- Email: [email protected]
SiO2
Influence of temperature on hydroxylation of benzene to phenol using molecular oxygen catalyzed by V/SiO 2 Chao Guo, Weidong Du, Gang Chen, Lei Shi, Qi Sun PII: DOI: Reference:
S1566-7367(13)00101-5 doi: 10.1016/j.catcom.2013.03.018 CATCOM 3443
To appear in:
Catalysis Communications
Received date: Revised date: Accepted date:
18 January 2013 16 March 2013 20 March 2013
Please cite this article as: Chao Guo, Weidong Du, Gang Chen, Lei Shi, Qi Sun, Influence of temperature on hydroxylation of benzene to phenol using molecular oxygen catalyzed by V/SiO2 , Catalysis Communications (2013), doi: 10.1016/j.catcom.2013.03.018
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.
ACCEPTED MANUSCRIPT Influence of temperature on hydroxylation of benzene
RI P
T
to phenol using molecular oxygen catalyzed by V/SiO2
SC
Chao Guo, Weidong Du, Gang Chen, Lei Shi, Qi Sun*
Institute of Chemistry for Functionalized Materials, Faculty of Chemistry and
MA NU
Chemical Engineering, Liaoning Normal University, Dalian 116029, Liaoning, China
Fax: +86-0411-82156989
ED
Tel: +86-0411-82159069
CE
Abstract
PT
E-mail : [email protected] (Qi Sun)
AC
Effect of temperature on hydroxylation of benzene to phenol with molecular oxygen as an oxidant was studied over V/SiO2 using different reductants. The V/SiO2 with highly dispersed vanadium species was prepared by a sol-gel process and characterized by diffuse reflectance UV-vis and ESR. This work shows that the onset temperature range of benzene hydroxylation and the temperature reaching the maximum phenol yield differ corresponding to each reductant. The reducing capacity of reductant can be showed by changing temperature and affects, in turn, benzene conversion, product selectivity, and the amount of leaching of V species.
1
ACCEPTED MANUSCRIPT Keywords: Benzene; hydroxylation; molecular oxygen; reductant; phenol
RI P
T
1. Introduction
Direct oxidation of benzene to phenol without byproducts is an attractive
SC
and challenging field from an economical and environmental point of view. A variety of oxygen sources such as O2 [1], H2O2 [2], and N2O [3] are used for this
MA NU
reaction. Among these oxygen sources, using the activation of O2 as an oxidant, many catalysts can efficiently catalyze the oxidation of benzene to phenol, but the reaction is truly catalytic only in the presence of a reductant able to recycle
ED
the oxidized catalyst. In 1954, Udenfriend et al. [4] first reported the oxidation
PT
of aromatics to produce phenol using the complex ferric sulfate-EDTA as a catalyst with O2 and ascorbic acid as the oxidant and reductant, respectively.
CE
From then on many reductants were tested to find a substitute for ascorbic acid.
AC
Masumoto et al. [5] developed seven different reductants over V/Al2O3 at 30 oC using O2 as oxidant, and concluded that all of reductants studied could not efficiently substitute ascorbic acid. Similarly, Battistel et al. [6] tested seven reductants at 50 oC over VCl3. Miyahara et al [7] studied eight reductants at 30 o
C over CuO-Al2O3. And they found that ascorbic acid was still the best
reductant. Thus,as reported in the current literature, the method for assessing different reductants is at the identical temperature over a catalyst in hydroxylation of benzene with O2. One critical parameter that influences the characteristic of a reductant should be reaction temperature. Therefore, we
2
ACCEPTED MANUSCRIPT decided to carry out a study on the effect of temperature on hydroxylation of benzene with different reductants, with the aim of providing a method to select
RI P
T
an effective reductant for hydroxylation of benzene using O2 as oxidant. Furthermore, vanadium compounds have been reported to be an active catalyst
SC
for phenol formation by liquid-phase catalyzed benzene oxidation using O2 as the oxidant [5, 6, 8]. Herein, a V/SiO2 xerogel was used to screen a suitable
MA NU
reductant.
2. Experimental
ED
2.1. Catalysts preparation
PT
The preparation of V/SiO2 was as follows: 18.61 cm3 of tetraethoxysilane (Tianjin Kermel Chemical Reagent Co. Ltd, AR grade) was mixed with 19.44 cm 3
CE
ethanol under stirring to form solution A. Solution B was prepared by dissolving
AC
NH4VO3 (0.5740g) (Tianjin Tianhe Chemical Reagent Factory, AR grade) and citric acid monohydrate (4.0114g) (Tianjin Beifang Tianyi Chemical Reagent Factory, AR grade) in 24 cm3 deionized water. Solution B was then added dropwise into solution A under stirring at room temperature followed by aging at 50 oC, drying at 110 oC for 20 h and calcining at 500 oC for 4 h. The vanadium loading per unit mass of the SiO2 matrix was 0.98mmol/g.
2.2. Catalyst Characterization Diffuse reflectance UV-vis spectra were recorded in the range of 200-900 nm on
3
ACCEPTED MANUSCRIPT a JASCO Corp V-550 spectrophotometer. The ESR spectrometer was recorded at room temperature with a Bruker A 200 spectrometer. The UV-vis spectra of H2O2
RI P
T
formed in the reaction solution were measured by a Shimazu Model UV-240 spectrophotometer. Vanadium content was determined by inductively coupled plasma
SC
(ICP) on a Perkin Elmer Plasma 2000. 2.3. Catalytic Tests
MA NU
The catalytic experiments were carried out in a 75 ml steel autoclave. The optimized reaction conditions were as follows: the catalyst (0.1 g), 10 cm3 of aqueous acetic acid solvent, 1 cm3 of benzene (11.3 m mol) and reductant (3
ED
mmol) were added to the reactor and stirred by a magnetic stirrer for 10 h under
PT
1 MPa of O2. After the reaction, the products were analyzed using Agilent-6890 gas chromatograph equipped with an FID using HP-5 capillary column (30
AC
CE
m×0.32 mm×0.25 μ m) and N2 as the carrier gas.
3. Results and Discussion
3.1. Influence of temperature on hydroxylation of benzene We assessed the reductants at different reaction temperatures with V/SiO2 as a catalyst, and the results are summarized in Table 1. Each reductant corresponds to two temperatures. “a” is the temperature of reaching the maximum phenol yield, and “b” is the onset temperature range of hydroxylation of benzene. Beginning at 20 oC, ascorbic acid was the only one found to function
4
ACCEPTED MANUSCRIPT as an effective reductant, and the phenol yield was 6.2% with selectivity of 100%. At the same temperature (20 oC), no activity was observed with other
RI P
T
reductants investigated. When increasing the temperature from 20 to 40 oC, the onset of the catalytic reaction was observed using hydroquinone as the reductant.
SC
However, benzoquinone was found to be the only product and 2.3% benzene conversion was detected at 40 oC. Also, with benzoquinone at 40 oC, similar
MA NU
phenomenon was observed. Further increasing temperature from 40 to 60 oC, with pyrocatechol as the reductant the formation of phenol was observed. The phenol selectivity was 67.5% and remaining products were benzoquinone
ED
(5.5%), hydroquinone (7.8%) and other products (19.2%) at 60 oC. Using oxalic
PT
acid or glucose as the reductant, the direct oxygenation of benzene began in higher temperature range. The yields of phenol were 3.3% using oxalic acid at
CE
90 oC and 4.9% using glucose at 100 oC, respectively. Hence, ascorbic acid is the
AC
best reductant at lower temperatures. With each reductant the phenol yield gradually increased with increasing temperature. The maximum phenol yields were reached at different temperatures (Table1). The maximum phenol yield decreased in the following order: hydroquinone (120 oC) > ascorbic acid (90 oC) > oxalic acid (140 oC) > benzoquinone (120 oC) > pyrocatechol (120 oC) > glucose (120 oC). Thus, hydroquinone is more effective reductant at higher reaction temperatures. This suggests that elevated reaction temperature is presumably required to show the reducing capacity of reductant. Without the reductant the V/SiO2 showed no activity for phenol formation, indicating
5
ACCEPTED MANUSCRIPT that the presence of the reductant is essential. Benzoquinone is also an effective reductant (Figure 1A). The controlled
RI P
T
experiment indicated that benzoquinone can react with V5+ from the V/SiO2 form hydroquinone and V4+ at > 80 oC. Benzoquinone and hydroquinone may be
SC
transformed into each other in the catalyst system (Figure 1B). Similar phenomenon was also observed in other catalyst systems [9]. With either of reductants the catalyst
MA NU
system showed the similar activity and 100% phenol selectivity at 120oC. The percentage of leaching of V was obviously different with different reductants (Table 2). For example, with hydroquinone as the reductant the
ED
percentage of the leaching of V decreased from 88.7% at 40 oC to 32.5% at 120 oC.
PT
The difference in leaching of V may be attributed to the difference in the nature of reductant, such as coordination to the vanadium center and the reducing capacity.
CE
Effect of the leaching of vanadium species on the yield of phenol was
AC
investigated using the filtrate and the spend catalyst, respectively, at optimization temperature corresponding to each reductant. With the filtrates, yields of phenol were 1.8% for hydroquinone, 2.5% for ascorbic acid, 1.9% for oxalic acid, 1.3% for pyrocatechol and 2.4% for glucose, respectively. Furthermore, unsupported V2O5 (NH4VO3) was also used as the catalyst. Yields of phenol were 1.5%-5% (5% for ascorbic acid) using the five reductants mentioned above. Using the spend V/SiO2, yields of phenol using hydroquinone, ascorbic acid, oxalic acid, pyrocatechol and glucose as the reductant were 9.6%, 7.5%, 5.2%, 7.8% and 6.1%, respectively. The decrease of phenol yields may be due to the V leaching. Obviously, the
6
ACCEPTED MANUSCRIPT heterogeneous catalysis plays a major role in the reaction.
RI P
T
3.2. Characterization of catalyst
The colorimetric reaction was performed in a glass flask. A mixture of V/SiO2,
SC
reductant, benzene, and aqueous acetic acid was heated under a N2 atmosphere and the temperature was increased from 20 to 150 oC. With ascorbic acid as the reductant,
MA NU
the surface of the V/SiO2 in the solution at 20 oC gave a green color, corresponding to V4+ species [10]. With other reductants the surface of the V/SiO2 also showed green color at higher temperatures, i.e. 30, 60, 80 and 100 oC with hydroquinone,
ED
pyrocatechol, oxalic acid and glucose, respectively. The change in color caused by
each reductant.
PT
variation in temperature accords with the onset temperature range corresponding to
CE
The presence of V4+ species in the V/SiO2 can be confirmed by the diffuse
AC
reflectance UV-vis and ESR spectra. Taking hydroquinone as example, the results of the characterization of the fresh and hydroquinone-reduced V/SiO2 are shown in Figure 2 and 3. In Figure 2, for fresh V/SiO2, the bands in the range of 250-300 nm should be assigned to charge transfer transitions involving oxygen and vanadium (V) in tetrahedral coordination, present as isolated species [11]. The absorption band in the region of 333-500 nm is associated with the lower-energy charge transfer of O-V5+ electron transfer for octahedral coordination [12]. When fresh V/SiO2 was reduced in hydroquinone at 40 oC for 2h, two bands at around 250 and 282 nm are observed. The band at 250 nm was assigned to an isolated tetrahedral V 5+ [11]. The
7
ACCEPTED MANUSCRIPT band at 282 nm is attributed to the lower-energy change transfer of O-V4+electron transfer [13]. For the fresh V/SiO2, the eight-line spectrum with very low intensity
RI P
T
was observed (Figure 3), which is attributed to vanadyl VIVO (d1) species [6, 14]. After reduction, the signal becomes well-resolved and the intensity of the signal
SC
increases, which indicates the V4+ complexes appear to be isolated and highly dispersed [15]. Thus, the vanadium species on the surface of the V/SiO2 are highly
MA NU
dispersed.
To gain insight into the reaction mechanism, the formation of H2O2 was directly measured via UV-vis spectroscopy of the reaction solution with different reductants.
ED
The results in Figure 4 indicated that the appearance of an absorption peak at ca.220
PT
nm with each reductant (curves b-f), this absorption peak based on H2O2 [16]. Without reductant, the absorption peak at 220 nm was silent (curve g). Therefore, the present
CE
V/SiO2 catalytic system using both O2 and reductant is considered to proceed via a
AC
reaction scheme similar to a Fenton type reaction [16-18]: V5+ species in the V/SiO2 was reduced to V4+ species by reductant. H2O2 was formed by the reaction of the V4+species with O2 and a proton. Hydroxyl radicals produced by the reaction of H2O2 with the V4+ species and protons are considered to participate in the phenol formation.
4. Conclusions In spite of the differences in the reduction properties, all the tested reductants were found to exhibit excellent reactivity for hydroxylation of benzene at the selective temperature. It was suggested that screening reductant should be carried out
8
ACCEPTED MANUSCRIPT at different temperatures. With each reductant the selectivity to phenol can be up to 100% corresponding to the maximum benzene conversion. Also, benzoquinone is also
RI P
T
an effective reductant, and benzoquinone and hydroquinone may be transformed into each other. With each reductant, H2O2 was formed and hydroxylation scheme was
SC
similar to a Fenton type reaction.
MA NU
Acknowledgement
This work was supported by the National Natural Science Foundation of China
ED
(21173110)
References
PT
[1] H. Yang, J. Q. Chen, J. Li, Y. Lv, S. Gao, Applied Catalysis A: General 415 (2012)
CE
22-28.
[2] P. P. Zhao, L. Yan, J. Wang, Chemical Engineering Journal 204 (2012) 72-78.
AC
[3] A. J. J. Koekkoek, H. C. Xin, Q. H. Yang, C. Li, E. J. M. Hensen, Microporous and Mesoporous Materials 145 (2011) 172-181. [4] S. Udenfriend, C. T. Clark, J. Axelrod, B. B. Brodie Journal of Biological Chemistry, 208 (1954) 731-739. [5] Y. Masumoto, R. Hamada, K. Yokota, S. Nishiyama, S.Tsuruya Journal of Molecular Catalysis A: Chemical
184 (2002) 215-222.
[6] E. Battistel, R.Tassinari, M. Fornaroli, L. Bonoldi Journal of Molecular Catalysis A: Chemical 202(2003) 107-115. [7] T. Miyahara, H. Kanzaki, R. Hamada, S. Kuroiwa, S. Nishiyama, S. Tsuruya, Journal of Molecular Catalysis A: Chemical 176 (2001) 141-150. [8] H. Q. Ge, Y. Leng, C. J. Zhou, J. Wang, Catalysis Letters 124 (2008) 324-329. [9] A. Hanyu, E. Takezawa, S. Sakaguchi, Y. Ishii, Tetrahedron Letters 39 (1998) 9
ACCEPTED MANUSCRIPT 5557-5560. [10] K. Lemke, H. Ehrich, U. Lohse, H. Berndt, K. Jähnisch, Applied Catalysis A:
T
General 243 (2003) 41-51.
RI P
[11] S. Dzwigaj, M. Matsuoka, M.Anpo, M. Che, The Journal of Physical Chemistry.
SC
B 104 (2000) 6012-6020.
[12] Z. H. Luan, J. Xu, H.Y. He, J. Klinowski, L. Kevan, The Journal of Physical
MA NU
Chemistry 100 (1996) 19595-19602.
[13] G. Centi, S. Perathoner, F. Trifiro, A. Aboukais, C. F. Aissi, M. Guelton, The Journal of Physical Chemistry 96 (1992) 2617-2629. [14] C. W. Lee, W. J. Lee, Y. K. park, S. E. park, Catalysis Today 61 (2000) 137-141.
ED
[15] C. H. Lee, T. S. Lin, C. Y. Mou, The Journal of Physical Chemistry C 111 (2007) 3873-3882.
PT
[16] M. Ishida, Y. Masumoto, R. Hamada, S. Nishiyama, S. Tsuruya, M. Masai,
CE
Journal of the Chemical Society, Perkin Transactions 2 (1999) 847-853. [17] X. H. Gao, J. Xu, Catalysis Letters 111 (2006) 203-205.
AC
[18] A. Kunai, S. Hata, S. Ito, K. Sasaki, Journal of the American Chemical Society 108 (1986) 6012-6016.
List of Tables
Table 1 Effect of various reductants on hydroxylation of benzene over V/SiO2 a
the temperature of reaching the maximum phenol yield
b
the onset temperature range of hydroxylation of benzene
10
ACCEPTED MANUSCRIPT c
benzoquinone selectivity is 100%
Reaction conditions: 0.1 g V/SiO2 , 1 ml benzene, 3 m mol reductant, 7 ml acetic
RI P
T
acid, 3 ml H2O, 1 MPa O2 , and 10 h. All of oxidation reactions were carried out
SC
with fresh catalyst each time.
MA NU
Table 2 Influence of reaction temperature on the percentage of V leaching Reaction conditions are the same as table 1
The percentage of V leaching equals the difference of V contents between fresh and
List of Figures
AC
CE
PT
ED
spent V/SiO2 divided by V content of fresh V/SiO2.
Figure 1 Effect of benzoquinone (A) or hydroquinone (B) as the reductant on the oxidation of benzene to phenol over V/SiO2 a. Selectivity to phenol (%) b. Conversion of benzene (%) c. Selectivity to benzoquinone (%) Reaction conditions are the same as table 1
11
ACCEPTED MANUSCRIPT Figure 2 Diffuse reflectance UV-vis spectra of (a) fresh V/SiO2 ; (b)
RI P
T
hydroquinone–reduced V/SiO2
SC
Figure 3 ESR spectra of (a) fresh V/SiO2;(b) hydroquinone–reduced V/SiO2
Figure 4 UV-vis spectra of H2O2 formed from the reaction solution with
MA NU
different reductants
a. aqueous solution of H2O2 (8×10-6 mol/l)
b. glucose ; c. pyrocatechol ; d. hydroquinone; e. ascorbic acid;
ED
f. oxalic acid ;
PT
g. without reductant
AC
CE
Reaction conditions are the same as table 1
12
ACCEPTED MANUSCRIPT
80
T
80
RI P
a
60
60
40
40
20
20
b
MA NU
0 40
60
Conversion of benzene (%)
100
A
SC
Selectivity to phenol(%)
100
80
100
0
120
o
Temperature ( C)
PT
60
60
40
40
a
20
b
20
0
Conversion of benzene
AC
80
c
CE
Selectivity (%)
80
100
B
ED
100
0 40
60
80
100
120
140
o
Temperature ( C)
Figure1 Effect of benzoquinone (A) or hydroquinone (B) as the reductant on the oxidation of benzene to phenol over V/SiO2 a. Selectivity to phenol (%);
b. Conversion of benzene (%);
c. Selectivity to benzoquinone (%) Reaction conditions are the same as table 1
13
T
ACCEPTED MANUSCRIPT
RI P
1.0
(a)
SC
(b) 0.6
MA NU
Absorbance
0.8
0.4
PT 300
400
500
600
700
800
900
Wavelength (nm)
AC
CE
0.0 200
ED
0.2
Figure 2 Diffuse reflectance UV-vis spectra of (a) fresh V/SiO2;(b) hydroquinone-reduced V/SiO2.
14
ACCEPTED MANUSCRIPT
RI P
T
(a)
MA NU
SC
(b)
2000
3000
4000
5000
ED
Gauss
PT
Figure 3 ESR spectra of (a) fresh V/SiO2;(b) hydroquinone-reduced
AC
CE
V/SiO2.
15
RI P
T
ACCEPTED MANUSCRIPT
a g
SC
Absorbance
b c
MA NU
d e
250
300
350
400
wavelength(nm)
CE
PT
200
ED
f
AC
Figure 4 UV-vis spectra of H2O2 formed from the reaction solution with different reductants a. aqueous solution of H2O2 (8×10-6 mol/L) b. glucose ; c. pyrocatechol ; d. hydroquinone e. ascorbic acid; f. oxalic acid ; g. without reductant Reaction conditions are the same as table 1
16
ACCEPTED MANUSCRIPT
Table 1
Ascorbic acid
40 (20-40)b
Hydroquinone
Phenol yield (%) 6.2 13.7 0
100 0.0c
14.3 0
100 67.5
10.0 9.0
100 100
9.7 3.3
100 100
10.1 4.9
100
9.5
the onset temperature range of hydroxylation of benzene
AC
c
CE
PT
ED
MA NU
120 a 14.3 40 11.8 b Benzoquinone (20-40) 120 a 10.0 60 13.4 Pyrocatechol (40-60)b 120 a 9.7 90 3.3 b Oxalic acid (60-90) 140 a 10.1 100 4.9 b Glucose (90-100) 120 a 9.5 a the temperature of reaching the maximum phenol yield b
Phenol selectivity (%) 100 100 0.0c
RI P
Reductant
Benzene conversion (%) 6.2 13.7 2.3
SC
Reaction temperature (oC) 20 90a
T
Effect of various reductants on hydroxylation of benzene over V/SiO2
benzoquinone selectivity is 100%
Reaction conditions: 0.1 g V/SiO2 (5 wt%), 1 ml benzene, 3 m mol reducing agent, 7 ml acetic acid, 3 ml H2O, 1 MPa O2 , and 10 h. All of oxidation reactions were carried out with fresh catalyst each time.
17
ACCEPTED MANUSCRIPT Table 2 Influence of reaction temperature on the percentage of V leaching Reaction temperature (oC)
Leaching of V (%)
T
Reductant
20
77.4
RI P
Ascorbic acid 90
Hydroquinone 120
MA NU
60
SC
40
Pyrocatechol
32.5 51.0 19.5
90
89.3
140
30.6
100
41.6
120
87.1
PT
Glucose
88.7
120
ED
Oxalic acid
63.4
Reaction conditions are the same as table 1.
CE
The percentage of V leaching equals the difference of V contents between fresh and
AC
spent V/SiO2 divided by V content of fresh V/SiO2.
18
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
MA NU
SC
RI P
T
Graphical abstract
19
ACCEPTED MANUSCRIPT Highlights 1. V/SiO2 with highly dispersed vanadium species was prepared by sol-gel process
T
2. Studying the effect of temperature on benzene oxidation with O2 over V/SiO2
RI P
3. Reducing capacity of reductant can be showed by changing temperature 4. Both of reductants benzoquinone and hydroquinone can be interconvertible
AC
CE
PT
ED
MA NU
SC
5. Presenting 100% selectivity to phenol with each reductant
20
S1566-7367(13)00101-5 doi: 10.1016/j.catcom.2013.03.018 CATCOM 3443
To appear in:
Catalysis Communications
Received date: Revised date: Accepted date:
18 January 2013 16 March 2013 20 March 2013
Please cite this article as: Chao Guo, Weidong Du, Gang Chen, Lei Shi, Qi Sun, Influence of temperature on hydroxylation of benzene to phenol using molecular oxygen catalyzed by V/SiO2 , Catalysis Communications (2013), doi: 10.1016/j.catcom.2013.03.018
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.
ACCEPTED MANUSCRIPT Influence of temperature on hydroxylation of benzene
RI P
T
to phenol using molecular oxygen catalyzed by V/SiO2
SC
Chao Guo, Weidong Du, Gang Chen, Lei Shi, Qi Sun*
Institute of Chemistry for Functionalized Materials, Faculty of Chemistry and
MA NU
Chemical Engineering, Liaoning Normal University, Dalian 116029, Liaoning, China
Fax: +86-0411-82156989
ED
Tel: +86-0411-82159069
CE
Abstract
PT
E-mail : [email protected] (Qi Sun)
AC
Effect of temperature on hydroxylation of benzene to phenol with molecular oxygen as an oxidant was studied over V/SiO2 using different reductants. The V/SiO2 with highly dispersed vanadium species was prepared by a sol-gel process and characterized by diffuse reflectance UV-vis and ESR. This work shows that the onset temperature range of benzene hydroxylation and the temperature reaching the maximum phenol yield differ corresponding to each reductant. The reducing capacity of reductant can be showed by changing temperature and affects, in turn, benzene conversion, product selectivity, and the amount of leaching of V species.
1
ACCEPTED MANUSCRIPT Keywords: Benzene; hydroxylation; molecular oxygen; reductant; phenol
RI P
T
1. Introduction
Direct oxidation of benzene to phenol without byproducts is an attractive
SC
and challenging field from an economical and environmental point of view. A variety of oxygen sources such as O2 [1], H2O2 [2], and N2O [3] are used for this
MA NU
reaction. Among these oxygen sources, using the activation of O2 as an oxidant, many catalysts can efficiently catalyze the oxidation of benzene to phenol, but the reaction is truly catalytic only in the presence of a reductant able to recycle
ED
the oxidized catalyst. In 1954, Udenfriend et al. [4] first reported the oxidation
PT
of aromatics to produce phenol using the complex ferric sulfate-EDTA as a catalyst with O2 and ascorbic acid as the oxidant and reductant, respectively.
CE
From then on many reductants were tested to find a substitute for ascorbic acid.
AC
Masumoto et al. [5] developed seven different reductants over V/Al2O3 at 30 oC using O2 as oxidant, and concluded that all of reductants studied could not efficiently substitute ascorbic acid. Similarly, Battistel et al. [6] tested seven reductants at 50 oC over VCl3. Miyahara et al [7] studied eight reductants at 30 o
C over CuO-Al2O3. And they found that ascorbic acid was still the best
reductant. Thus,as reported in the current literature, the method for assessing different reductants is at the identical temperature over a catalyst in hydroxylation of benzene with O2. One critical parameter that influences the characteristic of a reductant should be reaction temperature. Therefore, we
2
ACCEPTED MANUSCRIPT decided to carry out a study on the effect of temperature on hydroxylation of benzene with different reductants, with the aim of providing a method to select
RI P
T
an effective reductant for hydroxylation of benzene using O2 as oxidant. Furthermore, vanadium compounds have been reported to be an active catalyst
SC
for phenol formation by liquid-phase catalyzed benzene oxidation using O2 as the oxidant [5, 6, 8]. Herein, a V/SiO2 xerogel was used to screen a suitable
MA NU
reductant.
2. Experimental
ED
2.1. Catalysts preparation
PT
The preparation of V/SiO2 was as follows: 18.61 cm3 of tetraethoxysilane (Tianjin Kermel Chemical Reagent Co. Ltd, AR grade) was mixed with 19.44 cm 3
CE
ethanol under stirring to form solution A. Solution B was prepared by dissolving
AC
NH4VO3 (0.5740g) (Tianjin Tianhe Chemical Reagent Factory, AR grade) and citric acid monohydrate (4.0114g) (Tianjin Beifang Tianyi Chemical Reagent Factory, AR grade) in 24 cm3 deionized water. Solution B was then added dropwise into solution A under stirring at room temperature followed by aging at 50 oC, drying at 110 oC for 20 h and calcining at 500 oC for 4 h. The vanadium loading per unit mass of the SiO2 matrix was 0.98mmol/g.
2.2. Catalyst Characterization Diffuse reflectance UV-vis spectra were recorded in the range of 200-900 nm on
3
ACCEPTED MANUSCRIPT a JASCO Corp V-550 spectrophotometer. The ESR spectrometer was recorded at room temperature with a Bruker A 200 spectrometer. The UV-vis spectra of H2O2
RI P
T
formed in the reaction solution were measured by a Shimazu Model UV-240 spectrophotometer. Vanadium content was determined by inductively coupled plasma
SC
(ICP) on a Perkin Elmer Plasma 2000. 2.3. Catalytic Tests
MA NU
The catalytic experiments were carried out in a 75 ml steel autoclave. The optimized reaction conditions were as follows: the catalyst (0.1 g), 10 cm3 of aqueous acetic acid solvent, 1 cm3 of benzene (11.3 m mol) and reductant (3
ED
mmol) were added to the reactor and stirred by a magnetic stirrer for 10 h under
PT
1 MPa of O2. After the reaction, the products were analyzed using Agilent-6890 gas chromatograph equipped with an FID using HP-5 capillary column (30
AC
CE
m×0.32 mm×0.25 μ m) and N2 as the carrier gas.
3. Results and Discussion
3.1. Influence of temperature on hydroxylation of benzene We assessed the reductants at different reaction temperatures with V/SiO2 as a catalyst, and the results are summarized in Table 1. Each reductant corresponds to two temperatures. “a” is the temperature of reaching the maximum phenol yield, and “b” is the onset temperature range of hydroxylation of benzene. Beginning at 20 oC, ascorbic acid was the only one found to function
4
ACCEPTED MANUSCRIPT as an effective reductant, and the phenol yield was 6.2% with selectivity of 100%. At the same temperature (20 oC), no activity was observed with other
RI P
T
reductants investigated. When increasing the temperature from 20 to 40 oC, the onset of the catalytic reaction was observed using hydroquinone as the reductant.
SC
However, benzoquinone was found to be the only product and 2.3% benzene conversion was detected at 40 oC. Also, with benzoquinone at 40 oC, similar
MA NU
phenomenon was observed. Further increasing temperature from 40 to 60 oC, with pyrocatechol as the reductant the formation of phenol was observed. The phenol selectivity was 67.5% and remaining products were benzoquinone
ED
(5.5%), hydroquinone (7.8%) and other products (19.2%) at 60 oC. Using oxalic
PT
acid or glucose as the reductant, the direct oxygenation of benzene began in higher temperature range. The yields of phenol were 3.3% using oxalic acid at
CE
90 oC and 4.9% using glucose at 100 oC, respectively. Hence, ascorbic acid is the
AC
best reductant at lower temperatures. With each reductant the phenol yield gradually increased with increasing temperature. The maximum phenol yields were reached at different temperatures (Table1). The maximum phenol yield decreased in the following order: hydroquinone (120 oC) > ascorbic acid (90 oC) > oxalic acid (140 oC) > benzoquinone (120 oC) > pyrocatechol (120 oC) > glucose (120 oC). Thus, hydroquinone is more effective reductant at higher reaction temperatures. This suggests that elevated reaction temperature is presumably required to show the reducing capacity of reductant. Without the reductant the V/SiO2 showed no activity for phenol formation, indicating
5
ACCEPTED MANUSCRIPT that the presence of the reductant is essential. Benzoquinone is also an effective reductant (Figure 1A). The controlled
RI P
T
experiment indicated that benzoquinone can react with V5+ from the V/SiO2 form hydroquinone and V4+ at > 80 oC. Benzoquinone and hydroquinone may be
SC
transformed into each other in the catalyst system (Figure 1B). Similar phenomenon was also observed in other catalyst systems [9]. With either of reductants the catalyst
MA NU
system showed the similar activity and 100% phenol selectivity at 120oC. The percentage of leaching of V was obviously different with different reductants (Table 2). For example, with hydroquinone as the reductant the
ED
percentage of the leaching of V decreased from 88.7% at 40 oC to 32.5% at 120 oC.
PT
The difference in leaching of V may be attributed to the difference in the nature of reductant, such as coordination to the vanadium center and the reducing capacity.
CE
Effect of the leaching of vanadium species on the yield of phenol was
AC
investigated using the filtrate and the spend catalyst, respectively, at optimization temperature corresponding to each reductant. With the filtrates, yields of phenol were 1.8% for hydroquinone, 2.5% for ascorbic acid, 1.9% for oxalic acid, 1.3% for pyrocatechol and 2.4% for glucose, respectively. Furthermore, unsupported V2O5 (NH4VO3) was also used as the catalyst. Yields of phenol were 1.5%-5% (5% for ascorbic acid) using the five reductants mentioned above. Using the spend V/SiO2, yields of phenol using hydroquinone, ascorbic acid, oxalic acid, pyrocatechol and glucose as the reductant were 9.6%, 7.5%, 5.2%, 7.8% and 6.1%, respectively. The decrease of phenol yields may be due to the V leaching. Obviously, the
6
ACCEPTED MANUSCRIPT heterogeneous catalysis plays a major role in the reaction.
RI P
T
3.2. Characterization of catalyst
The colorimetric reaction was performed in a glass flask. A mixture of V/SiO2,
SC
reductant, benzene, and aqueous acetic acid was heated under a N2 atmosphere and the temperature was increased from 20 to 150 oC. With ascorbic acid as the reductant,
MA NU
the surface of the V/SiO2 in the solution at 20 oC gave a green color, corresponding to V4+ species [10]. With other reductants the surface of the V/SiO2 also showed green color at higher temperatures, i.e. 30, 60, 80 and 100 oC with hydroquinone,
ED
pyrocatechol, oxalic acid and glucose, respectively. The change in color caused by
each reductant.
PT
variation in temperature accords with the onset temperature range corresponding to
CE
The presence of V4+ species in the V/SiO2 can be confirmed by the diffuse
AC
reflectance UV-vis and ESR spectra. Taking hydroquinone as example, the results of the characterization of the fresh and hydroquinone-reduced V/SiO2 are shown in Figure 2 and 3. In Figure 2, for fresh V/SiO2, the bands in the range of 250-300 nm should be assigned to charge transfer transitions involving oxygen and vanadium (V) in tetrahedral coordination, present as isolated species [11]. The absorption band in the region of 333-500 nm is associated with the lower-energy charge transfer of O-V5+ electron transfer for octahedral coordination [12]. When fresh V/SiO2 was reduced in hydroquinone at 40 oC for 2h, two bands at around 250 and 282 nm are observed. The band at 250 nm was assigned to an isolated tetrahedral V 5+ [11]. The
7
ACCEPTED MANUSCRIPT band at 282 nm is attributed to the lower-energy change transfer of O-V4+electron transfer [13]. For the fresh V/SiO2, the eight-line spectrum with very low intensity
RI P
T
was observed (Figure 3), which is attributed to vanadyl VIVO (d1) species [6, 14]. After reduction, the signal becomes well-resolved and the intensity of the signal
SC
increases, which indicates the V4+ complexes appear to be isolated and highly dispersed [15]. Thus, the vanadium species on the surface of the V/SiO2 are highly
MA NU
dispersed.
To gain insight into the reaction mechanism, the formation of H2O2 was directly measured via UV-vis spectroscopy of the reaction solution with different reductants.
ED
The results in Figure 4 indicated that the appearance of an absorption peak at ca.220
PT
nm with each reductant (curves b-f), this absorption peak based on H2O2 [16]. Without reductant, the absorption peak at 220 nm was silent (curve g). Therefore, the present
CE
V/SiO2 catalytic system using both O2 and reductant is considered to proceed via a
AC
reaction scheme similar to a Fenton type reaction [16-18]: V5+ species in the V/SiO2 was reduced to V4+ species by reductant. H2O2 was formed by the reaction of the V4+species with O2 and a proton. Hydroxyl radicals produced by the reaction of H2O2 with the V4+ species and protons are considered to participate in the phenol formation.
4. Conclusions In spite of the differences in the reduction properties, all the tested reductants were found to exhibit excellent reactivity for hydroxylation of benzene at the selective temperature. It was suggested that screening reductant should be carried out
8
ACCEPTED MANUSCRIPT at different temperatures. With each reductant the selectivity to phenol can be up to 100% corresponding to the maximum benzene conversion. Also, benzoquinone is also
RI P
T
an effective reductant, and benzoquinone and hydroquinone may be transformed into each other. With each reductant, H2O2 was formed and hydroxylation scheme was
SC
similar to a Fenton type reaction.
MA NU
Acknowledgement
This work was supported by the National Natural Science Foundation of China
ED
(21173110)
References
PT
[1] H. Yang, J. Q. Chen, J. Li, Y. Lv, S. Gao, Applied Catalysis A: General 415 (2012)
CE
22-28.
[2] P. P. Zhao, L. Yan, J. Wang, Chemical Engineering Journal 204 (2012) 72-78.
AC
[3] A. J. J. Koekkoek, H. C. Xin, Q. H. Yang, C. Li, E. J. M. Hensen, Microporous and Mesoporous Materials 145 (2011) 172-181. [4] S. Udenfriend, C. T. Clark, J. Axelrod, B. B. Brodie Journal of Biological Chemistry, 208 (1954) 731-739. [5] Y. Masumoto, R. Hamada, K. Yokota, S. Nishiyama, S.Tsuruya Journal of Molecular Catalysis A: Chemical
184 (2002) 215-222.
[6] E. Battistel, R.Tassinari, M. Fornaroli, L. Bonoldi Journal of Molecular Catalysis A: Chemical 202(2003) 107-115. [7] T. Miyahara, H. Kanzaki, R. Hamada, S. Kuroiwa, S. Nishiyama, S. Tsuruya, Journal of Molecular Catalysis A: Chemical 176 (2001) 141-150. [8] H. Q. Ge, Y. Leng, C. J. Zhou, J. Wang, Catalysis Letters 124 (2008) 324-329. [9] A. Hanyu, E. Takezawa, S. Sakaguchi, Y. Ishii, Tetrahedron Letters 39 (1998) 9
ACCEPTED MANUSCRIPT 5557-5560. [10] K. Lemke, H. Ehrich, U. Lohse, H. Berndt, K. Jähnisch, Applied Catalysis A:
T
General 243 (2003) 41-51.
RI P
[11] S. Dzwigaj, M. Matsuoka, M.Anpo, M. Che, The Journal of Physical Chemistry.
SC
B 104 (2000) 6012-6020.
[12] Z. H. Luan, J. Xu, H.Y. He, J. Klinowski, L. Kevan, The Journal of Physical
MA NU
Chemistry 100 (1996) 19595-19602.
[13] G. Centi, S. Perathoner, F. Trifiro, A. Aboukais, C. F. Aissi, M. Guelton, The Journal of Physical Chemistry 96 (1992) 2617-2629. [14] C. W. Lee, W. J. Lee, Y. K. park, S. E. park, Catalysis Today 61 (2000) 137-141.
ED
[15] C. H. Lee, T. S. Lin, C. Y. Mou, The Journal of Physical Chemistry C 111 (2007) 3873-3882.
PT
[16] M. Ishida, Y. Masumoto, R. Hamada, S. Nishiyama, S. Tsuruya, M. Masai,
CE
Journal of the Chemical Society, Perkin Transactions 2 (1999) 847-853. [17] X. H. Gao, J. Xu, Catalysis Letters 111 (2006) 203-205.
AC
[18] A. Kunai, S. Hata, S. Ito, K. Sasaki, Journal of the American Chemical Society 108 (1986) 6012-6016.
List of Tables
Table 1 Effect of various reductants on hydroxylation of benzene over V/SiO2 a
the temperature of reaching the maximum phenol yield
b
the onset temperature range of hydroxylation of benzene
10
ACCEPTED MANUSCRIPT c
benzoquinone selectivity is 100%
Reaction conditions: 0.1 g V/SiO2 , 1 ml benzene, 3 m mol reductant, 7 ml acetic
RI P
T
acid, 3 ml H2O, 1 MPa O2 , and 10 h. All of oxidation reactions were carried out
SC
with fresh catalyst each time.
MA NU
Table 2 Influence of reaction temperature on the percentage of V leaching Reaction conditions are the same as table 1
The percentage of V leaching equals the difference of V contents between fresh and
List of Figures
AC
CE
PT
ED
spent V/SiO2 divided by V content of fresh V/SiO2.
Figure 1 Effect of benzoquinone (A) or hydroquinone (B) as the reductant on the oxidation of benzene to phenol over V/SiO2 a. Selectivity to phenol (%) b. Conversion of benzene (%) c. Selectivity to benzoquinone (%) Reaction conditions are the same as table 1
11
ACCEPTED MANUSCRIPT Figure 2 Diffuse reflectance UV-vis spectra of (a) fresh V/SiO2 ; (b)
RI P
T
hydroquinone–reduced V/SiO2
SC
Figure 3 ESR spectra of (a) fresh V/SiO2;(b) hydroquinone–reduced V/SiO2
Figure 4 UV-vis spectra of H2O2 formed from the reaction solution with
MA NU
different reductants
a. aqueous solution of H2O2 (8×10-6 mol/l)
b. glucose ; c. pyrocatechol ; d. hydroquinone; e. ascorbic acid;
ED
f. oxalic acid ;
PT
g. without reductant
AC
CE
Reaction conditions are the same as table 1
12
ACCEPTED MANUSCRIPT
80
T
80
RI P
a
60
60
40
40
20
20
b
MA NU
0 40
60
Conversion of benzene (%)
100
A
SC
Selectivity to phenol(%)
100
80
100
0
120
o
Temperature ( C)
PT
60
60
40
40
a
20
b
20
0
Conversion of benzene
AC
80
c
CE
Selectivity (%)
80
100
B
ED
100
0 40
60
80
100
120
140
o
Temperature ( C)
Figure1 Effect of benzoquinone (A) or hydroquinone (B) as the reductant on the oxidation of benzene to phenol over V/SiO2 a. Selectivity to phenol (%);
b. Conversion of benzene (%);
c. Selectivity to benzoquinone (%) Reaction conditions are the same as table 1
13
T
ACCEPTED MANUSCRIPT
RI P
1.0
(a)
SC
(b) 0.6
MA NU
Absorbance
0.8
0.4
PT 300
400
500
600
700
800
900
Wavelength (nm)
AC
CE
0.0 200
ED
0.2
Figure 2 Diffuse reflectance UV-vis spectra of (a) fresh V/SiO2;(b) hydroquinone-reduced V/SiO2.
14
ACCEPTED MANUSCRIPT
RI P
T
(a)
MA NU
SC
(b)
2000
3000
4000
5000
ED
Gauss
PT
Figure 3 ESR spectra of (a) fresh V/SiO2;(b) hydroquinone-reduced
AC
CE
V/SiO2.
15
RI P
T
ACCEPTED MANUSCRIPT
a g
SC
Absorbance
b c
MA NU
d e
250
300
350
400
wavelength(nm)
CE
PT
200
ED
f
AC
Figure 4 UV-vis spectra of H2O2 formed from the reaction solution with different reductants a. aqueous solution of H2O2 (8×10-6 mol/L) b. glucose ; c. pyrocatechol ; d. hydroquinone e. ascorbic acid; f. oxalic acid ; g. without reductant Reaction conditions are the same as table 1
16
ACCEPTED MANUSCRIPT
Table 1
Ascorbic acid
40 (20-40)b
Hydroquinone
Phenol yield (%) 6.2 13.7 0
100 0.0c
14.3 0
100 67.5
10.0 9.0
100 100
9.7 3.3
100 100
10.1 4.9
100
9.5
the onset temperature range of hydroxylation of benzene
AC
c
CE
PT
ED
MA NU
120 a 14.3 40 11.8 b Benzoquinone (20-40) 120 a 10.0 60 13.4 Pyrocatechol (40-60)b 120 a 9.7 90 3.3 b Oxalic acid (60-90) 140 a 10.1 100 4.9 b Glucose (90-100) 120 a 9.5 a the temperature of reaching the maximum phenol yield b
Phenol selectivity (%) 100 100 0.0c
RI P
Reductant
Benzene conversion (%) 6.2 13.7 2.3
SC
Reaction temperature (oC) 20 90a
T
Effect of various reductants on hydroxylation of benzene over V/SiO2
benzoquinone selectivity is 100%
Reaction conditions: 0.1 g V/SiO2 (5 wt%), 1 ml benzene, 3 m mol reducing agent, 7 ml acetic acid, 3 ml H2O, 1 MPa O2 , and 10 h. All of oxidation reactions were carried out with fresh catalyst each time.
17
ACCEPTED MANUSCRIPT Table 2 Influence of reaction temperature on the percentage of V leaching Reaction temperature (oC)
Leaching of V (%)
T
Reductant
20
77.4
RI P
Ascorbic acid 90
Hydroquinone 120
MA NU
60
SC
40
Pyrocatechol
32.5 51.0 19.5
90
89.3
140
30.6
100
41.6
120
87.1
PT
Glucose
88.7
120
ED
Oxalic acid
63.4
Reaction conditions are the same as table 1.
CE
The percentage of V leaching equals the difference of V contents between fresh and
AC
spent V/SiO2 divided by V content of fresh V/SiO2.
18
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
MA NU
SC
RI P
T
Graphical abstract
19
ACCEPTED MANUSCRIPT Highlights 1. V/SiO2 with highly dispersed vanadium species was prepared by sol-gel process
T
2. Studying the effect of temperature on benzene oxidation with O2 over V/SiO2
RI P
3. Reducing capacity of reductant can be showed by changing temperature 4. Both of reductants benzoquinone and hydroquinone can be interconvertible
AC
CE
PT
ED
MA NU
SC
5. Presenting 100% selectivity to phenol with each reductant
20