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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 60, 2017 

A publication of 

 

The Italian Association 
of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Luca Di Palma, Elisabetta Petrucci, Marco Stoller
Copyright © 2017, AIDIC Servizi S.r.l. 
ISBN 978-88-95608- 50-1; ISSN 2283-9216 

About a Novel Production Method for N-Doped Magnetic 
Nanocore Nanoparticles of Titania by Means of a Spinning 

Disk Reactor 

Marco Stoller*a, Srikanth Vuppalab, Mariantonietta Matarangoloc, Vincenzo 
Vaianoc, Diana Sanninoc, Angelo Chianesea, Claudio Cianfrinib 

a Sapienza University of Rome, Dept. of Chemical Engineering Materials Environment, Via Eudossiana 18, Rome, Italy 
b 
Sapienza University of Rome, Dept. of Astronautics Electrical and Energy Engineering,Via Eudossiana 18, Rome, Italy 

c 
University of Salerno, Dept. of Industrial Engineering, Via Giovanni Paolo II 132, 84084 Fisciano(SA), Italy  

marco.stoller@uniroma1.it 

This study reports a novel approach to produce nitrogen doped magnetic core TiO2 nanoparticles (N-
TiO2/FM). The treatment of wastewater streams by photocatalysis appears a feasible pre-treatment for many 
subsequent purification steps, such as membranes. In order to keep high efficiencies in dealing with the 
wastewater streams, the photocatalyst requires to be suspended in order to reach the water surface for proper 
irradiation and operation. A main drawback is the recovery of the suspended photocatalyst, that may be 
accomplished by magnetic filters (up to 99.9%) as soon as the titania nanoparticles are attached to magnetic 
nanocores (FM). Moreover, the photocatalyst should react to visible light and not only to UV (as pure titania), 
to operate with a high energy efficient process that may use LED lamps instead of UV lamps. This property 
can be acquired through nitrogen doping. Therefore, the production of NMTNP may represent a general 
solution to all these problems. The N-TiO2/FM were synthesised starting with the production of magnetic 
nanocores by SDR and their coating of silica by using the Stroeber method. Finally, FM particles were 
dispersed in Urea solution and then titanium tetraisopropoxide (TTIP) is added to produce N-TiO2/FM, 
respectively. In the final stage of production, the N-TiO2/FM solution is washed and calcinated at higher 
temperatures. The final product is a core-shell-shell nanoparticle of FM/silica and titania. The experimental 
runs performed in an aerated photoreactor for phenol degradation shows the efficiency of NMTNP for 
purification purposes and its easily recovery by magnets. 

1. Introduction 
Water pollution has become a major problem in recent year (Muradova et al. 2016; Vilardi and Di Palma 
2016). Phenolic compounds represent a threat to the environmental point of view because of their toxicity, 
bioaccumulation, and persistency in the environment. These materials were recorded by The Agency for Toxic 
Substances and Disease Registry-USA (ATSDR) as one of the year 2007 priority contaminants that have 
critical potential danger to human wellbeing (Shawabkeh et al. 2010; Vaiano et al., 2016). The effluents of 
various industries such as petrochemical, coal, pharmaceutical, wood, paint, pulp and paper industries 
contains phenol and its derivatives besides inorganic pollutants (Vilardi et al., 2017). Traditional techniques 
such as active carbon adsorption, chemical oxidation, and biological digestion have low efficiency in the 
removal of phenol (Stoller et al. 2016). Advanced oxidation process (AOPs) is an interesting alternative to the 
traditional technologies. Among AOPs, heterogeneous photocatalysis with nanoparticles have shown high 
efficiency in the removal of a wide range of organic contaminants, also present in low amount in wastewater 
(Bavasso et al. 2016). Titanium dioxide exists primarily as anatase, rutile and brookite. In comparison to rutile 
and brookite, the anatase phase is catalytically more active (Choquette-Labbé, Shewa, Lalman, & 
Shanmugam, 2014). Fujishima and Honda demonstrated the potential of titanium dioxide (TiO2) 
semiconductor materials to split water into hydrogen and oxygen in a photo-electrochemical cell. Their work 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1760008

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Stoller M., Vuppala S., Matarangolo M., Vaiano V., Sannino D., Chianese A., Cianfrini C., 2017, About a novel 
production method for n-doped magnetic nanocore nanoparticles of titania by means of a spinning disk reactor, Chemical Engineering 
Transactions, 60, 43-48  DOI: 10.3303/CET1760008 

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triggered the development of semiconductor photocatalysis for a wide range of environmental and energy 
applications. In the case of anatase TiO2, the band gap is 3.2 eV, therefore UV light (≤ 387 nm) is required.  
Later, Asahi and co-workers explored for first time the visible light activity of N-doped TiO2 produced by 
sputter deposition of TiO2 under an N2/Ar atmosphere, followed by annealing under N2. N-doped TiO2 is used 
to extend the photocatalyst’s response into the visible region and hence improve the oxidation of several 
organic compounds such as chloroform, toluene, benzene, alcohols and ethers (Ruzmanova et al. 2015; 
Shawabkeh et al. 2010). Simultaneous TiO2 growth and N doping is achieved by hydrolysis of titanium 
alkoxide precursors in the presence of nitrogen sources. Typical titanium salts (titanium tetrachloride) and 
alkoxide precursors (including titanium tetra-isopropoxide, tetrabutyl orthotitanate) have been used. Nitrogen 
containing precursors used include aliphatic amines, nitrates, ammonium salts, ammonia and urea. The 
synthesis root involves several steps; however, the main characteristic is that precursor hydrolysis is usually 
performed at room temperature. Pulverization and calcination were done to remove solvents from the 
precipitate at temperatures from 200 to 600 °C (Pelaez et al. 2012). The limitation of the slurry process is that 
the N-TiO2 nanoparticles must be separated from the system after the treatment (Rashid et al. 2015; Vaiano et 
al., 2016). The use of magnetic core TiO2 nanoparticles offers a solution to this problem. The application of an 
external magnetic field to such materials provides an effortless way for removing and recycling the 
photocatalyst (Di Palma et al. 2015; Shirinova et al. 2016). In addition to incorporating an SiO2 intermediate 
layer between the Fe3O4 (FM) core and the TiO2 shell weakens the adverse influence of Fe3O4 on the 
photocatalysis of TiO2 (Rashid et al. 2015) and increase in its specific surface area by atomic mixing (Viet-
Cuong and The-Vinh 2009). Magnetic photocatalyst obtained by coating TiO2 particles onto Fe3O4 has been 
studied in the photocatalytic removal of phenols, 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 (Vaiano et 
al., 2016). Preparation of a magnetic photocatalyst by coating TiO2 particles onto iron oxide have been 
reported by Beydoun and co-workers. Due to its chemical inertia, silica (SiO2) has been proposed to be added 
between the magnetic particles core and TiO2 coating to overcome the above-mentioned problems. The 
application of an intermediate layer barrier such as SiO2 between the magnetic core and the titanium dioxide 
shell may lead to the avoidance of the photo dissolution of iron, magnetic core stabilization, and the prevention 
of the magnetic core from acting as an electron-hole recombination center which would negatively affect the 
photoactivity of TiO2. The deposition of TiO2 onto silica-coated iron oxide has been conducted by several 
techniques such as impregnation, precipitation, and sol–gel (Hamzezadeh-Nakhjavani et al. 2015). The 
Spinning Disk Reactor (SDR) has many advantages when compared with other mixing devices used for 
precipitation process: i) a small liquid residence time, limiting the growth rate after nucleation, that leads to the 
production of narrow PDSs of nanoparticles at a specific target size; ii) micro-mixing conditions attained by 
means of a limited energy consumption; iii) continuous operation, compatible to industrial practice, can be 
performed (De Caprariis et al. 2015). The silica shell thickness can be controlled from 12.5 nm to 45 nm by 
varying the operating parameters. The reaction time, the ratio of TEOS/Fe3O4, and the concentration of 
hydrophilic Fe3O4 seeds were found to be very important parameters in the control of silica shell thickness 
(Ruzmanova et al. 2013).  

2. Materials and Methods 
2.1 Synthesis of Fe3O4-SiO2 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. 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 minutes 
(Vaiano et al., 2016). 

2.2 Synthesis of Fe3O4-SiO2/N-doped TiO2 nanoparticles 

Fe3O4-SiO2/N-doped TiO2 nanoparticles were prepared by adding urea in 50 ml water and continue the stirring 
for 10 minutes, then Fe/SiO2 was added in sonicator for 5 minutes finally TTIP was added under sonication 
followed by 10 minutes mechanical mixing. The mixture was centrifuged and washed two times. Finally, the 
recovered sample was calcinated at 450°C/30 minutes (Ramp 10°C/min) to obtain the final N-TiO2/FM 
catalyst. The nominal loading of N-TiO2 on the FM support was 37.5 wt %.  

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2.3 Samples characterization 

Physico-chemical samples characterization has been performed with different techniques. Laser Raman 
spectra were obtained at room temperature with a Dispersive Micro Raman (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 micro-
diffractometer 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 
average size and morphology of the nanoparticles was measured by SEM (FE-SEM HR Zeiss Auriga 405).   

2.4 Photocatalysis tests  

The photocatalytic experiments were carried out with initial concentration of phenol equal to 25 mg L-1, at 
room temperature (25°C). The catalyst dosage was 3 g L-1. The total volume of phenol aqueous solution was 
80mL. The experiments were conducted using a pyrex cylindrical photoreactor (ID=2.5 cm, height=25 cm) 
equipped with an air distributor device (Qair=150 cm

3 min−1 (STP)). Continuous mixing of the aqueous solution 
was done by external recirculation of the same solution using a peristaltic pump. The photoreactor was 
irradiated with a strip composed of 25 Blue light LEDs (6W 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 30 min to reach phenol adsorption equilibrium, and then 
photocatalytic reaction was initiated under visible light for 180 min. The residual concentration of phenol in 
aqueous samples was monitored by observing the change in the absorbance at the maximum absorption 
wavelength of 270 nm using a UV–vis spectrophotometer (Lambda 35, Perkin Elmer), and then the 
concentration was calculated from a calibration curve. 

3. Results and Discussion 
3.1 Samples characterization 

Crystal phase composition and of N-TiO2, FM and N-TiO2/FM was determined by XRD and RAMAN. The XRD 
and RAMAN spectra are reported in Figure 1.  

(a)  (b) 
Figure 1: Catalysts XRD spectra (a) N-TiO2, FM and N-TiO2/FM and Raman spectra (b) N-TiO2, FM and N-
TiO2/FM 
 
XRD result of FM sample exhibited the presence of the the orthorhombic phase of Fe3O4 (Vaiano et al., 2016). 
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. The same composition 
and structure was confirmed by Raman analysis (Figure 1b). Anatase and Fe3O4 crystallite size of the 
samples were evaluated from XRD analysis, using the Scherrer equation. For N-TiO2, the anatase crystallite 
size was about 11 nm and slightly decreased (8 nm) after the deposition of N-TiO2 on FM. Fe3O4 particle size 
was found to be about 20 - 30 nm which corresponds to the determined average particle size by SEM 
measurement (Figures 2a and 2b).   
 

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 (a)    
                                                                            

 (b) 

Figure 2: N-TiO2 SEM (a) and N-TiO2/FM SEM (b). 

Figure 3a reports the UV–vis reflectance spectra in terms of Reflectance for N-TiO2. The shifting of the 
absorption onset from about 350 nm (for undoped TiO2) to about 550 nm (for N-TiO2) indicates the ability of 
the sample to absorb visible light, as confirmed by the results in Figure 3b, which is the typical absorption 
property of TiO2 doped with nitrogen (Vaiano et al., 2016). Composition of elements in N-TiO2 and N-TiO2/FM 
were checked by EDX- SEM characterization, reported in Figure 4. 

  (a)  (b) 

Figure 3: N-TiO2 UV-Vis DRS-Spectra (a) and N-TiO2 UV-DRS (band gap) (b) 

46



 (a)   (b) 

Figure 4: N-TiO2 EDX (a) and Fe/SiO2/N-TiO2 EDX (b). 

3.2 Photocatalytic activity results 

Preliminary experiments were carried out 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 (Vaiano et al., 2016). Therefore, photolysis phenomena did not occur. 
Figure 5a reports the photocatalytic activity of N-TiO2 and N-TiO2/FM.  
After 180 min of visible light irradiation, no photocatalytic activity was observed for FM sample (Vaiano et al., 
2016). On the contrary, both N-TiO2 and N-TiO2/FM catalysts were effective in the degradation of phenol in 
aqueous solutions. The degradation efficiency of N-TiO2 and N-TiO2/FM were 55% and 76%, respectively. 
These values are higher than those reported by other researchers, concerning the photocatalytic degradation 
of phenol under visible light irradiation (Vaiano et al., 2016). The higher photocatalytic activity of N-TiO2/FM 
compared to N-TiO2 particles could be attributed to the lower anatase crystallite size obtained with N-TiO2/FM 
sample. As the separability of photocatalysts from treated wastewater in a practical wastewater treatment 
system is very important, magnetic N-TiO2/FM sample was chosen for investigating the stability and efficiency 
after four reuse cycles (Figure 5b). The treated water containing N-TiO2/FM catalyst was collected into a 
beaker after each test cycle and the use of a magnet on the external surface of the beaker allows to easily 
separate the treated solution from the used photocatalyst. After washing with distilled water and drying at 
100°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 in 
the range 71-76 %. 

(a)  (b) 
 
Figure 5: Phenol photodegradation (a) N-TiO2 and N-TiO2/FM and reusability and efficiency of catalysts (b) N-
TiO2/FM  

4. Conclusions 
Nanocomposite N-TiO2/SiO2/Fe3O4 (N-TiO2/FM), which are visible-active and magnetically separable, was 
synthesized successfully 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 

47



and the average nanoparticle size of N-TiO2/FM magnetic core was about 26 nm, and composition was 
successfully checked by SEM-EDX. 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. After an irradiation time of 180 min, the experimental results showed that N-
TiO2/FM nanoparticles are effective in the removal of phenol, reaching a value of 76%. The results of visible 
active magnetic catalyst reuse showed the effectiveness of prepared samples after four cycles of repetitive 
use, evidencing phenol degradation in the range 71-76%. 

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