 on the pores and external surface of AC. The
171
decreasing of the surface area of the TiO2/AC can be interpreted in terms of the
172
calcinations at high temperature (200˚ C) which induced the formation of anatase
173
TiO2 on the surface and the pores of activated carbon [38]. In addition, total pore
174
volume of AC was slightly decreased from 0.8645 to 0.7804 cm3/g after the
175
deposition of TiO2. However, mean pore diameter of AC increased from 2.57 to
176
3.74 nm after the deposition process. Both processes mainly occurred due to the
177
partial pore collapse and shrinkage after impregnation at high temperature that may
178
lead to discrepancies in pore structure from micropores to mesopores [41].
179
Furthermore, the larger pore size is mainly caused by the formation of inter-
180
agglomeration particles [42].
8
181
The (SEM) images of naked activated carbon and the composite of TiO2/AC are
182
shown in Figs. 2a and b. The images show that the naked activated carbon
183
particulates have irregular shapes (Fig. 2a). Moreover, the surface of the activated
184
carbon particulates is rough with heterogeneous pores, which certainly indicates a
185
high prospect for TiO2 to be entrapped and adsorbed onto the surface and the pores
186
of activated carbon. For the TiO2/AC, The SEM image (Fig.2b) shows that TiO2
187
particulates are uniformly immobilized on the surface of activated carbon. It can be
188
seen that the supported TiO2 which appears in image by gray color covered most
189
of the surface of activated carbon, and also it is reported that some of TiO2 could
190
deposit in the mesopores and macrospores of activated carbon [29]. Since the
191
photocatalysis process strongly depends on light intensity, deposition of TiO2 on
192
the external surface of AC will undoubtedly provide more chance to be exhibited
193
to light and subsequently will improve the photocatalytic degradation process.
194
Moreover a high content TiO2 on the external surface of activated carbon is
195
favored to enhance and accelerate the photocatalytic activity of the catalyst [35].
196
The spectra of Fourier transform infrared spectroscopy (FTIR) spectra of AC, and
197
TiO2/AC are illustrated in Fig. 3. The spectrums revealed that the impregnation of
198
TiO2 with the activated carbon produced a broad peak from 400 to 800 cm-1 which
199
could be attributed to the formation of bulk Titania framework on the surface and
200
the pores of activated carbon [19]. This result indicated a good interaction between
201
the activated carbon surface and titanium dioxide. In addition, the peak at 1650 cm-
202
1
203
appeared in the spectrum of TiO2/AC. This shift was probably caused by the Ti-O-
204
C band owing to the electron affinity of carbon when using hydrothermal methods
205
in preparation of TiO2/AC [28]. The peak at 2382 cm-1 which refers to O–H
206
stretching [43] became smaller after TiO2 immobilization. Moreover, the band at
assigned to –OH vibration was shifted to 1585 cm-1. A new peak at 1165 cm-1
9
207
3400 cm-1 that assigned to –OH stretching [44] was disappeared in TiO2/AC
208
spectra.
209
3.2. Photocatalytic degradation by bare TiO2
210
Fig.4 depicts the efficiency of TiO2 photocatalytic degradation of pharmaceuticals
211
(amoxicillin, ampicillin, diclofenac, and paracetamol). The obtained results
212
indicated that the removal efficiencies of amoxicillin, ampicillin, diclofenac, and
213
paracetamol after 30 minutes without illumination were 5%, 4% 5% and 6% which
214
are considered very limited comparing to the removal in illumination period. The
215
removal of pharmaceuticals during the first 30 minutes was mainly due to
216
adsorption of pharmaceuticals on the catalyst active sites. The photocatalytic
217
degradation after the illumination is allowed was influenced by irradiation time as
218
shown in Fig 4. The major portion of pharmaceuticals was removed by TiO2
219
photocatalysis during the first 90 minutes of irradiation (86 % for amoxicillin, 72%
220
for ampicillin, 58% for diclofenac, and 40% for paracetamol). The higher
221
degradation rates at the first 90 minutes are attributed to the abundance of hydroxyl
222
radicals. In the second 90 minutes of irradiation the degradation rates were
223
diminished which resulted in final removal efficiency of 89 % for amoxicillin,
224
83% for ampicillin, 68% for diclofenac, and 57% for paracetamol. This can be due
225
to the exhausting of the active sites of the catalyst and hence the produced
226
hydroxyl radicals were completely consumed at the late stages of the reaction. The
227
difference in photocatalytic degradation efficiency from pharmaceutical to another
228
is attributed to the adsorbability of pharmaceutical molecules towards the active
229
sites of TiO2 where the hydroxyl radicals are available.
230
3.3. Photocatalytic degradation by TiO2/AC
231
The degradation of pharmaceuticals by TiO2/AC is shown in Fig. 5. The
232
elimination of pharmaceuticals in the dark process by TiO2/AC was higher than
10
233
bare TiO2 resulting in removal efficiencies of 17% for amoxicillin, 9 % for
234
ampicillin, 10% for diclofenac, and 11% for paracetamol. This indicates that the
235
adsorption capacity of TiO2 /AC is substantially higher than naked TiO2 as
236
expected[45]. During the first 90 minutes of irradiation high degradation rates of
237
pharmaceuticals were observed. This founding is due to the free surface of
238
activated carbon at early stage which led to higher adsorbability of the catalyst. In
239
addition, at early stage of the process there is abundance of hydroxyl radicals near
240
the surface of the catalyst. Nevertheless, the produced hydroxyl radicals are
241
completely consumed at the late stages of the reaction which diminished the
242
photocatalytic degradation rates as shown in Fig. 5. Complete degradation of
243
amoxicillin was attained after 120 minutes of irradiation. This was better than
244
naked TiO2 as 89% of amoxicillin was removed after 150 minutes of irradiation.
245
This indicates that TiO2/AC does not only attain higher degradation efficiency of
246
amoxicillin but also accelerate the photocatalytic process. Similar trends were
247
observed for the removal of ampicillin, diclofenac, and paracetamol. Apparently,
248
the immobilization process enhanced the reaction between the produced hydroxyl
249
radicals and the amoxicillin molecules on the surface of TiO2/AC because the
250
attraction of pharmaceutical molecules to the catalyst active sites has been
251
increased. Moreover, the variation in degradation efficiency of pharmaceuticals
252
can be attributed to the different affinity to the binding sites on the catalyst. The
253
enhancement of photocatalytic degradation of pharmaceuticals by using TiO2/AC
254
is in accordance with the finding of other researchers who examined the
255
immobilization of TiO2 on activated carbon for removal of different organic
256
compounds [30,32,46,47].
257
Comparing these results with our previous work for degradation of the same
258
pharmaceuticals by solar photo-Fenton process [1], it is found that photo-Fenton
259
process is more effective. Complete degradation of all pharmaceuticals was
11
260
attained after irradiation time ranged between 60 and 120 minutes. In addition,
261
there is no big difference in the estimated costs as shown in part 3.5. However,
262
there are some problems associated with photo-Fenton process. First, photo-Fenton
263
process is favored at lower pH (optimum pH≈3) which may cause some problems
264
such as corrosion of mechanical facilities and it needs neutralization stage. Second,
265
traces of iron remained in the treated effluent [48]. Third, considerable amount of
266
sludge is produced during Fenton process. On the other hand, there is no
267
considered sludge produced during photocatalysis process and the remained
268
amount of TiO2 is not harmful to the environment. For all these reasons,
269
photocatalysis may be preferred in spite of the lower efficiency.
270
3.3. Parameters affecting photocatalytic degradation
271
3.3.1. Effect of initial pH on degradation efficiency
272
The pH of the solution affects the surface charge of activated carbon, TiO2, and the
273
dissolved organic molecules. Subsequently adsorption, and photocatalysis process
274
are affected [26,49,50]. Fig. 6 shows the effect of initial pH on the degradation
275
efficiency of pharmaceuticals. Complete removal of amoxicillin and ampicillin
276
was achieved at pH 10. However, the removal efficiency was dropped at pH values
277
ranging from 3 to 5 as shown in Fig 6a and b. Similar was observed for diclofenac,
278
and paracetamol which the removal efficiencies were decreased from 82% and
279
70% at pH value of 10 to 60% and 58% at pH 3 respectively. The effect of pH on
280
degradation of pharmaceuticals can be explained in terms of the ionization state of
281
the TiO2 and the substrate. The surface charge of the activated carbon and the
282
loaded catalyst depends on the zero point of charge (pHpzc) and the pH of the
283
solution. The surface charge of the adsorbent is negative and its surface functional
284
group is protonated by the H+ ions from the dissolved matter in the solution at pH
285
˃ pHpzc,. On the contrary, at pH ˂ pHpzc, the surface charge of the adsorbent is
12
286
positive and the functional groups is deprotonated by the excess of OH- ions [51].
287
In literature [7] the zero point of charge of TiO2 is 6.4. Accordingly, increasing
288
the pH of the solution changed the surface charge of TiO2 from positive to
289
negative. The pHpzc of the activated carbon is reported to be between 3 and 7
290
regarding to the preparing method and the used material [43,45,52]. On the other
291
hand, amoxicillin has a negative charge when the pH is lower than 5 [53]. In the
292
acidic conditions, amoxicillin, free active sites of carbon and TiO2 particulates are
293
positively charged which led to repulsive forces between amoxicillin and the
294
catalyst which inhibited the degradation.
295
At alkaline conditions the catalyst and pharmaceuticals are negatively charged.
296
This also produces repulsive forces which detract the adsorption on the active sites
297
of the catalyst. The observed enhancement in degradation efficiency of amoxicillin
298
on higher pH could be attributed to the increasing of hydroxyl radicals production
299
in alkaline conditions because of the availability of hydroxyl ions production on
300
TiO2 surface which can be oxidized to form more hydroxyl radicals [7]. This
301
finding is in accordance with other researchers who investigated the effect of pH
302
on photocatalytic oxidation of pharmaceuticals [53–55].
303
3.3.2. Effect of catalyst loading
304
The effect of dosage of TiO2/AC on the removal efficiency of pharmaceuticals is
305
shown in Fig. 7a. The results obtained revealed that photocatalytic degradation
306
performance was substantially improved with increasing the amount of TiO2/AC
307
and reached a plateau at a dosage of 1.2 g/L. This finding is mainly due to the
308
increasing of active sites of activated carbon and TiO2 by providing a higher
309
amount of catalyst. Consequently, the production of electron-hole pairs on the
310
surface of TiO2 and the high reactive hydroxyl radicals was improved [56].
311
Increasing the dosage of TiO2/AC up to 1.6 g/L attained a slight improvement in
13
312
degradation process in spite of the increasing of the active sites. This finding can
313
be attributed to the decreasing of light penetration due to higher turbidity. Fig 7.b
314
depicts the effect of TiO2 loading on the removal of pharmaceuticals. Increasing
315
the amount of TiO2 substantially improved the degradation efficiency of
316
pharmaceuticals due to the enhancement of production of hydroxyl radicals.
317
However, the loading of TiO2 more than 0.6 g/L led to more turbidity of the
318
solution because TiO2 particulates are very fine. Subsequently, a smaller amount of
319
the TiO2 in the suspension was activated only near the reactor wall, where the
320
sunlight can penetrate [57]. Moreover, increasing the TiO2 loading may deactivate
321
the previously activated particulates by collision with ground-state catalysts.
322
Moreover, agglomeration and sedimentation of TiO2 may also occur under large
323
amount of loadings which leads to lower surface area [58].
324
3.4. Degradation kinetic studies
325
Fig.8 shows the linear relationship between ln (C0/C) and irradiation time. Kapp and
326
R2 were calculated for TiO2/AC and TiO2 which are illustrated in Table 2. The
327
photocatalytic degradation by TiO2/AC shows high reaction rates compared to the
328
TiO2 which confirms the enhancement of photocatalytic performance by
329
immobilization of TiO2 on activated carbon. Moreover the high correlation
330
coefficient values revealed that the photocatalytic degradation of the used
331
pharmaceuticals strictly followed Langmuir–Hinshelwood model.
332
3.5 Economic evaluation
333
The design and construction of industrial wastewater treatment plant are certainly
334
influenced by the efficiency of contaminants removal, and the costs of different
335
alternatives [59]. Estimation of construction and operation costs depends on the
336
optimization of operational conditions i.e., irradiation time and dosage of
337
chemicals [60].
14
338
In this investigation, capital and running costs of photocatalytic oxidation process
339
by TiO2 and TiO2/AC were assessed. The results obtained from the experimental
340
work were used to estimate the costs of treatment plant with a capacity of 30 m3/d
341
and contaminated of 100 mg/L of one pharmaceutical. The capacity (C ) of the
342
proposed wastewater treatment plant is estimated using equation (5) [61].
343
C Vt
tt tw D
5
344
Where Vt: volumetric treated wastewater in one year, tt: operation time for the
345
treatment plant facilities in one batch, tw: working time per day for wastewater
346
treatment plant, and D: the number of working days in a year. The ratio between
347
treatment time and working time was assumed 35% which corresponded to the
348
optimum irradiation time concluded from the experiments and the average solar
349
UV flux in Egypt. The ratio of irradiated volume to the total treatment plant
350
volume was assumed 75%, and the illumination area of the plant (Ap) is 4.5 m2
351
according to the volumetric rate of the wastewater.
352
Amortization costs of the investment (AMC) and operating costs (OC) per cubic
353
meter of liquid waste were considered for costs estimation. The amortization costs
354
were calculated taking into consideration the constructing materials and the
355
required equipment. The investment cost per year (I) is calculated according to the
356
illumination area of the treatment plant (Ap), and the treatment plant life time (L)
357
using equation (6) [61]:
358
I
ApCp L
6
359
Where Cp: the cost per one m2 of the illuminated surface in the plant. A value of
360
800 €/m2 is considered according to the costs of durable reflection surface,
15
361
borosilicate tubes, tanks, and other mechanical equipment. The amortization costs
362
per m3 is calculated by equation (7) [62]:
363
AMC
I Vt
7
364
The operating costs include maintenance, the reactants and the energy consumed.
365
The staff costs are not calculated in this estimation for the simplicity of the
366
calculations. In addition, the solar photocatalytic reactor is independent on
367
manpower [62]. The maintenance costs are assumed to be 2% of the yearly
368
investment according to previous studies [63,64].
369
including catalysts and pH adjustment reagents are calculated as the concentration
370
(Ci) (kg/m3) multiplied by the unit price (Pi) (€/kg). Prices of chemicals were taken
371
as the average values from different suppliers inside and outside of Egypt. The
372
prices of commercial TiO2 and powdered activated carbon for industrial use were
373
taken 2.3 €/kg and 0.45 €/kg respectively. The energy cost (EC) (€/m3) is
374
calculated concerning the required power for pumping the liquid waste in the
375
treatment plant by equation (8).
376
EC
EPti w D Vt
The costs of chemicals
8
377
Where E: the power for pumping the wastewater from the tank to the reactor, Pi:
378
the unit price of energy. It is assumed that the costs of energy is 0.12 €/kw.h
379
according to the rates in Egypt. The calculated treatment costs including
380
amortization costs (AMC) by using TiO2 and TiO2/AC are illustrated in Table 3.
381
According to the fixed volume of liquid waste and plant life cycle, the
382
amortization cost was 1.52 €/m3 for all the cases. Table 3 reveals that the variation
383
of operating costs mainly depend on the type and dosage of the catalyst. Moreover,
16
384
for all types of pharmaceuticals using TiO2/AC was more economic than using
385
TiO2 in terms of removal efficiency. For instance, the maximum removal
386
efficiency of amoxicillin by TiO2/AC was 100% and costs 3.19 €/m3. On the other
387
hand, the maximum removal efficiency of amoxicillin by TiO2 was 91% and costs
388
3.29 €/m3. This trend is similar to the trend of ampicillin, diclofenac, and
389
paracetamol as illustrated in table 3.
390 391
4. Conclusions
392
Solar photocatalytic degradation of four types of pharmaceuticals namely
393
amoxicillin, ampicillin, diclofenac, and paracetamol using TiO2 nano-particles
394
versus TiO2 immobilized on powdered activated carbon (TiO2/AC) was
395
investigated. The images of TiO2/AC taken by SEM revealed successful
396
impregnation of TiO2 on PAC. This was also confirmed by the FTIR spectra and
397
BET analysis for activated carbon and the prepared TiO2/AC. Complete removal
398
of amoxicillin and ampicillin was achieved by TiO2/AC after 120 and 180 minutes
399
of irradiation respectively. This was not the case for bare TiO2, where 89 and 83%
400
of amoxicillin and ampicillin were removed. Similar trends were observed for the
401
removal of diclofenac and paracetamol. The removal efficiency of diclofenac and
402
paracetamol were increased from 68 to 85% and from 57 to 70% respectively
403
using TiO2/AC. Photocatalytic degradation efficiency of pharmaceuticals was
404
strongly dependent on the pH values and dosage of the catalysts. The estimated
405
total costs to attain optimum removal of pharmaceuticals by TiO2/AC were 3.19
406
€/m3 while the total costs to attain optimum removal by bare TiO2 were 3.29 €/m3.
407
Based on these results it is recommended to use TiO2 immobilized on activated
408
carbon (AC) for removal of pharmaceuticals from industrial wastewater.
409
17
410
Acknowledgments
411
The authors wish to acknowledge Ms. Iman Abdelaal for the valuable revision of
412
this paper.
413
education which granted him a full PhD scholarship.
The first author is grateful for the Egyptian ministry of higher
414
18
414 415
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Fig. 1 Schematic diagram of the solar compound parabolic collectors reactor.
644 645 646 647 648 649 650
28
651 652
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654 655
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656
29
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658 659 660 661 662 663
664 665
Fig. 3 FTIR spectra of TiO2 and TiO2/AC catalysts.
666 667 668
30
669
670 671 672
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673 674 675 676
31
677 678 679
Fig. 5 Degradation of pharmaceuticals by TiO2/AC, Initial concentration of all pharmaceuticals = 50 mg/L, TiO2/AC dosage = 1.2 g/L.
680 681 682
32
683 684 685 686
Fig. 6 Effect of initial pH on degradation of pharmaceuticals by photocatalysis, Initial concentration of all pharmaceuticals = 50 mg/L, TiO2/AC dosage = 1.2 g/L, (a) Amoxicillin, (b) Ampicillin, (c) Diclofenac, (d) Paracetamol
687
33
688 689 690 691
692 693 694 695
Fig. 7 Effect of catalyst dosage on Degradation of pharmaceuticals by photocatalysis, Initial concentration of all pharmaceuticals = 50 mg/L, Initial pH = 10, t30,w = 180 min, (a) by TiO2/AC, (b) by TiO2.
696
34
697
698 699 700 701 702
Fig. 8 Kinetic analysis for photocatalytic degradation of pharmaceuticals, Initial concentration of all pharmaceuticals = 50 mg/L, Initial pH = 10, (a) by TiO2/AC, (b) by TiO2.
703
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Tables
705
Table. 1 Brunauer–Emmett–Teller (BET) analysis of AC and TiO2/AC Parameter
AC
TiO2/AC
Specific surface area SBET (m2/g)
1325.2
849.2
Total pore volume (cm3/g)
0.8645
0.7804
Mean pore diameter (nm)
2.57
3.74
706 707
36
708 709
Table 2. kinetic analysis by Langmuir–Hinshelwood model. Catalyst
TiO2/AC
TiO2
Pharmaceutical
Kapp
R2
Amoxicillin
0.037
0.997
Ampicillin
0.022
0.984
Diclofenac
0.010
0.973
Paracetamol
0.006
0.903
Amoxicillin
0.013
0.830
Ampicillin
0.011
0.955
Diclofenac
0.005
0.898
Paracetamol
0.004
0.943
710 711 712 713 714 715 716 717 718 719 720 721 722
37
723
Table 3. Costs estimation for TiO2/AC and TiO2 solar photocatalysis TiO2 dose (mg/L)
AC dose
TiO2/AC
133
TiO2/AC
Catalyst
Operating Total costs costs (€/m3)
(€/m3)
267
0.81
2.33
267
533
1.24
2.76
TiO2/AC
400
800
1.67
3.19
TiO2
200
0
0.85
2.37
TiO2
400
0
1.31
2.83
TiO2
600
0
1.77
3.29
Removal Pharmaceutical efficiency (%) Amoxicillin 62 Ampicillin 57 Diclofenac 51 Paracetamol 43 Amoxicillin 87 Ampicillin 84 Diclofenac 73 Paracetamol 63 Amoxicillin 100 Ampicillin 100 Diclofenac 85 Paracetamol 70 Amoxicillin 52 Ampicillin 55 Diclofenac 43 Paracetamol 40 Amoxicillin 88 Ampicillin 84 Diclofenac 64 Paracetamol 57 Amoxicillin 91 Ampicillin 89 Diclofenac 75 Paracetamol 63
724 725 726 727
38
S2213-3437(16)30102-6 http://dx.doi.org/doi:10.1016/j.jece.2016.03.023 JECE 1025
To appear in: Received date: Revised date: Accepted date:
23-12-2015 12-3-2016 12-3-2016
Please cite this article as: Mohamed Gar Alalm, Ahmed Tawfik, Shinichi Ookawara, Enhancement of photocatalytic activity of TiO2 by immobilization on activated carbon for degradation of pharmaceuticals, Journal of Environmental Chemical Engineering http://dx.doi.org/10.1016/j.jece.2016.03.023 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
1 2
Enhancement of photocatalytic activity of TiO2 by immobilization on activated carbon for degradation of pharmaceuticals
3
Mohamed Gar Alalma* [email protected], [email protected], b c [email protected], Ahmed Tawfik , Shinichi Ookawara
4 5 6 7 8 9 10 11 12 13
a
Department of Public Works Engineering, Faculty of Engineering, Mansoura University, Mansoura, 35516, Egypt b
Department of Environmental Engineering, School of Energy, Environmental, Chemical and Petrochemical,, Egypt-Japan University of Science and Technology (E-Just), New Borg El Arab City, 21934, Alexandria, Egypt c
Department of Chemical Engineering, Graduate School of Science and Engineering, Tokyo Institute of Technology, O-okayama, Meguro-ku, Tokyo 1528552, Japan *
Corresponding author. Tel. fax. +2-03-4599520
14
1
15
Abstract
16
This work evaluates the photocatalytic activity of bare TiO2 and TiO2 immobilized
17
on activated carbon (TiO2/AC) for degradation of pharmaceuticals. Four selected
18
pharmaceuticals namely amoxicillin, ampicillin, diclofenac, and paracetamol were
19
oxidized using solar irradiation. The TiO2/AC composite was prepared by a
20
temperature impregnation method. Characterization of TiO2/AC by Brunauer–
21
Emmett–Teller (BET) analysis, Fourier transforms infrared spectroscopy (FTIR),
22
and scanning electron microscope (SEM) revealed successful immobilization of
23
TiO2 particles on activated carbon. Amoxicillin and ampicillin were completely
24
degraded by TiO2/AC, while 89% of amoxicillin and 83% of ampicillin were
25
removed by bare TiO2. Likely, TiO2/AC attained higher removal of diclofenac
26
(85%) and paracetamol (70%) as compared to bare TiO2. Amortization and
27
operating costs of full scale solar photocatalytic reactor were estimated. It was
28
found that TiO2/AC is more economic.
29
Keywords: Solar; photocatalytic; pharmaceuticals; TiO2; TiO2/AC
30
2
31
1. Introduction
32
The pharmaceutical industrial facilities produce various products which are used
33
for human and animal medications [1]. Unfortunately, wastewater generated from
34
pharmaceutical industries contains non-biodegradable organics such as drugs and
35
antibiotics which are ineffectively removed by conventional wastewater treatment
36
systems [2–4]. Therefore, treatment of pharmaceutical wastewater is urgently
37
needed for prior treatment before being released into water streams in order to
38
avoid
39
pharmaceuticals are not only found in pharmaceutical industrial wastewater but
40
also low concentrations of different pharmaceuticals were detected in municipal
41
wastewater, surface water and ground water [5,6]. Among all the pharmaceutical
42
compounds that may be harmful to the environment, scientists expressed serious
43
concerns about antibiotics and drugs because of their high consumption rate in
44
both veterinary and human medication [7,8]. In addition, the widespread presence
45
of antibiotics in low concentration leads to development of antibiotic resistant
46
bacteria [9].
47
Biological treatment is preferable due to its low cost. However, the presence of
48
toxic and bio-recalcitrant chemicals detracts the viability of biological treatment
49
process for treatment of pharmaceutical wastewater [10,11]. Advanced oxidation
50
processes (AOPs) have been realized as particularly efficient technologies for
51
treatment of toxic wastewater and non-biodegradable organics [12–14]. In AOPs
52
powerful reactive species like hydroxyl radicals (•OH) are generated by specific
53
chemical reactions in aqueous solutions [15]. Hydroxyl radicals are able to destroy
54
the most resistant organic molecules and break them down into relatively less
55
persistent organics and end products such as CO2 and H2O [16]. Among AOPs,
56
heterogeneous photocatalysis using artificial ultraviolet (UV) light source or solar
57
irradiation has been recognized to be effective for the degradation of several types
serious
environmental
problems.
Researchers
have
found
that
3
58
of
59
pharmaceuticals [17]. In heterogeneous UV/TiO2 processes, ultraviolet light (λ<
60
400nm) is utilized as an energy source and TiO2 acts as a semiconductor photo-
61
catalyst[18–20]. Nano-scale TiO2 is distinctive with big surface area, good particle
62
size distribution, high chemical stability, and the possibility of using sunlight as a
63
source of irradiation [12]. In photocatalysis process, the photons with energies
64
higher than the band-gap energy cause excitation of valence band (VB) electrons
65
which then enhance the reaction of TiO2 with organic molecules [21]. Illumination
66
of the catalyst active sites with sufficient energy produces positive holes (h+) in the
67
valence band and in electrons (e-) in the conduction band. The positive holes
68
oxidize either the organic pollutants or H2O to induce hydroxyl radicals [7,22].
69
Many researchers investigated immobilization of TiO2 nano particles on different
70
support materials to improve the photocatalytic activity and make the separation of
71
treated effluent more effective [23–25]. Coating surfaces with TiO2 has relatively
72
low improvement on photocatalytic reaction because of the low particles
73
dispersion and limited mass transfer between the pollutants molecules and the
74
catalyst [26,27]. Catalysts can be more effective and easily separated from the
75
effluent if they are supported on adsorbent surface such as powdered activated
76
carbon (PAC) [28–30]. Activated carbon (AC) has no photocatalytic activity but it
77
certainly enhances the photocatalytic reaction between TiO2 and the contaminants
78
due to the adsorption of pollutants on its surface [31,32]. Increased adsorption
79
contributes to higher concentration of contaminants around TiO2 active sites [33].
80
Activated carbon has a good developed pore structure, very large surface area, and
81
high adsorption capacity. Therefore, it is widely used as an adsorbent for organic
82
and inorganic pollutants [34]. The AC in the TiO2/AC catalyst would act as a
83
reaction station where organic molecules are adsorbed before transferring to the
84
decomposition center [32,35]. Many researchers used Langmuir–Hinshelwood
persistent
organics
such
as
phenolic
compounds,
pesticides,
and
4
85
model to describe the kinetics of photocatalytic degradation of different organics in
86
aqueous solutions [36]. The model basically relates the rate of degradation (r) and
87
concentration of substrate (C) in water at reaction time (t) [37].
88
The main objective of this investigation is to assess the efficiency of solar
89
photocatalytic oxidation process using TiO2 versus TiO2/AC for degradation of
90
pharmaceuticals. Two antibiotics namely amoxicillin and ampicillin and two
91
prevalent drugs (diclofenac and paracetamol) were used as model substrates.
92
TiO2/AC catalyst characterization was carried out and factors affecting on the
93
photo degradation process such as pH and catalyst loading were extensively
94
studied. Furthermore, the pseudo-first order kinetic reaction was tested according
95
to the Langmuir–Hinshelwood model.
96 97
2. Materials and methods
98
2.1 Chemicals
99
Amoxicillin, ampicillin, paracetamol, and diclofenac were purchased from Glaxo
100
Smith Kline. The TiO2 and powdered activated carbon (AC) with bulk density of
101
0.37 g/cm3 in Nano scale was obtained form from Acros and Adwic respectively.
102
2.2 Catalyst preparation
103
Immobilization of TiO2 on activated carbon (AC) was executed according to the
104
high temperature impregnation method described by El-Sheikh et al [38]. A slurry
105
of 20 g TiO2 was heated and stirred with 300 ml of distilled water at a temperature
106
of 70˚C. AC was added with a ratio of TiO2 being 1:2 respectively. The mixture
107
was continuously stirred for 120 minutes at a temperature of 70˚ C. The dark black
108
color of AC and white color of TiO2 were observed at the beginning at which the
109
mixture was gradually changed into a gray color. This observation implies that the
5
110
interaction between AC and TiO2 certainly occurred. The mixture was settled for
111
15 minutes and then the supernatant was decanted and the precipitate was dried in
112
the oven at a temperature of 200˚ C for 12 hrs.
113
2.3 Photocatalysis experiments
114
Photocatalysis experiments were carried out using a solar reactor equipped with
115
compound parabolic collectors (CPCs). The reactor was placed at the city of Borg
116
Alarab, Egypt (Latitude 30°52’, Longitude 29°35’). The reactor consists of six
117
borosilicate tubes (0.36 m2) with a diameter of 2.5 cm and a length of 75 cm
118
mounted on curved polished aluminum sheets with radius of curvature 9.2 cm. The
119
module was fed with pharmaceutical mixtures in a closed cycle. The feed stock of
120
pharmaceuticals solution was continuously circulated in a closed cycle in the
121
module. A schematic diagram of the experimental set-up is shown in Fig 1. The
122
reactor was initially fed with 4 L of a pharmaceutical solution (50 mg/l) for a
123
period of 210 minutes. The first 30 minutes was used to assess the adsorption
124
process without illumination and 180 minutes for photocatalytic process. TiO2 or
125
TiO2/AC were used as catalysts. Effects of pH values, TiO2 and TiO2/AC dosage
126
were investigated. The pH value of the mixture was changed from 3 to 10 using
127
H2SO4, and NaOH (50%). TiO2 and TiO2/AC dosages varied from 0.2 to 0.8 and
128
from 0.4 to 1.6 g/L respectively. The solar irradiation was measured by Met, one
129
Portable Weather Station (Model Number 466A). The normalized illumination
130
time (t30w) was used to compare between photo-catalytic experiments instead of
131
exposure time (t). The normalized illumination time was calculated by the
132
following equations [16,39]:
133
t30w,n t30w,n1 tn UV / 30 Vi / Vt
(4)
134
6
135
tn tn – tn1
136
Where tn : contact time, UV : average solar ultraviolet radiation (W/m2) measured
137
during ∆tn, t30W : the normalized illumination time, which refers to a constant solar
138
UV power of 30W/m2 (typical solar UV power on a perfectly sunny day around
139
noon), Vt : the total reactor volume and Vi : the total irradiated volume.
140
2.4 Analytical methods
141
The concentrations of pharmaceuticals were quantified by Shimadzu HPLC using
142
C-18 phenomenex reverse phase column, degasser (20A5), pump (LC-20AT), and
143
prominences Diode Array Detector (SPD-M20A). The samples were filtered by
144
micro syringe filters (0.2 µm). The mobile phase was (60:40) 0.025M KH2PO4
145
buffer solution in ultrapure water and acetonitrile. The flow rate was 0.50 mL/min
146
and the temperature was 60˚C. For characterization of TiO2 deposition on activated
147
carbon, FTIR spectra were recorded on a VERTEX 70 spectrometer over the wave
148
number range 3800-400 cm-1 using KBr pellets for sample preparation. Scanning
149
electron microscope (SEM) images were taken with a JEOL 611. Pore size and
150
surface area of the catalyst were determined by Brunauer–Emmett–Teller (BET)
151
analysis using Belsorp-max automated apparatus using liquid N2 adsorption at a
152
temperature of 77 K.
153
2.5 Kinetic study
154
The model of Langmuir–Hinshelwood was used to relate the rate of degradation (r)
155
and concentration of substrate (C) in water at reaction time t. The model can be
156
expressed by the following equation [40];
157
r
dC Kr Kad C dt 1 Kad C
(2)
(3)
7
158
Where kr : the rate constant and Kad : the adsorption equilibrium constant. In the
159
process of photocatalysis when the adsorption is relatively weak like and/or the
160
reactant concentration is low, Equation (3) can be simplified to the pseudo- first
161
order kinetics with an apparent first-order rate constant kapp [36]:
162
C ln 0 Kr Kad t Kappt C
163
Where C0: is the initial concentration of pharmaceuticals.
(4)
164 165
3. Results and discussion
166
3.1 Characterization of TiO2/AC
167
The results of Brunauer–Emmett–Teller (BET) analysis for AC and TiO2/AC are
168
summarized in Table. 1. The specific surface area of AC was decreased from
169
1325.23 to 849.2 m2/g by impregnation of TiO2 into its surface, which certainly
170
attributed to the deposition of TiO2 on the pores and external surface of AC. The
171
decreasing of the surface area of the TiO2/AC can be interpreted in terms of the
172
calcinations at high temperature (200˚ C) which induced the formation of anatase
173
TiO2 on the surface and the pores of activated carbon [38]. In addition, total pore
174
volume of AC was slightly decreased from 0.8645 to 0.7804 cm3/g after the
175
deposition of TiO2. However, mean pore diameter of AC increased from 2.57 to
176
3.74 nm after the deposition process. Both processes mainly occurred due to the
177
partial pore collapse and shrinkage after impregnation at high temperature that may
178
lead to discrepancies in pore structure from micropores to mesopores [41].
179
Furthermore, the larger pore size is mainly caused by the formation of inter-
180
agglomeration particles [42].
8
181
The (SEM) images of naked activated carbon and the composite of TiO2/AC are
182
shown in Figs. 2a and b. The images show that the naked activated carbon
183
particulates have irregular shapes (Fig. 2a). Moreover, the surface of the activated
184
carbon particulates is rough with heterogeneous pores, which certainly indicates a
185
high prospect for TiO2 to be entrapped and adsorbed onto the surface and the pores
186
of activated carbon. For the TiO2/AC, The SEM image (Fig.2b) shows that TiO2
187
particulates are uniformly immobilized on the surface of activated carbon. It can be
188
seen that the supported TiO2 which appears in image by gray color covered most
189
of the surface of activated carbon, and also it is reported that some of TiO2 could
190
deposit in the mesopores and macrospores of activated carbon [29]. Since the
191
photocatalysis process strongly depends on light intensity, deposition of TiO2 on
192
the external surface of AC will undoubtedly provide more chance to be exhibited
193
to light and subsequently will improve the photocatalytic degradation process.
194
Moreover a high content TiO2 on the external surface of activated carbon is
195
favored to enhance and accelerate the photocatalytic activity of the catalyst [35].
196
The spectra of Fourier transform infrared spectroscopy (FTIR) spectra of AC, and
197
TiO2/AC are illustrated in Fig. 3. The spectrums revealed that the impregnation of
198
TiO2 with the activated carbon produced a broad peak from 400 to 800 cm-1 which
199
could be attributed to the formation of bulk Titania framework on the surface and
200
the pores of activated carbon [19]. This result indicated a good interaction between
201
the activated carbon surface and titanium dioxide. In addition, the peak at 1650 cm-
202
1
203
appeared in the spectrum of TiO2/AC. This shift was probably caused by the Ti-O-
204
C band owing to the electron affinity of carbon when using hydrothermal methods
205
in preparation of TiO2/AC [28]. The peak at 2382 cm-1 which refers to O–H
206
stretching [43] became smaller after TiO2 immobilization. Moreover, the band at
assigned to –OH vibration was shifted to 1585 cm-1. A new peak at 1165 cm-1
9
207
3400 cm-1 that assigned to –OH stretching [44] was disappeared in TiO2/AC
208
spectra.
209
3.2. Photocatalytic degradation by bare TiO2
210
Fig.4 depicts the efficiency of TiO2 photocatalytic degradation of pharmaceuticals
211
(amoxicillin, ampicillin, diclofenac, and paracetamol). The obtained results
212
indicated that the removal efficiencies of amoxicillin, ampicillin, diclofenac, and
213
paracetamol after 30 minutes without illumination were 5%, 4% 5% and 6% which
214
are considered very limited comparing to the removal in illumination period. The
215
removal of pharmaceuticals during the first 30 minutes was mainly due to
216
adsorption of pharmaceuticals on the catalyst active sites. The photocatalytic
217
degradation after the illumination is allowed was influenced by irradiation time as
218
shown in Fig 4. The major portion of pharmaceuticals was removed by TiO2
219
photocatalysis during the first 90 minutes of irradiation (86 % for amoxicillin, 72%
220
for ampicillin, 58% for diclofenac, and 40% for paracetamol). The higher
221
degradation rates at the first 90 minutes are attributed to the abundance of hydroxyl
222
radicals. In the second 90 minutes of irradiation the degradation rates were
223
diminished which resulted in final removal efficiency of 89 % for amoxicillin,
224
83% for ampicillin, 68% for diclofenac, and 57% for paracetamol. This can be due
225
to the exhausting of the active sites of the catalyst and hence the produced
226
hydroxyl radicals were completely consumed at the late stages of the reaction. The
227
difference in photocatalytic degradation efficiency from pharmaceutical to another
228
is attributed to the adsorbability of pharmaceutical molecules towards the active
229
sites of TiO2 where the hydroxyl radicals are available.
230
3.3. Photocatalytic degradation by TiO2/AC
231
The degradation of pharmaceuticals by TiO2/AC is shown in Fig. 5. The
232
elimination of pharmaceuticals in the dark process by TiO2/AC was higher than
10
233
bare TiO2 resulting in removal efficiencies of 17% for amoxicillin, 9 % for
234
ampicillin, 10% for diclofenac, and 11% for paracetamol. This indicates that the
235
adsorption capacity of TiO2 /AC is substantially higher than naked TiO2 as
236
expected[45]. During the first 90 minutes of irradiation high degradation rates of
237
pharmaceuticals were observed. This founding is due to the free surface of
238
activated carbon at early stage which led to higher adsorbability of the catalyst. In
239
addition, at early stage of the process there is abundance of hydroxyl radicals near
240
the surface of the catalyst. Nevertheless, the produced hydroxyl radicals are
241
completely consumed at the late stages of the reaction which diminished the
242
photocatalytic degradation rates as shown in Fig. 5. Complete degradation of
243
amoxicillin was attained after 120 minutes of irradiation. This was better than
244
naked TiO2 as 89% of amoxicillin was removed after 150 minutes of irradiation.
245
This indicates that TiO2/AC does not only attain higher degradation efficiency of
246
amoxicillin but also accelerate the photocatalytic process. Similar trends were
247
observed for the removal of ampicillin, diclofenac, and paracetamol. Apparently,
248
the immobilization process enhanced the reaction between the produced hydroxyl
249
radicals and the amoxicillin molecules on the surface of TiO2/AC because the
250
attraction of pharmaceutical molecules to the catalyst active sites has been
251
increased. Moreover, the variation in degradation efficiency of pharmaceuticals
252
can be attributed to the different affinity to the binding sites on the catalyst. The
253
enhancement of photocatalytic degradation of pharmaceuticals by using TiO2/AC
254
is in accordance with the finding of other researchers who examined the
255
immobilization of TiO2 on activated carbon for removal of different organic
256
compounds [30,32,46,47].
257
Comparing these results with our previous work for degradation of the same
258
pharmaceuticals by solar photo-Fenton process [1], it is found that photo-Fenton
259
process is more effective. Complete degradation of all pharmaceuticals was
11
260
attained after irradiation time ranged between 60 and 120 minutes. In addition,
261
there is no big difference in the estimated costs as shown in part 3.5. However,
262
there are some problems associated with photo-Fenton process. First, photo-Fenton
263
process is favored at lower pH (optimum pH≈3) which may cause some problems
264
such as corrosion of mechanical facilities and it needs neutralization stage. Second,
265
traces of iron remained in the treated effluent [48]. Third, considerable amount of
266
sludge is produced during Fenton process. On the other hand, there is no
267
considered sludge produced during photocatalysis process and the remained
268
amount of TiO2 is not harmful to the environment. For all these reasons,
269
photocatalysis may be preferred in spite of the lower efficiency.
270
3.3. Parameters affecting photocatalytic degradation
271
3.3.1. Effect of initial pH on degradation efficiency
272
The pH of the solution affects the surface charge of activated carbon, TiO2, and the
273
dissolved organic molecules. Subsequently adsorption, and photocatalysis process
274
are affected [26,49,50]. Fig. 6 shows the effect of initial pH on the degradation
275
efficiency of pharmaceuticals. Complete removal of amoxicillin and ampicillin
276
was achieved at pH 10. However, the removal efficiency was dropped at pH values
277
ranging from 3 to 5 as shown in Fig 6a and b. Similar was observed for diclofenac,
278
and paracetamol which the removal efficiencies were decreased from 82% and
279
70% at pH value of 10 to 60% and 58% at pH 3 respectively. The effect of pH on
280
degradation of pharmaceuticals can be explained in terms of the ionization state of
281
the TiO2 and the substrate. The surface charge of the activated carbon and the
282
loaded catalyst depends on the zero point of charge (pHpzc) and the pH of the
283
solution. The surface charge of the adsorbent is negative and its surface functional
284
group is protonated by the H+ ions from the dissolved matter in the solution at pH
285
˃ pHpzc,. On the contrary, at pH ˂ pHpzc, the surface charge of the adsorbent is
12
286
positive and the functional groups is deprotonated by the excess of OH- ions [51].
287
In literature [7] the zero point of charge of TiO2 is 6.4. Accordingly, increasing
288
the pH of the solution changed the surface charge of TiO2 from positive to
289
negative. The pHpzc of the activated carbon is reported to be between 3 and 7
290
regarding to the preparing method and the used material [43,45,52]. On the other
291
hand, amoxicillin has a negative charge when the pH is lower than 5 [53]. In the
292
acidic conditions, amoxicillin, free active sites of carbon and TiO2 particulates are
293
positively charged which led to repulsive forces between amoxicillin and the
294
catalyst which inhibited the degradation.
295
At alkaline conditions the catalyst and pharmaceuticals are negatively charged.
296
This also produces repulsive forces which detract the adsorption on the active sites
297
of the catalyst. The observed enhancement in degradation efficiency of amoxicillin
298
on higher pH could be attributed to the increasing of hydroxyl radicals production
299
in alkaline conditions because of the availability of hydroxyl ions production on
300
TiO2 surface which can be oxidized to form more hydroxyl radicals [7]. This
301
finding is in accordance with other researchers who investigated the effect of pH
302
on photocatalytic oxidation of pharmaceuticals [53–55].
303
3.3.2. Effect of catalyst loading
304
The effect of dosage of TiO2/AC on the removal efficiency of pharmaceuticals is
305
shown in Fig. 7a. The results obtained revealed that photocatalytic degradation
306
performance was substantially improved with increasing the amount of TiO2/AC
307
and reached a plateau at a dosage of 1.2 g/L. This finding is mainly due to the
308
increasing of active sites of activated carbon and TiO2 by providing a higher
309
amount of catalyst. Consequently, the production of electron-hole pairs on the
310
surface of TiO2 and the high reactive hydroxyl radicals was improved [56].
311
Increasing the dosage of TiO2/AC up to 1.6 g/L attained a slight improvement in
13
312
degradation process in spite of the increasing of the active sites. This finding can
313
be attributed to the decreasing of light penetration due to higher turbidity. Fig 7.b
314
depicts the effect of TiO2 loading on the removal of pharmaceuticals. Increasing
315
the amount of TiO2 substantially improved the degradation efficiency of
316
pharmaceuticals due to the enhancement of production of hydroxyl radicals.
317
However, the loading of TiO2 more than 0.6 g/L led to more turbidity of the
318
solution because TiO2 particulates are very fine. Subsequently, a smaller amount of
319
the TiO2 in the suspension was activated only near the reactor wall, where the
320
sunlight can penetrate [57]. Moreover, increasing the TiO2 loading may deactivate
321
the previously activated particulates by collision with ground-state catalysts.
322
Moreover, agglomeration and sedimentation of TiO2 may also occur under large
323
amount of loadings which leads to lower surface area [58].
324
3.4. Degradation kinetic studies
325
Fig.8 shows the linear relationship between ln (C0/C) and irradiation time. Kapp and
326
R2 were calculated for TiO2/AC and TiO2 which are illustrated in Table 2. The
327
photocatalytic degradation by TiO2/AC shows high reaction rates compared to the
328
TiO2 which confirms the enhancement of photocatalytic performance by
329
immobilization of TiO2 on activated carbon. Moreover the high correlation
330
coefficient values revealed that the photocatalytic degradation of the used
331
pharmaceuticals strictly followed Langmuir–Hinshelwood model.
332
3.5 Economic evaluation
333
The design and construction of industrial wastewater treatment plant are certainly
334
influenced by the efficiency of contaminants removal, and the costs of different
335
alternatives [59]. Estimation of construction and operation costs depends on the
336
optimization of operational conditions i.e., irradiation time and dosage of
337
chemicals [60].
14
338
In this investigation, capital and running costs of photocatalytic oxidation process
339
by TiO2 and TiO2/AC were assessed. The results obtained from the experimental
340
work were used to estimate the costs of treatment plant with a capacity of 30 m3/d
341
and contaminated of 100 mg/L of one pharmaceutical. The capacity (C ) of the
342
proposed wastewater treatment plant is estimated using equation (5) [61].
343
C Vt
tt tw D
5
344
Where Vt: volumetric treated wastewater in one year, tt: operation time for the
345
treatment plant facilities in one batch, tw: working time per day for wastewater
346
treatment plant, and D: the number of working days in a year. The ratio between
347
treatment time and working time was assumed 35% which corresponded to the
348
optimum irradiation time concluded from the experiments and the average solar
349
UV flux in Egypt. The ratio of irradiated volume to the total treatment plant
350
volume was assumed 75%, and the illumination area of the plant (Ap) is 4.5 m2
351
according to the volumetric rate of the wastewater.
352
Amortization costs of the investment (AMC) and operating costs (OC) per cubic
353
meter of liquid waste were considered for costs estimation. The amortization costs
354
were calculated taking into consideration the constructing materials and the
355
required equipment. The investment cost per year (I) is calculated according to the
356
illumination area of the treatment plant (Ap), and the treatment plant life time (L)
357
using equation (6) [61]:
358
I
ApCp L
6
359
Where Cp: the cost per one m2 of the illuminated surface in the plant. A value of
360
800 €/m2 is considered according to the costs of durable reflection surface,
15
361
borosilicate tubes, tanks, and other mechanical equipment. The amortization costs
362
per m3 is calculated by equation (7) [62]:
363
AMC
I Vt
7
364
The operating costs include maintenance, the reactants and the energy consumed.
365
The staff costs are not calculated in this estimation for the simplicity of the
366
calculations. In addition, the solar photocatalytic reactor is independent on
367
manpower [62]. The maintenance costs are assumed to be 2% of the yearly
368
investment according to previous studies [63,64].
369
including catalysts and pH adjustment reagents are calculated as the concentration
370
(Ci) (kg/m3) multiplied by the unit price (Pi) (€/kg). Prices of chemicals were taken
371
as the average values from different suppliers inside and outside of Egypt. The
372
prices of commercial TiO2 and powdered activated carbon for industrial use were
373
taken 2.3 €/kg and 0.45 €/kg respectively. The energy cost (EC) (€/m3) is
374
calculated concerning the required power for pumping the liquid waste in the
375
treatment plant by equation (8).
376
EC
EPti w D Vt
The costs of chemicals
8
377
Where E: the power for pumping the wastewater from the tank to the reactor, Pi:
378
the unit price of energy. It is assumed that the costs of energy is 0.12 €/kw.h
379
according to the rates in Egypt. The calculated treatment costs including
380
amortization costs (AMC) by using TiO2 and TiO2/AC are illustrated in Table 3.
381
According to the fixed volume of liquid waste and plant life cycle, the
382
amortization cost was 1.52 €/m3 for all the cases. Table 3 reveals that the variation
383
of operating costs mainly depend on the type and dosage of the catalyst. Moreover,
16
384
for all types of pharmaceuticals using TiO2/AC was more economic than using
385
TiO2 in terms of removal efficiency. For instance, the maximum removal
386
efficiency of amoxicillin by TiO2/AC was 100% and costs 3.19 €/m3. On the other
387
hand, the maximum removal efficiency of amoxicillin by TiO2 was 91% and costs
388
3.29 €/m3. This trend is similar to the trend of ampicillin, diclofenac, and
389
paracetamol as illustrated in table 3.
390 391
4. Conclusions
392
Solar photocatalytic degradation of four types of pharmaceuticals namely
393
amoxicillin, ampicillin, diclofenac, and paracetamol using TiO2 nano-particles
394
versus TiO2 immobilized on powdered activated carbon (TiO2/AC) was
395
investigated. The images of TiO2/AC taken by SEM revealed successful
396
impregnation of TiO2 on PAC. This was also confirmed by the FTIR spectra and
397
BET analysis for activated carbon and the prepared TiO2/AC. Complete removal
398
of amoxicillin and ampicillin was achieved by TiO2/AC after 120 and 180 minutes
399
of irradiation respectively. This was not the case for bare TiO2, where 89 and 83%
400
of amoxicillin and ampicillin were removed. Similar trends were observed for the
401
removal of diclofenac and paracetamol. The removal efficiency of diclofenac and
402
paracetamol were increased from 68 to 85% and from 57 to 70% respectively
403
using TiO2/AC. Photocatalytic degradation efficiency of pharmaceuticals was
404
strongly dependent on the pH values and dosage of the catalysts. The estimated
405
total costs to attain optimum removal of pharmaceuticals by TiO2/AC were 3.19
406
€/m3 while the total costs to attain optimum removal by bare TiO2 were 3.29 €/m3.
407
Based on these results it is recommended to use TiO2 immobilized on activated
408
carbon (AC) for removal of pharmaceuticals from industrial wastewater.
409
17
410
Acknowledgments
411
The authors wish to acknowledge Ms. Iman Abdelaal for the valuable revision of
412
this paper.
413
education which granted him a full PhD scholarship.
The first author is grateful for the Egyptian ministry of higher
414
18
414 415
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26
637
processes for wastewater treatment, J. Adv. Oxid. Technol. 11 (2008) 270–275.
638 639
27
640
Figure Caption
641
642 643
Fig. 1 Schematic diagram of the solar compound parabolic collectors reactor.
644 645 646 647 648 649 650
28
651 652
(a)
653
654 655
(b)
656
29
657
Fig. 2 Scanning electronic micrographs (SEM) of (a) PAC, (b) TiO2/AC.
658 659 660 661 662 663
664 665
Fig. 3 FTIR spectra of TiO2 and TiO2/AC catalysts.
666 667 668
30
669
670 671 672
Fig. 4 Degradation of pharmaceuticals by TiO2, Initial concentration of all pharmaceuticals = 50 mg/L, TiO2 dosage = 0.4 g/L.
673 674 675 676
31
677 678 679
Fig. 5 Degradation of pharmaceuticals by TiO2/AC, Initial concentration of all pharmaceuticals = 50 mg/L, TiO2/AC dosage = 1.2 g/L.
680 681 682
32
683 684 685 686
Fig. 6 Effect of initial pH on degradation of pharmaceuticals by photocatalysis, Initial concentration of all pharmaceuticals = 50 mg/L, TiO2/AC dosage = 1.2 g/L, (a) Amoxicillin, (b) Ampicillin, (c) Diclofenac, (d) Paracetamol
687
33
688 689 690 691
692 693 694 695
Fig. 7 Effect of catalyst dosage on Degradation of pharmaceuticals by photocatalysis, Initial concentration of all pharmaceuticals = 50 mg/L, Initial pH = 10, t30,w = 180 min, (a) by TiO2/AC, (b) by TiO2.
696
34
697
698 699 700 701 702
Fig. 8 Kinetic analysis for photocatalytic degradation of pharmaceuticals, Initial concentration of all pharmaceuticals = 50 mg/L, Initial pH = 10, (a) by TiO2/AC, (b) by TiO2.
703
35
704
Tables
705
Table. 1 Brunauer–Emmett–Teller (BET) analysis of AC and TiO2/AC Parameter
AC
TiO2/AC
Specific surface area SBET (m2/g)
1325.2
849.2
Total pore volume (cm3/g)
0.8645
0.7804
Mean pore diameter (nm)
2.57
3.74
706 707
36
708 709
Table 2. kinetic analysis by Langmuir–Hinshelwood model. Catalyst
TiO2/AC
TiO2
Pharmaceutical
Kapp
R2
Amoxicillin
0.037
0.997
Ampicillin
0.022
0.984
Diclofenac
0.010
0.973
Paracetamol
0.006
0.903
Amoxicillin
0.013
0.830
Ampicillin
0.011
0.955
Diclofenac
0.005
0.898
Paracetamol
0.004
0.943
710 711 712 713 714 715 716 717 718 719 720 721 722
37
723
Table 3. Costs estimation for TiO2/AC and TiO2 solar photocatalysis TiO2 dose (mg/L)
AC dose
TiO2/AC
133
TiO2/AC
Catalyst
Operating Total costs costs (€/m3)
(€/m3)
267
0.81
2.33
267
533
1.24
2.76
TiO2/AC
400
800
1.67
3.19
TiO2
200
0
0.85
2.37
TiO2
400
0
1.31
2.83
TiO2
600
0
1.77
3.29
Removal Pharmaceutical efficiency (%) Amoxicillin 62 Ampicillin 57 Diclofenac 51 Paracetamol 43 Amoxicillin 87 Ampicillin 84 Diclofenac 73 Paracetamol 63 Amoxicillin 100 Ampicillin 100 Diclofenac 85 Paracetamol 70 Amoxicillin 52 Ampicillin 55 Diclofenac 43 Paracetamol 40 Amoxicillin 88 Ampicillin 84 Diclofenac 64 Paracetamol 57 Amoxicillin 91 Ampicillin 89 Diclofenac 75 Paracetamol 63
724 725 726 727
38