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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 47, 2016 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Angelo Chianese, Luca Di Palma, Elisabetta Petrucci, Marco Stoller
Copyright © 2016, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-38-9; ISSN 2283-9216 

 

Catalytic Wet Peroxide Oxidation of Phenol in Dark With 
Nanostructured Titania Catalysts:  Effect of Exposure of 

Anatase 001 Plane 

Michael Ferentz, Miron V.Landau*, Roxana Vidruk-Nehemya, Moti Herskowitz 

Department of Chemical Engineering, Blechner Center for Industrial Catalysis and Process Development, Ben-Gurion 
University of the Negev, Beer-Sheva, 84105, Israel 
mlandau@bgu.ac.il 
 

A series of nanocrystalline titanium oxide materials with anatase structure was collected by purchasing the 
commercial products and by solvothermal synthesis. Characterization of these materials by XRD, HRTEM and 
N2-adsorption-desorption techniques showed that they displayed 10-30 nm crystal size, total surface area of 
30-150 m2/g  and the share of total surface area represented by [001] facets varied in range  of 30-65%. The 
exposed surface of [001] facets in selected TiO2 materials varied in range of 9-94 m

2/g. Testing of these 
materials as catalysts in catalytic wet peroxide oxidation of phenol revealed  a stright correlation  between the 
rate of phenol mineralization (concversion of TOC) and the value of exposed surface of [001] facets. 

1. Introduction 
Titanium oxide is known as efficient catalyst for photocatalytic degradation of organics in wastewater 
(Ananpattarachai et.al., 2014; Busca et.al., 2008). Recently was reported high efficiency of nanocrystalline 
titanium oxide (anatase) with surface area of 150 m2/g in catalytic wet peroxide oxidation (CWPO) of phenol in 
dark at low pH (Ferentz et.al.,2015). This is the first application of TiO2 in organocatalytic H2O2-assisted water 
purification in dark. One of the directions for further improvements in this field is tailoring of the specific atomic 
configuration and associated surface reactivity of TiO2 nanocrystals by changing the relative exposure of their 
surface facets. The strong impact of this parameter on performance of TiO2 in photocatalytic reactions was 
well established in last decade and reviewed by Grabowska et.al. (2014). The electronic properties of anatase 
TiO2 crystals with dominant [001] high-energy facets have a substantial effect on the surface separation and 
transfer of photo-generated  electron-hole pairs determining the strong effect of these planes exposure in 
photocatalysis (Liu et.al, 2011). The spontaneous dissociation of water molecules producing surface hydroxyls 
at adjacent Ti atoms bonded by a strong H bond is energetically favoured at [001] surface even in absence of 
light irradiation (Selloni, 2008). This is due to very high Ti-O-Ti bonds angles at this plane meaning 
destabilizing of O2p sites. Since formation of these adjacent H-bonded hydroxyls is the first step of catalytic 
H2O2 decomposition to highly reactive 

.OH radicals (Lousada et.al.,2012) it was assumed that the exposure of 
[001] planes in anatase nanocrystals would favour also the organocatalytic activity of TiO2 in dark. Testing of 
this effect is the aim of the present work. 
A series of anatase TiO2 materials consisting on truncated bipyramid nanocrystals of Wulff construction 
(Lazzeri et.al., 2001) with crystal size 10-30 nm, surface area 30-150 m2/g and exposure of [001] planes 12-
65% was tested in CWPO of phenol in a fixed-bed reactor in dark at 80oC. It was demonstrated that the first-
order rate constant of phenol mineralization defined as TOC removal does not correlate with total surface area 
of catalytic materials but increases proportionally to the specific surface area of [001] planes in TiO2 
nanocrystals. The estimated catalytic activity of [001] planes in anatase TiO2 nanocrystals was an order of 
magnitude higher compared with the activity of equivalent side [101, 011, 10 ͞1 and 01 ͞1] crystals facets.  

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1647039

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Ferentz M., Landau M., Vidruk-Nehemya R., Herskowitz M., 2016, Catalytic wet peroxide oxidation of phenol in dark 
with nanostructured titania catalysts: effect of exposure of anatase 001 plane, Chemical Engineering Transactions, 47, 229-234   
DOI: 10.3303/CET1647039

229



2. Experimental 
2.1 Preparation of titanium oxides  

The titanium oxides were prepared by solvothermal method in presence (ST-TA) and absence (ST-NA) of 
diethylenetriamine (DETA) as crystallographic controlling agent. The isopropyl alcohol (>99.5%, Daejung), 
(DETA) (99.0%, Sigma-Aldrich) and titanium(IV) isopropoxide (>98.0%, Acros) used were of analytical grade. 
In a typical synthesis, 0.025ml of (DETA) was mixed with 28 ml of isopropyl alcohol and stirred for 3 min at 
room temperature, then 1 ml of titanium(IV)isopropoxide was dropped slowly into the above mixture. The 
resulting mixture was transferred into a Teflon-lined stainless autoclave (35 mL capacity). The autoclave was 
sealed and maintained at T=200 °C for 24 h. The system was then allowed to cool ambient temperature. The 
final product was collected by centrifugation, washed thoroughly with ethanol, and dried at 70 °C overnight. 
The product was calcined at 400 °C for 2 h with a heating rate of 1 °C min-1. Two commercial titanium oxides 
XT25384 (COM-II) and XT25376 (COM-I) were purchased from Saint-Gobain NorPro Co. 

2.2 Characterization of titanium oxides  

X-ray powder diffraction (XRD) patterns were recorded with a Philips 1050/70 powder diffractometer equipped 
with a graphite monochromator using software developed by Crystal Logic. The high resolution SEM and TEM 
micrographs were obtained using JSM 7400F scanning microscope and JEM 2010 transmission microscope 
at 200 kV. The N2-adsorption-desorption Isotherms were obtained at the temperature of liquid nitrogen with a 
Surface Area & Pore Size Analyzer NOVA-3200e (Quantachrome) instrument.  

2.3 Testing of catalysts performance  

The catalytic activity of TiO2 materials was tested in CWPO of phenol as a model pollutant in water (200 ppm) 
at atmospheric pressure, H2O2/PhOH = 1.5 (1520 ppmw of H2O2 relative to stoichiometric demand for full 
PhOH conversion to CO2/H2O), inlet pH = 2.5, T = 80°C, and water flow 4-40 cc/ g cat*h in a tubular fixed-bed 
SS reactor with ID 7 mm (Ferentz, 2015). 0.10–0.25 mm catalysts particles were diluted with glass particles of 
0.3–0.6 mm at volume ratio 1:1.The reactor was operated in an up-flow mode excluding liquid distribution 
problems. The TOC content in effluent water was analyzed using VCPNTOC analyzer (Shimadzu Co.). 

3. Results and discussion 
According to XRD patterns (Fig. 1) all the TiO2 materials were pure titania phases with atomic order 
characteristic for anatase modification (Powder Diffraction File 4-784). Their average crystal size varied from 
10 nm (ST-TA) to 30 nm (COM-II). The surface area varied from 30 to 150 m2/g with values of pore diameter 
and volume listed in Table 1.  
 
Table 1: Texture parameters and crystal size of TiO2 materials 

 
 
 
 
 
 
 
 
 
 

According to HRTEM micrographs all TiO2 materials consisted of truncated bipyramid nanocrystals (Fig. 2) 
that at proper orientation yield rectangular or hexagon 2D images at the HRTEM micrographs. The calculation 
of the total theoretical surface area and exposure of [001] facets at the samples surface (m2/g) was conducted 
according to algorithm based on the amount of crystal unit cells placed in the nanocrystals volume and their 
width/height ratio N=a/b (Figure 2) assuming the theoretical density of anatase 3.904 g/cc. The N value was 
established by statistical analysis of HRTEM micrographs taking in account crystals images with right hexagon 
shape. As shown in Fig. 3 the hexagons shape varied significantly causing change of N from 0.30 to 0.95 
(Table 2). The surface area of exposed [001] facets varied from 9 to 94 m2/g corresponding to their relative 
exposure in individual nanocrystals from 30 to 55% (Table 2). Elongated flat nanocrystals obtained in 

Sample 

Surface 
Area 
(BET) 
[m2/g]  

Pore 
Volume 

(Av.) 
[cc/g] 

Pore 
Diameter 

(Av.) 
[nm] 

Crystal 
Diameter 

(XRD) 
[nm] 

ST-TA 145 0.45 12.4 10 

ST-NA 65 0.15 4.5 20 

COM-I 150 0.43 10.7 12 

COM-II 30 0.17 20 30 

230



presence of amine crystallographic controlling agent (ST-TA,Fig.3.1) displayed maximal exposed surface of 
[001] planes while the COM-II material (Fig.3.3) demonstrated the lowest exposed surface of [001] facets.  
Since the nanocrystals formed aggregates with different types of connectivity, the estimation of the exposure 
of [001] facets requires corrections taking into account the self-screening of crystallographic planes in 
aggregates. In the ST-TA material the primary nanocrystals were connected in particle-linked nanowires 
packed in microspheres (Fig.4.1).   

 
Figure 1: XRD patterns of TiO2 materials: 1-ST-TA; 2- ST-NA; 3- COM-I; 4 – COM-

 
Figure  2:  Schematic representation of  bipyramid TiO2 nanocrysytals: left- only Ti atoms; right – oxygens 
layers 
 
 
 
 
 
 
 
 
 
                    1                                     2                                              1                                              2            
 
                                                                                          
 
 
 
 
 
                                                                                        
 
      Figure 3: HRTEM images of individual nano-           Figure 4: Aggregates of individual nanocrystals in TiO2 
      crystals in TiO2 materials: 1 -  ST-TA; 2 - ST-NA;    materials: 1 - ST-TA; 2 - ST-NA; 3 – COM-I; 4 -COM-II 
      3 – COM-I; 4 – COM-II                                                                 
 
 
 
 
                                                                            
 
 

Figure 5: Association spaces of nanocrystals in nanowires of ST-TA TiO2 material 

231



 
Table 2: Exposure of [001] facets in TiO2 materials and rate constants of phenol mineralization in CWPO 

 
In other materials nanocrystals, aggregates did not show a specific orientation (Fig.4.2-4). The effect of self-
screening of crystallographic planes in nanocrystalline aggregates on their exposed surface area may be 
estimated by the aggregation ratio ψ, calculated as S.A.theor./S.A.BET which is the ratio between calculated 
theoretical surface area of individual nanocrystal and actual exposed surface area measured by BET method 
(Landau, 2014). The ψ values presented in Table 2 show that in COM-I material the primary nanocrystals are 
not screening each other (ψ = 1.00). In other materials this value varied from 1.18 to 1.66. This means that in 
COM-I TiO2 the relative exposure of [001] facets is equal in nanocrystals and their aggregates. The surface 
area of [001] facets displayed in materials ST-NA and COM-II with random orientation of nanocrystals may be 
calculated as S.A.[001] aggregates = S.A.[001]theor./ψ.  
In case of ST-TA material for calculation of [001] planes exposure should be taken in account the specific 
connectivity of primary nanocrystals in nanowires. It is very difficult to find on HRTEM micrographs images 
nanowires where primary particles are oriented relative to the electronic beam so as to detect the fringes of 
atomic layers in all the nanocrystals. Therefore the micrographs areas were carefully considered so the atomic 
structure of nanocrystals may be seen in two adjusted crystallites (Fig.5). The primary nanocrystals were 
connected by their side [101] planes leaving [001] facets exposed. The fringes of atomic layers corresponded 
to [101] planes with spacing of 0.352 nm are cut at the contact interface. It means that elongated TiO2 
nanocrystals in ST-TA material forming nanowires are not connected through coupling of their [001] facets. In 
this case, the fringes of atomic layers in two neighbouring crystallites are extended from one nanocrystal to 
another without changing the direction (Fig.2). These considerations were the basis for building a model of 
nanocrystals connectivity in nanowires of ST-TA material shown in Figure 6. This type of connectivity may be 
realized assuming preferential adsorption of DETA as crystallographic controlling agent at the [001] planes of 
growing TiO2 crystals. Selective adsorption of amine molecules on [001] planes not only favours the crystals  
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Figure 6: HRTEM image of particle-linked nanowire in ST-TA TiO2 and schematic representation of their 
aggregation mode 

Sampl
e 

S.A.   
(BET) 

N=a/b 

S.A.Theor. [m
2
/g] 

ψ 

Exposed 

Kw 

Kwheterog.=

STotal S001 S101 

[001] facets % [001] Kw-Kblank

m
2
/g crystals aggregates m

2
/g g

-1
*h

-1
*cm

3
 g

-1
*h

-1
*cm

3
 

ST-TA 145 0.30 171 94 77 55 65 1.18 94 16 15.2 

ST-NA 65 0.50 79 30 49 38 38 1.21 25 9 8.2 

COM-I 150 0.95 150 18 132 12 12 1.00 18 4.5 3.7 

COM-II 30 0.61 50 17 33 30 30 1.66 9 3.3 2.5 

232



growth in direction increasing the exposure of these planes in individual nanocrystals (Zhang, 2009) but also 
protects these facets from coupling during aggregation. Based on the above considerations, the relative 
exposure of [001] facets in nanowires of ST-TA TiO2 should be higher than its theoretical value calculated for 
individual nanocrystals by the ψ factor. The aggregation increases the share of [001] facets in exposed total 
surface area from the theoretical value of 55% to 65% (Table 2). The last number (65%) was used for 
calculation of physically exposed [001] surface (m2/g) in ST-TA material (Table 2) that is equal to its 
theoretical value since [001] planes are not screened. 
Measuring the conversion as a function of residence time for the four selected TiO2 materials in CWPO of 
phenol indicated a first-order equation reaction. ln(1-XTOC) plotted as a function of W/Q, where XTOC – 
conversion of total organic carbon, W – weight of catalyst loaded to reactor (g), Q - flow rate of aqueous 
phenol solution (cc/h) (Fig.7) yielded a linear dependency where the slope k is the rate constant (g cat

-1
 * h

-1 * 
cc solution),. According to the values of calculated rate constants of phenol mineralization the catalytic activity 
of tested materials increased in the sequence: ST-TA > ST-NA > COM-I > COM-II (Table 2). The blank testing 
experiment conducted at the same conditions in a reactor loaded with glass particles yielded TOC conversions 
corresponding to the equivalent value of the reaction rate constant of 0.8 g cat

-1
 * h

-1 * cc solution. Subtracting 
this value from the measured rate constants represents the heterogeneous catalytic reaction rates (Table 2). 
In absence of diffusion limitations excluded by implementation of small 0.10-0.25 mm catalysts particles the 
catalytic activity is determined by the TiO2 surface area multiplied with the value of specific reaction rate 
constant : k = ks * S.A.  Assuming that the specific catalytic activity (per 1 m2 of solid) is constant for all the 
materials depending only on their chemical composition - TiO2, the kinetic rate constants of all materials 
should be proportional to their total surface area. 
Plotting the measured rate constants vs the total surface area of tested materials (Fig.8.1) does not show a 
linear correlation. However, the plot in Fig.8.2 indicates that the catalytic activity of TiO2 materials correlates 
well with the exposed surface area of active [001] facets in nanocrystalline aggregates. Extrapolation of graph 
presented in Fig.8.2 to the S.A.[001] = 150 m2/g assuming that all the total  surface in COM-I or ST-TA 
materials is represented by [001] facets yields the rate constant value k ~ 25 g cat

-1
 * h

-1 * cc solution. 
Extrapolation to the opposite direction assuming that the total surface is represented by [101] facets gives the 
rate constant value of k ~ 2.5 g cat

-1
 * h

-1 * cc solution. Therefore, the catalytic activity of [001] facets of TiO2 
anatase nanocrystals in CWPO oxidation of phenol is an order of magnitude higher compared with activity of 
[101] facets. As mentioned above this may be a direct consequence of high Ti-O-Ti bonds angles at [001] 
surface plane meaning destabilizing of O2p sites and leading to spontaneous dissociation of water molecules 
and producing surface hydroxyls at adjacent Ti atoms (Selloni, 2008). Formation of such surface hydroxyl 
pairs is critical for selective decomposition of H2O2 into 

.OH radicals highly reactive in phenol oxidation 
(Lousada et.al., 2012).   
The presented data suggest further improvement of TiO2-based catalysts for CWPO of organic contaminants 
in water requires increasing the exposure of [001] facets of anatase nanocrystals to more than 80%. This 
means preparation of thin nano-sheets of TiO2 with high exposure of [001] planes on both sides. Preparation 
and stabilization of such nano-sheets is a challenge, since they curve and aggregate. Application of TiO2 
anatase nanotubes with [001] planes exposed at their inner and external surface is another challenge. 
 
 

 
 
 
 
 
 
 
 
 
 
 
 

 
 
 
 
Figure 7: Kinetics of phenol mineralization by CWPO with following catalytic materials: 1 – ST-NA;  
 2 – ST-TA; 3 – COM-I; 4 – COM-II 

233



 
 
 
 

  
 
 
 
 
 
 
 
 

                                           1                                                                                       2 
Figure 8: Correlations between phenol mineralization rate constants and catalysts surface area: 1 – total  
surface area; 2 - surface area of exposed [001] crystal planes of TiO2 materials\ 

4. Conclusions 
The exposure of high-energy [001] facets in anatase nanocrystals with Wulff construction of truncated 
bipyramid determines their catalytic activity in phenol CWPO in dark. This may be attributed to spontaneous 
water dissociation being a sequence of unique atomic configuration at the surface of [001] crystal planes and 
leading to formation of surface hydroxyl pairs directing the H2O2 decomposition to

 .OH radicals. 

Acknowledgments 

We acknowledge the financial support provided by Ben Gurion University of the Negev in the framework of the 
collaboration between BGU, the Institute for Molecular Engineering at the University of Chicago, and Argonne 
National Laboratory on the Engineering and Science of Water Resources. The authors are grateful to Dr. A. 
Erenburg and Dr. V. Ezersky for characterization of catalysts using XRD and HRTEM methods, respectively. 

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