Photocatalytic performance of SiO2@TiO2 spheres in selective conversion of oxidation of benzyl alcohol to benzaldehyde and reduction of nitrobenzene to aniline

Abstract Selective photocatalytic oxidation of benzyl alcohol to benzaldehyde and reduction of nitrobenzene to aniline reactions are investigated by using SiO2@TiO2 spheres produced in a simple route using chitosan as a template. The spheres are predominantly macroporous and, the XRD points out an amorphous crystallographic profile suggesting the uniform distribution of TiO2. Under low-power lighting for 4 hours, the conversions achieved was of the order of 49% and 99% for benzyl alcohol and nitrobenzene, respectively, with selectivity to benzaldehyde and aniline of 99% in both reactions. The study also follows the effects of the solvent and the presence of O2.

However, the photocatalytic process can promote reduction or oxidation reactions with good selectivity (Imamura et al. 2013).Additionally, it is worth mentioning that the photocatalytic process neds mild temperature and pressure conditions (Fukui et al. 2019, Livingstone et al. 2019).This versatility contributes to the development of new studies that have led to the improvement of the photocatalytic technique as an innovative method in the field of fine chemistry, even enabling the use of renewable resources (solar radiation and biomass) as an energy source for the propagation of the phenomenon.
On the other hand, photocatalysis can selectively produce the conversion of the -CH 2 OH to -CHO group, enabling the production of compounds from the aldehyde group under mild conditions, which are widely applied as precursors of various medicines, vitamins, and fragrances (Pillai & Sahle-Demessie 2003).The conventional route of aldehyde production contributes to the release of metallic waste derived from the catalysts used, generating negative impacts on the environment (Xie et al. 2014).In the proposed photocatalytic mechanism for this reaction, one step is the reaction of the alcoholic substrate with the photogenerated positive holes ( h VB + ) and the molecular oxygen (O 2 ) acts as a photoelectrons acceptor (Turchi 1990).The photocatalytic oxidation selectivity is higher by using an organic solvent, such as acetonitrile.Using water produces hydroxyl radical, highly reactive (Spasiano et al. 2013).The O 2 , however, can generate the superoxide radical, hydrogen peroxide, and hydroxyl radical (Nosaka & Nosaka 2017).Therefore, to improve the photocatalytic selectivity, it would be interesting to use another photoelectron acceptor.
Aniline is a compound widely used to produce pharmaceuticals, dyes, pigments, and pesticides in laboratory and industrial scales (Corma et al. 2007, Wang et al. 2010).As with benzaldehyde, the industrial production route involves the release of waste containing metallic catalysts harmful to the environment.Furthermore, the traditional catalytic process (Ni, Pt, or Pd under H 2 pressure) leads to the hydrogenation of the phenyl group, resulting in a low selectivity (Shiraishi et al. 2012).Alternatively, photocatalysis can promote this reaction, which means to be possible to introduce a method with lower residues production.Therefore, the nitrobenzene reduction to aniline is an interesting process to act as a photoelectron acceptor.
Although both processes, the benzaldehyde and the aniline production, have been known for a long time (Buck et al. 1987, Lawrence 1983, Spiegler & Graham 1958), industrially a large amount of waste is still produced.These wastes require treatment, but sometimes they are often just stored, subject to possible environmental accidents.Thus, it is necessary to implement a production process for such products or their derivatives, which generates a lower amount of waste.
The need to decrease the environmental impact has encouraged research, either to explore the reaction or to test the photocatalytic activity of new materials for H 2 evolution or oxidation of organic pollutants (Fiorenza et al. 2019, Tahir & Tahir 2020, Wojtyła et al. 2020).But the low cost, no toxicity, and high oxidizing activity are properties that make the TiO 2 be widely used for photocatalytic process (Chen et al. 2010, Colmenares et al. 2016, Flores et al. 2007, Huang et al. 2010, Kominami et al. 2009, Palmisano et al. 2007b2006, Shiraishi et al. 2012, Zhang et al. 2009).
Generally, the TiO 2 is prepared as finely particulate material, which difficult the recovery for reusing (Horikoshi & Serpone 2020).To make more accessible the recovering process, the TiO 2 can alternatively be prepared as a supported catalyst (Fiorenza et al. 2019, Ho et al. 2019, Islam et al. 2020).With this goal in mind, numerous solid matrices have been used as support material for the active phase (Islam et al. 2020).But, SiO 2 has been pointed out as the most interesting support because it is chemically inert, transparent to UV radiation, and has a high surface area (Bellardita et al. 2010, Gude et al. 2008).Porous materials with a high surface area tend to increase the rate and amount of substrate adsorption, enhancing the TiO 2 performance of superficially exposed contact with the adsorbate.
Parallel to the supporting process, the pellet shape and diameter also can affect the catalytic performance.The synthesis route of macroporous spheres of SiO 2 or Al 2 O 3 presented previously  (Braga et al. 2009, Santos et al. 2015) may produce a sample with a spherical shape and diameter near 1.0 mm and easy separation process.Additionally, spheres with such a diameter range are easily kept in suspension in the reaction solution, either under the gas flow or under the solution flow itself.
The photocatalytic macroporous sphere was synthesized (SiO 2 spheres with a diameter near 1.0 mm containing TiO 2 ) by the method presented previously (Braga et al. 2009), aiming to explore the synthesis route.Additionally, with the aim to contribute to a lower reaction by-product formation, the sample was tested for the photocatalytic performance for benzyl alcohol oxidation and the nitrobenzene reduction reactions.

MATERIALS AND METHODS
Preparation of the SiO 2 @TiO 2 spheres The SiO 2 spheres were synthesized using the hybrid system, SiO 2 precursors, and chitosan (Braga et al. 2009).Under continuous stirring, the chitosan (CTS) (3% m/v) was dispersed in an aqueous solution of acetic acid (5% v/v).Following, equimolar amounts of particulate SiO 2 (Aerosil, Degussa Evonik) and tetraethylorthosilicate (TEOS, Aldrich) were added in the same solution, yielding a molar ratio of 1:1.5 between CTS monomer to Si.This mixture was dripped in an alkaline medium (NH 4 OH, 30%) using a peristaltic pump.The formed spheres were removed and dried at room temperature for 72 hours.The hybrid spherical material was calcined at 550 °C for 3 hours using a heating rate of 5 °C/min.The surface coating of the silica spheres with titanium was made from the wet impregnation of its organic precursor, where 1.0 mL of titanium isopropoxide (Aldrich) was added to 25 mL of isopropyl alcohol containing 1.0 g of the silica spheres, keeping the contact under constant stirring for 24 hours.After the spheres drying at room temperature for 24 hours, the calcination was again carried out at 500 °C for 3 hours to form the crystalline TiO 2 ; the sample was named SiO 2 @TiO 2 .

Characterization of the SiO 2 @TiO 2 spheres
The X-ray diffraction (XRD) measurement was performed in the angular range (2θ) of 10-90° with Cu Kα, 40 kV and 45 mA.The N 2 adsorption/desorption isotherm was carried out after degassing for 2 hours under vacuum at 200 °C.The scanning electron micrographs, energy dispersive spectroscopy coupled (SEM-EDS) analysis was performed at 10 kV and 2.27 x 10 -7 Pa.Samples were placed in a double-sided carbon tape on aluminium support and metalized with gold in an argon atmosphere at low pressure.The diffuse reflectance spectrum (DRS-UV-vis) was measured in a 300 to 800 nm scanning range.

Photocatalytic Conversion Experiments
The selective photocatalytic conversion reactions of benzyl alcohol to benzaldehyde and nitrobenzene to aniline were performed in a glass reactor with a quartz tube located in the centre using magnetic stirring.A high-pressure mercury lamp (8 W, 315-420 nm, maximum wavelength at 365 nm) was used as an irradiation source.The reaction mixture comprised 0.25 g of SiO 2 @TO 2 spheres with 25 mL of a solution containing the organic compound.For the photocatalytic oxidation reactions, the initial concentration of benzyl alcohol was 10 -3 mol/L, while in the photocatalytic reduction reactions, the initial concentration of nitrobenzene was 8.0 x 10 -4 mol/L.In both reactions, the solvents were  (2023) 95(2) e20220105 4 | 22 pre-saturated for 30 minutes with O 2 or N 2 for favouring oxidative or reducing conditions, respectively.The system was kept under magnetic stirring for 1 hour before turning on the lamp to achieve the adsorption equilibrium.The monitoring of composition was done by HPLC using a C18 column (5μ, Phenomenex) at 210 nm.The mobile phase was composed of methanol, water, and buffer solution in a ratio of 40:20:40 and a flow rate of 1.0 mL/min.The buffer was prepared with 10 mL of H 3 PO 4 (5.05 mol/L), 50 mL of methanol, and ultra-pure water, for a total volume of 1 L. To evaluate the isolated effects, TiO 2 powder (P25, Degussa, 0.025 g) and SiO 2 sphere (without titanium dioxide) were tested under the same reaction conditions.

X-ray diffraction
Figure 1 shows the diffraction profile of the silica spheres (SiO 2 ) before and after titanium coating (SiO 2 @TiO 2 ).Both samples show no clear diffraction peak.However, it is observed a broad signal in the 2θ degree range of 15 to 30, which is typical for the SiO 2 samples material heat treated at low temperature (550 °C) (Matos et al. 2011, Pan et al. 2008).Despite that, the diffraction profile for sample SiO 2 @TiO 2 shows a smooth enlargement of the broad signal (emphasized in the inserted figure), which can be attributed to the formation of the tetragonal anatase phase according to the diffraction pattern (ICSD code of 9854) inserted in Figure 1.
In a previous study developed by the authors (Salgado & Valentini 2019), an apparent surface coverage of 13.2% of TiO 2 on the surface of the SiO 2 spheres was estimated through the surface charge (point of zero charge) of SiO 2 , TiO 2 and SiO 2 @TiO 2 .The absence of a defined peak demonstrating the presence of TiO 2 can be attributed to the morphological characteristics inherent to the process of synthesis of silica spheres, contributing to a reduced adsorption of the Ti precursor and consequent growth of the TiO 2 particle.

Diffuse reflectance
The optical property of the SiO 2 @TiO 2 spheres was determined by diffuse reflectance spectroscopy, as shown in Figure 2. The spheres impregnated with titanium on their surface have an absorption band in the UV region, which is attributed to the charge transfer process of the valence band of the 2p orbital of the O 2-ions to the conduction band of the t 2g orbitals of the Ti 4+ (Loddo et al. 1999).The bandgap determination of the photocatalyst can be performed by applying the Kubelka-Munk function ([1-R] 2 /2R) to the reflectance spectral data of the material.Knowing that the TiO 2 phase has a direct bandgap (Yu et al. 2011), the bandgap value is obtained from the intercept of the graph generated by [F(R) hv] 2 vs. hv.The SiO 2 @TiO 2 spheres show 3.33 eV, near the value determined for the P25 (3.22 eV), which is close to the anatase phase of TiO 2 (3.2 eV) (Jaroenworaluck et al. 2012, Mahesh et al. 2015).
Considering the negligible absorption of silica (SiO 2 ) in the range from 250 to 700 nm, as shown in Figure 2, the behavior presented in the diffuse reflectance spectrum is attributed exclusively to TiO 2 .The potentials of the valence (BV) and conduction (BC) bands can be calculated through the Mulliken electronegativity and band-gap of the semiconductor (Cheng et al. 2019), according to equations 1 and 2.
Where E g , E VB e E CB are the band-gap and potentials of the valence and conduction bands of the semiconductor, respectively, E e is the energy of free electrons of the hydrogen scale (4.5 eV), and X is the absolute electronegativity (Mulliken) of the atom semiconductor, expressed as the geometric mean of the absolute electronegativity of the constituent atoms, which is defined as the arithmetic mean of the atomic electro affinity and the first ionization energy.
Considering the band-gap of 3.3 eV (Fig. 2) and the X value for TiO2 of 5.81 eV, the calculated values of E VB and E CB for the SiO2@TiO2 spheres were 2.96 and -0.34 eV.

Textural properties and chemical composition
The specific surface area and pore size distribution of the spheres were determined by adsorption/ desorption isotherms of N 2 (Figure 3, Table I).The spheres have isothermal profiles typical of types II and III, besides indicating the formation of pores in the form of slits characteristic of the hysteresis of type H3 (Thommes et al. 2015).In both samples, SiO 2 and SiO 2 @TiO 2 , the pore diameter distribution profile show the presence of micropores (< 2 nm) and mesopores (pores 2-50 nm), but with a predominance of macropores (> 50 nm), as indicated by the isothermal profiles.
The addition of titanium on the silica spheres caused a considerable effect on the surface area, decreasing from 317 to 147 m 2 /g.Similarly, as points out the pore size distribution (inserted in Figure 3), it is also observed effect over the pore volume, which decreases from 2.402 to 1.191 cm 3 /g; due to Ti impregnation.However, there was no change in the pore distribution profile.This fact suggests a homogeneous distribution of TiO 2 across the surface of SiO 2 , both in the micropores and in the macropores.The SiO 2 @TiO 2 spheres were analyzed for morphology and composition by scanning electron microscopy (Figure 4).The synthesized material showed spherical morphology with an average diameter of 1 mm (Figure 4a), which is a pellet diameter easier to recover from the reactional solution.-c show the surface sphere morphology, which is composed of interconnecting platelets.This aspect is due to the synthesis route, which uses TEOS and particulate SiO 2 (Aerosil).The TEOS undergoes hydrolysis and then reacts with the SiO 2 particle surface (platelet) at the silanol group, linking the platelets and producing a sample with high pore volume and pore diameter (Table I).

Figures 4b
The results of elemental mapping by EDS indicate that the proposed synthesis methodology led to a homogeneous deposition of Ti on the surface of SiO 2 spheres (Figure 4f).The Figures 4g-h show the presence of residual carbon (near 9 wt%), despite the calcination at 550 °C/3h, this is consistent with previous results which shows mass elimination up to 600 °C (Braga et al. 2009), it is important to point out that the second calcination temperature, after the titanium isopropoxide impregnation, the sample was calcined at 500 °C.Considering the platelet condensation, it is reasonable to propose retaining a small fraction of carbon in the pore of the material or between the platelets.

Photocatalytic oxidation of benzyl alcohol to benzaldehyde
Several authors reported the photocatalytic partial oxidation of alcohols to aldehyde (Augugliaro et al. 2008, Li et al. 2012, Palmisano et al. 2007b;Spasiano et al. 2013, Xie et al. 2014).The reaction is called selective photocatalytic conversion or partial photocatalysis (Augugliaro et al. 2008), which has emerged as a vital field in the photocatalytic area for 'green synthesis' in fine chemistry and efficient energy conversion since it produces a useful compound (-CHO) instead of its decomposition (CO 2 and H 2 O).
The photocatalytic conversion of benzyl alcohol to benzaldehyde is possible due to the higher standard potential of the TiO 2 valence band (2.96 V) compared with the oxidation reaction (Eq.3) (Xiao et al. 2013): Figure 5 shows the O 2 effect over the conversion of benzyl alcohol to its corresponding aldehyde (benzaldehyde), using acetonitrile as solvent.A test was carried out under the same conditions without catalyst (SiO 2 @TiO 2 ) with the presence of O 2 , in which conversion of benzyl alcohol was not observed.The replacement of O 2 with N 2 leads to a decrease in both the conversion rate of benzyl alcohol (48.7% to 22.3%) and the rate of production of benzaldehyde (45.2 to 20.9%) (Figure 5), suggesting that O 2 plays an essential role in the photocatalytic oxidation of benzyl alcohol.This fact is consistent with the fundamental reactions of the photocatalytic process, where the molecular O 2 adsorbed on the surface of the photocatalyst act as an electron acceptor, favouring the separation of the electron/hole pair, leading to the maintenance of the photocatalyst in its excited state.Similar results are reported (Xiao et al. 2013), where a conversion rate of the same order was achieved using a photocatalyst of composition Bi 12 O 17 Cl 2 under irradiation in the visible range.
Despite the effect over the benzyl alcohol conversion, the O 2 replacement with N 2 has no impact on the selectivity of the reaction to produce benzaldehyde, reaching levels of 100%.
Figure 6 shows the solvent effect.The replacement of acetonitrile by water under the same reaction conditions shows that the presence of water assumes high relevance in the photocatalytic oxidation of benzyl alcohol.The reaction performed with water presence resulted in a higher conversion of benzyl alcohol, reaching reduction levels of 54.8% in their concentration.However, this conversion did not produce a stoichiometric amount of its corresponding aldehyde, getting    2014) found a similar result, where a photocatalyst composed of In 2 S 3 was used in the selective oxidation of benzyl alcohol to benzaldehyde under visible light irradiation in the presence of O 2 in four solvents: trifluorobenzene (TFB), toluene (TOL), acetonitrile (ACN) and water (H 2 O).The researchers found a strong effect of the solvent polarity on the reaction performance, where, in terms of production and selectivity, the solvents were ordered as follows: TFB > TOL > ACN > H 2 O.The best performance of the photocatalyst in trifluorobenzene was ascribed to a higher solubility of O 2 .While the water using as solvent affect the performance of the photocatalyst negatively.This fact is due to the production of highly reactive radical species ( OH • ), which reacts non-selectively with the adsorbed organic substrate.Consequently, the photocatalytic conversion increase but loses in terms of production and selectivity.This finding is strengthened by the production of benzoic acid with water as the solvent, which suggests the occurrence of reactions in series due to the constant nonselective attack of hydroxyl radicals to benzyl alcohol and benzaldehyde.
In reaction condition with O 2 and acetonitrile as the solvent, the silica spheres without titanium did not show photocatalytic activity.At the same time, using TiO 2 powder (P25) led to the conversion of 62% of benzyl alcohol and production of 45% to benzaldehyde.Despite the greater conversion capacity of TiO 2 into powder, the selectivity to benzaldehyde was lower, in addition to the fact that the application in powdered form confers a dispersion of particles that do not sediment under the action of gravity, imposing the need for one more step for recovery of the catalyst.
Figure 7 compares the photocatalytic performance of the SiO 2 @ TiO 2 spheres in the oxidation of benzyl alcohol to benzaldehyde under different experimental conditions.
A comparative analysis of the data presented in Table II allows concluding that the SiO 2 @ TiO 2 beads showed photocatalytic efficiency in the oxidation of benzyl alcohol to benzaldehyde, obtaining conversion and selectivity values similar to those reported by other researchers when using acetonitrile as solvent.The performance of the SiO 2 @TiO 2 spheres in the photocatalytic oxidation of benzyl alcohol is even more evident when comparing the power of the irradiation source used (8 W), which is much lower than the other works.Taking into account the experimental data obtained and based on studies reported by other researchers (Feng et al. 2011, Xie et al. 2014, Zhang et al. 2009), a reactive scheme is proposed, presented in the following topics and demonstrated in Figure 8: 1. Alcohol molecule adsorbs on the surface of the beads via a deprotonation process, which reacts with the photogenerated hole ( h VB + ) to form a carbonic radical via subsequent deprotonation.
2. In the absence of oxygen, carbon radical loses another electron by reacting again with the hole, leading to the formation of benzaldehyde.

Photocatalytic reduction of nitrobenzene to aniline
The photocatalytic reduction of nitrobenzene to aniline has attracted attention because of the advantages presented in comparison with traditional methods of aniline synthesis, such as room temperature reaction, lower operational costs, and environmental benefits resulting from the significant decrease in waste production (Mohamed & Kadi 2014).In this work, some factors, such as solvent composition and O 2 presence, which affect the performance of the photocatalyst in the reduction reaction of nitrobenzene were evaluated.
Figure 9 shows the O 2 effect over the photocatalytic performance for the reduction of nitrobenzene using methanol as solvent.The presence of O 2 in the medium resulted in a decrease in nitrobenzene conversion levels and aniline production but did not affect selectivity (>99%).The decrease of the reaction rate is due to the competitive effect between nitrobenzene and O 2 by the electrons of the conduction band of the photocatalyst.When adsorbed, O 2 will act as an electron acceptor, with the production of O 2 •− radical.Kominami et al. (2009) using TiO 2 presented similar results in the photocatalytic reduction of nitrobenzene in an aqueous medium with the addition of oxalic acid as a hole sequestrant.Additionally, the same authors observed that the O 2 partial pressure increase affects the aniline production.
The effect of the solvent composition was evaluated by carrying out photocatalytic reduction tests of nitrobenzene in methanol or ethanol previously saturated with N 2 (Figure 10).
The reducing reaction of nitrobenzene to aniline shows a meaningful effect of the solvent over the photocatalytic performance.By using methanol, the reaction reached higher conversion levels of nitrobenzene and aniline production if compared with the reaction in ethanol medium.Despite the different performances regarding conversion and production, in both solvents, the selectivity was >99% for aniline and no other product of the reaction was identified.This fact is due to the properties of the solvent, such as viscosity and polarity/polarizability, i.e., the ability of a solvent to stabilize a charge or a dipole through its dielectric constant.An increase in polarity/polarizability corresponds   to better stabilization of the charged intermediate species produced, causing an increase in the reaction rate (Palmisano et al. 2007a), which justifies the best performance in methanol medium, given its lower viscosity and higher dielectric constant compared with ethanol.A similar result was reported by Chen et al. (2010) in the photocatalytic reduction of nitrobenzene by TiO 2 , where isopropanol was also tested as solvent.These researchers ordered solvents for the performance of the photocatalyst as follows: isopropanol < ethanol < methanol.
On the other hand, it should be considered that the pKa for ethanol (16.0) is higher than methanol (15.5).Therefore, if the proton abstraction from the alcohol is one-step of the process, this short difference between acidity can affect the process.
In addition to alcoholic solvents, the photocatalytic reduction of nitrobenzene was also performed in the aqueous medium.In this condition, no reduction of nitrobenzene concentration was observed, as there was no aniline production.However, the use of acetonitrile promoted a 97% conversion, with a selectivity of 40%.This fact reinforces the effect of the solvent on the development of the photocatalytic process in question.The reduction of nitrobenzene occurs by the electrons present in the conducting band of the photocatalyst, and the photogenerated holes will act in an antagonistic way to the objective of the reaction since they have oxidative properties.As the oxidation potential of the holes present in the valence band is much higher than the reduction potential of the electrons in the conduction band, substances, which are able of inhibiting the action of the holes, must be added.In this sense, methanol will capture photogenerated holes, acting as electron donors, preventing the recombination of the electron/hole pair (Imamura et al. 2013) and inhibiting oxidation reactions.
In reaction condition with N 2 and methanol as solvent, the silica spheres without titanium did not show photocatalytic activity.TiO 2 (P25) powder led to 99% conversion and selectivity of 97.6%.
Table III shows results reported by several authors regarding the application of different photocatalysts in the synthesis of aniline via reduction of nitrobenzene.As shown above, although the reaction time was higher than the other studies, a complete conversion of nitrobenzene to aniline was achieved using a much lower energy source (8 W); for example, when comparing with the work of Huang et al. (2010) where a Xe lamp of 2,000 W was used.
Figure 11 shows a comparative analysis of the performance of the photocatalyst in the different experimental conditions.
Based on the experimental data obtained in this study and on information extracted from studies reported by several researchers (Flores et al. 2007, Jensen et al. 2016, Mohamed & Kadi 2014, Qusti et al. 2014), a reaction mechanism of photocatalytic reduction of nitrobenzene to aniline was proposed, which is detailed in the following topics: The reaction between methanol and photogenerated hole, producing formaldehyde and H reductor, according to reactions below:

NB + 2H
2. The NB-N •-OH radical is produced from the reduction of the NSB, yielding the intermediate phenylhydroxylamine (PHA).
3. PHA undergoes another electron transfer, producing the radical NB-N •-OOH, which is easily converted to the aniline (AN).Figure 12 represents the aforementioned topics.
According to Flores et al. (2007) the excess of alcohol solvent used in the experiments and the anaerobic conditions and long periods of irradiation support the hypothesis that the photocatalytic reduction of nitrobenzene occurs mainly by hydroxyalkyl radicals derived from methanol (reaction 3), justifying the occurrence of reaction 8, since the value of the TiO 2 conduction band potential (0.34 V) is not able to lead to the reduction of phenylhydroxylamine to aniline.However, the direct reaction between the electron-accepting substrate (nitrobenzene) and the electrons in the conducting band of the photocatalyst (TiO 2 ) should also contribute to a significant production of aniline.

Photocatalytic benzyl alcohol oxidation with simultaneously nitrobenzene reduction
The photocatalytic performance study of SiO 2 @TiO 2 spheres in simultaneous conversion via oxidation and reduction of benzyl alcohol and nitrobenzene, respectively, was performed in the presence of acetonitrile as a solvent with an initial concentration of 1.0 x 10 -3 mol/L for both organic compounds.The choice of acetonitrile as a solvent was based on the results presented above.Before lamp activation, the solution was saturated with N 2 to eliminate O 2 and favor nitrobenzene as a species to be reduced by electrons ( e CB − ), and the performance of the material in this condition is shown in Figure 13.The kinetic profiles presented in Figure 13 show a selective photocatalytic performance to the oxidation of benzyl alcohol over nitrobenzene reduction, showing a decrease in alcohol concentration and proportional production of its respective aldehyde, while for nitrobenzene no change of its concentration was detected and, obviously, without aniline production.As discussed earlier, TiO 2 has a hole ( h VB + ) with much greater potential than the electrons present in the conduction band ( e CB − ), giving the material a predominantly oxidizing characteristic.Besides, the experiment was carried out under identical concentrations of the two substrates with acetonitrile as the solvent, unlike isolated nitrobenzene reduction assays, which occurred under the presence of alcoholic solvents.This fact reinforces the need for a sacrificial agent (alcohol solvent) to inhibit the oxidative activity of the holes and to favor photogenerated electrons to promote reduction reactions with TiO 2 .

Figure 7 .
Figure 7. Photocatalytic oxidation of benzyl alcohol to benzaldehyde using SiO 2 @TiO 2 spheres under different reaction conditions.

3.
In the presence of O 2 , the superoxide radical formed by the reduction of O 2 in the excited TiO 2 conduction band reacts with the carbon radical, forming an intermediate oxygen bridge structure.The formation of the superoxide radical on the surface of SiO 2 @TiO 2 was confirmed in a previous study (Salgado & Valentini 2019) with the use of benzoquinone as a sequestering agent.4. Cleavage of the C-O of the alcohol and O-O of O 2 bonds leads to benzaldehyde formation.The bridged structure of the peroxide bond of TiO 2 can combine with protons to form H 2 O 2 .In a study performed by Zhang et al. (2009) using oxygen isotopes, it was demonstrated that in the presence of O 2 , the O atom of the aldehyde did not originate from the water surface adsorbed or OH groups of TiO 2 , but from O 2 , indicating an important role of this species when present in the photocatalytic process.

Figure 8 .
Figure8.Proposed reaction pathway for selective photocatalytic oxidation of benzyl alcohol to benzaldehyde in the presence of SiO 2 @TiO 2 spheres with and without O 2 presence.Adapted from(Feng et al. 2011, Li et al. 2012, Xie et al. 2014, Zhang et  al. 2009).

Figure 11 .
Figure 11.Photocatalytic reduction of nitrobenzene to aniline using SiO 2 @TiO 2 spheres under different reaction conditions.

Table I .
Specific surface area and pore volume of the spheres from N 2 adsorption/desorption isotherms.

Table II .
Comparison of conversion and selectivity of photocatalytic oxidation of benzyl alcohol to benzaldehyde in different studies.

Table III .
Conversion and selectivity of the photocatalytic reduction of nitrobenzene to aniline in different studies.