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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 

Photocatalytic Removal of Phenol by Ferromagnetic N-
TiO2/SiO2/Fe3O4 Nanoparticles in presence of Visible Light 

Irradiation 

Vincenzo Vaianoa*, Olga Saccoa, Diana Sanninoa, Marco Stollerb, Paolo 
Ciambellia, Angelo Chianeseb 
a
Department of Industrial Engineering, University of Salerno, Via Giovanni Paolo II 132, 84084 Fisciano (SA), Italy 

b
Department of Chemical Material Environmental Engineering, University of Rome “La Sapienza”, Via Eudossiana 18, 

00184 Rome, Italy. 
vvaiano@unisa.it 

Heterogeneous photocatalysis with TiO2 has shown high efficiency in the removal of a wide range of organic 
contaminants. Recently, significant efforts have been made to activate TiO2 under visible light wavelengths, 
and promising results were obtained by doping it with nitrogen. The main drawback of the use of nanoparticles 
for the purification of wastewater is their separation after the depollution treatment and this is an issue that has 
to be addressed for a proficient application of N-doped TiO2 nanoparticles. The use of magnetic core Fe3O4 
and N-doped TiO2 shell nanoparticles could be a solution to this problem. With the aid of an external magnetic 
field, the removal and recycling of the photocatalyst nanoparticles become possible. For this reason, the aim 
of this work was to obtain nanocomposites consisting of visible active N-doped TiO2 supported on SiO2/Fe3O4 
ferromagnetic nanoparticles. The nanocomposites were then evaluated in the photocatalytic removal of 
phenol. The photocatalytic tests were carried out in a recirculating batch cylindrical photoreactor irradiated by 
a strip of white LEDs surrounding the external surface of the reactor and emitting in the visible region.  
The experimental results showed that N-doped TiO2/SiO2/Fe3O4 nanoparticles are effective in the removal of 
phenol, reaching degradation and TOC removal of about 64 and 55%, respectively, after an irradiation time of 
270 min. The catalyst was collected at the photoreactor bottom after each test cycle by applying a magnet on 
the external surface of the photoreactor, so easily separating the treated solution from the photocatalyst. After 
washing with distilled water and drying at 50 °C, the photocatalyst was reused without further treatment. 
Photocatalytic tests on the recycled catalyst showed that N-doped TiO2/SiO2/Fe3O4 remains stable, evidencing 
phenol degradation in the range 59-65% after four operation/regeneration cycles. 

1. Introduction 
Phenolic compounds represent a threat to the environmental point of view because of their toxicity, 
bioaccumulation, and persistency in the environment. The representative of this class of compounds is phenol, 
widely used as a raw material in the petrochemical industries and oil refineries (Tao et al., 2013). Phenol and 
its derivatives are found in the effluents of various industries such as petrochemical, coal, pharmaceutical, 
wood, paint, pulp and paper industries (Ahmaruzzaman, 2008). Therefore, the increasing presence of phenol 
represented significant hazardous environmental toxicity (Tao et al., 2013). However, traditional techniques 
such as active carbon adsorption, chemical oxidation, and biological digestion have low efficiency in the 
removal of phenol. Advanced oxidation process (AOPs) to degrade organic pollutants in wastewater is an 
interesting alternative to the traditional technologies. Among AOPs, heterogeneous photocatalysis with TiO2 
have shown high efficiency in the removal of a wide range of organic contaminants, also present in low 
amount in wastewater. However, TiO2 has a large band-gap (3.2 eV), meaning that it can be only active under 
the UV light irradiation. Recently, significant efforts have been made to activate TiO2 under visible light 
wavelengths, and successful results were obtained by doping it with nitrogen through sol-gel method (Sacco 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1647040

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Vaiano V., Sacco O., Sannino D., Stoller M., Ciambelli P., Chianese A., 2016, Photocatalytic removal of phenol by 
ferromagnetic n-tio2/sio2/fe3o4 nanoparticles in presence of visible light irradiation, Chemical Engineering Transactions, 47, 235-240   
DOI: 10.3303/CET1647040

235



et al., 2012). The developed N-doped TiO2 (N-TiO2) was very active in the removal of organic dyes (Vaiano et 
al., 2014), atrazine (Sacco et al., 2015) and spiramycin (Vaiano et al., 2015).  
However, one of the most important drawbacks of photocatalytic process is that photocatalysts are often used 
in slurry reactors. The limitation of the slurry process is that the N-TiO2 nanoparticles must be separated from 
the system after the treatment. The cost of this separation step may even invalidate economically the 
technique (Pozzo et al., 1997). Among several reported methods for separating and recycling the 
photocatalyst particle from the treated water, magnetic separation provides a convenient approach by the 
means of applying an external magnetic field. Magnetic photocatalyst obtained by coating TiO2 particles onto 
Fe3O4 has been studied in the photocatalytic removal of 2-chlorophenol (Rashid et al., 2015), organic dyes 
(Wang et al., 2012) and in the photocatalytic degradation of organic compounds of olive mill wastewater 
(Ruzmanova et al., 2013), showing in all cases good stability after several cycles of repetitive use under UV 
irradiation. However, very scarce is the literature reporting the use of a visible-active magnetic photocatalyst in 
the removal of organic compounds from wastewater. For this reason, the aim of this work was to obtain 
nanocomposites consisting of visible active N-doped TiO2 supported on SiO2/Fe3O4 ferromagnetic 
nanoparticles (N-TiO2/FM) and to evaluate the performances and recyclability of N-TiO2/FM in the 
photocatalytic removal of phenol. 

2. Experimental 
2.1 Synthesis of N-doped TiO2 photocatalyst  
The N-TiO2 photocatalyst was prepared by hydrolysis and condensation reactions at 0°C between a TiO2 
precursor (titanium tetraisopropoxide, >97 wt%, Sigma Aldrich) and ammonia aqueous solution (30 wt%, Carlo 
Erba). The obtained gel was then centrifuged and washed with distilled water. Finally, the sample was 
calcined at 450° C for 30 min. The molar ratio N/Ti is 18.6, the same as in the optimized catalyst formulation 
found in our previous work (Sacco et al., 2012). 

2.2 Synthesis of SiO2/Fe3O4 core-shell nanoparticles 
The core-shell SiO2/Fe3O4 nanoparticles (FM) were prepared by two steps. Firstly, Fe3O4 magnetic 
nanoparticles were synthesized using a spinning disk reactor (De Caprariis et al., 2012). Then, FM 
nanoparticles were prepared by dispersing Fe3O4 particles in distilled water, followed by the addition of 
C2H5OH (Sigma Aldrich). Tetraethyl ortosilicate (TEOS), preliminarily diluted in C2H5OH, was added drop-wise 
to the Fe3O4 particle suspension. Then an aqueous solution of NH3 (30 wt %) was added and the TEOS 
hydrolysis and condensation was allowed under overnight gentle stirring. The obtained FM particles were 
washed in a centrifuge using firstly water/ethanol mixtures then distilled water. Finally, they were dried and 
calcinated at 450 °C for 30 min.  

2.3 Synthesis of N-doped TiO2 supported on SiO2/Fe3O4 nanoparticles 
The FM nanoparticles were used as support for N-TiO2 catalyst: 0.5g of FM particles were dispersed in 100 
mL of HNO3 (0.1 mol L

−1) aqueous solution and maintained under mechanical stirring several minutes until to 
obtain an uniform dispersion. Then, 4 mL of TEOS and 0.3 g of N-TiO2 were added to the FM aqueous 
suspension. The mixture was kept under stirring for 48 h at 25 °C and then centrifuged. Finally, the recovered 
sample was calcined at 450° C for 30 min to obtain the final N-TiO2/FM catalyst. The nominal loading of N-
TiO2 on the FM support was 37.5 wt %. 

2.4 Samples characterization 
Physico-chemical characterisation of samples has been performed with different techniques. Laser Raman 
spectra were obtained at room temperature with a Dispersive MicroRaman (Invia, Renishaw), equipped with 
514 nm laser, in the range 100-2500 cm-1 Raman shift. UV-Vis reflectance spectra were recorded with a 
Perkin Elmer spectrometer Lambda 35. X-ray diffraction (XRD) was carried out using an X-ray 
microdiffractometer Rigaku D-max-RAPID, using Cu-Kα radiation and a cylindrical imaging plate detector. 
Diffraction data from 0 to 204 degree horizontally and from -45 to 45 degree vertically were collected. The 
incident beam collimators enable different spot sizes to be projected onto the sample. Specific surface area 
(SSA) of catalysts was obtained by N2 adsorption measurement at -196 °C with a Costech Sorptometer 1040 
after pretreatment at 60 °C for 120 min in He flow (99.9990 %).  
The average size of the Fe3O4 nanoparticles was measured by dynamic light scattering instrument 
(Brookhaven Plus 91). 

2.5 Photocatalytic tests 
The photocatalytic experiments were carried out with initial concentration of phenol equal to 75 mg L−1, at 
ambient temperature and pressure. The catalyst dosage was 3 g L-1. The total volume of phenol aqueous 
solution was 75mL. The experiments were realized using a pyrex cylindrical photoreactor (ID=2.5 cm; 

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height=25 cm) equipped with an air distributor device (Qair=150 cm
3 min−1 (STP)). Continuous mixing of the 

aqueous solution was realized by external recirculation of the same solution through the use of a peristaltic 
pump. The photoreactor was irradiated with a strip composed of 25 white light LEDs (5W nominal power; 
provided by New Oralight), with wavelength emission in the range 400–800 nm with main emission peak at 
475 nm. The LEDs strip was positioned around and in contact with the external surface of the photoreactor 
(incident light intensity 32mW cm−2). The system was left in the dark for 120 min to reach phenol adsorption 
equilibrium, and then photocatalytic reaction was initiated under visible light for 270 min. 
The residual concentration of phenol in aqueous samples was monitored by observing the change in the 
absorbance at the maximum absorption wavelength of 500 nm using a UV–vis spectrophotometer (Lambda 
35, Perkin Elmer), and then the concentration was calculated from a calibration curve. Total organic carbon 
(TOC) of aqueous samples was calculated from CO2 obtained by catalytic combustion at T=680°C. 

3. Results and discussion 
3.1 Samples characterization 
The characteristics of the prepared samples are listed Table 1.  

Table 1: Samples and their characteristics 

Sample SSA 
m2 g-1 

Anatase average crystallite size  
nm 

Fe3O4 average crystallite size  
nm 

N-TiO2 30 17 - 
FM 88 - 20 
N-TiO2/FM 46 15 20 
 
The specific surface area (SSA) of pure N-TiO2 (Table 1) was 30 m

2 g-1, while a higher value (88 m2 g-1) was 
found for FM sample. The deposition of N-TiO2 particles on FM surface determined a decrease of the SSA 
value up to 46 m2 g-1. This last result is due to the coupling of two materials: one (N-TiO2) with a lower SSA 
(30 m2 g-1) and the other one (FM) with a higher SSA (88 m2 g-1). 
Dynamic light scattering results evidenced that Fe3O4 size distribution (not shown) was quite narrow with an 
average size of about 20 nm. Crystal phase composition of N-TiO2, FM and N-TiO2/FM was determined by 
XRD measurements (Figure 1). 

 
Figure 1: XRD spectra for N-TiO2, FM and N-TiO2/FM 
 

237



 
Figure 2: UV–VIS DRS spectra for N-TiO2, FM and N-TiO2/FM 
 
XRD result of FM sample exhibited the presence of the crystalline form the orthorhombic phase of Fe3O4 
(Wang et al., 2012). From the analysis of XRD spectra of N-TiO2/FM compared with those of FM and 
unsupported N-TiO2 powder, it was found the presence of the anatase-TiO2 peaks with together the signals of 
FM. No diffraction peaks corresponding to SiO2 were observed for FM and N-TiO2/FM probably because silica 
has amorphous structure. The same results were obtained from Raman analysis (not shown). Anatase and 
Fe3O4 crystallite size of the samples were evaluated from XRD analysis, using the Scherrer equation (Table 
1). For N-TiO2, the anatase crystallite size was about 17 nm and slightly decreased after the deposition of N-
TiO2 on FM. Fe3O4 crystallite size was found to be about 19 nm which corresponds to the determined average 
particle size by dynamic light scattering measurement.  
Figure 2 reports the UV–vis reflectance spectra in terms of Kubelka-Munk function for N-TiO2, N-TiO2/FM and 
FM. N-TiO2 and N-TiO2/FM samples exhibited remarkable red shift of absorption edge to the visible light 
region which is the typical absorption property of TiO2 doped with nitrogen (Lindgren et al., 2003). The shifting 
of the absorption onset from about 530 nm (for N-TiO2) to about 610 nm (for N-TiO2/FM) is due to the 
absorption properties of FM indicating an additive effect of the specific band edges of N-TiO2 and FM on the 
N-TiO2/FM catalyst. 

3.2 Photocatalytic results 
Preliminary experiments were carried out in order to verify that phenol was removed by the heterogeneous 
photocatalytic process under visible light. It was found that in the absence of photocatalyst, no decrease in 
phenol concentration was observed, Therefore, photolysis phenomena didn’t occur. 
Figure 3 reports the photocatalytic activity of N-TiO2, FM and N-TiO2/FM. After 270 min of visible light 
irradiation, no photocatalytic activity was observed for FM sample. On the contrary, both N-TiO2 and N-
TiO2/FM catalysts were effective in the degradation of phenol in aqueous solutions. In particular the 
degradation efficiency of N-TiO2 and N-TiO2/FM were 77 and 64%, respectively. These values are higher than 
those reported in the literature concerning the photocatalytic degradation of phenol under visible light 
irradiation (Hamzezadeh-Nakhjavani et al., 2015). In addition TOC removal of about 65 and 55 % was 
achieved after 270 min of irradiation for N-TiO2 and N-TiO2/FM, respectively. This last result evidenced that 
the photocatalysts were also effective in the mineralization of phenol to CO2 and H2O.  
The lower photocatalytic activity of N-TiO2/FM compared to N-TiO2 particles could be attributed to the strong 
brown colour of N-TiO2/FM particles, which reduces the light penetration into the aqueous medium. 
However, as the separability of photocatalysts from treated wastewater in practical wastewater treatment 
systems is very important, magnetic N-TiO2/FM sample was chosen for investigating the stability and 
efficiency after four reuse cycles (Figure 4).  

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N-TiO2/FM catalyst was collected at the photoreactor bottom after each test cycle by applying a magnet on the 
external surface of the photoreactor, so easily separating the treated solution from the photocatalyst. After 
washing with distilled water and drying at 50 °C, the photocatalyst was reused without further treatment. 
Photocatalytic tests on the recycled catalyst showed that, after four reuse cycles, N-TiO2/FM catalyst 
remained stable, evidencing phenol degradation and TOC removal in the range 59-65 and 45-56%, 
respectively. 
 

 
Figure 3: Photocatalytic degradation of phenol using N-TiO2, FM and N-TiO2/FM 
 

 
Figure 4: Photocatalytic degradation of phenol on N-TiO2/FM after repetitive use 

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4. Conclusion 
Visible-active magnetically separable nanocomposite N-TiO2/SiO2/Fe3O4 (N-TiO2/FM) was successfully 
synthesized and tested in the photocatalytic removal of phenol under visible light irradiation. The XRD and 
Raman results confirmed the presence of crystalline magnetite, SiO2, and TiO2 in anatase phase and the 
average nanoparticle size of Fe3O4 magnetic core was about 20 nm.  
The photocatalytic tests were carried out in a recirculating batch cylindrical photoreactor irradiated by a strip of 
white LEDs surrounding the external surface of the reactor and emitting in the visible region. The experimental 
results showed that N-TiO2/FM nanoparticles are effective in the removal of phenol, reaching degradation and 
TOC removal of about 64 and 55%, respectively, after an irradiation time of 270 min. The results of visible-
active magnetic catalyst reuse showed the effectiveness of prepared samples after four cycles of repetitive 
use, evidencing phenol degradation and TOC removal in the range 59-65 and 45-56%, respectively. 

Acknowledgments 

The support of the University of Salerno by funding the project “Sistemi catalitici per l'intensificazione di 
processo e per la riduzione dell'inquinamento ambientale" (Ex 60%, anno 2014) is here gratefully 
acknowledged by the authors. 

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