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ORIGINAL RESEARCH article

Front. Chem., 22 August 2018
Sec. Catalysis and Photocatalysis

Insights Into the Sunlight-Driven Water Oxidation by Ce and Er-Doped ZrO2

\r\nSimelys Hernndez*Simelys Hernández1*Chiara Gionco*Chiara Gionco2*Thomas HusakThomas Husak1Micaela CastellinoMicaela Castellino3Jos A. Muoz-TabaresJosé A. Muñoz-Tabares3Kristine R. Tolod,Kristine R. Tolod1,4Elio GiamelloElio Giamello2Maria C. PaganiniMaria C. Paganini2Nunzio RussoNunzio Russo1
  • 1CREST Group, Department of Applied Science and Technology (DISAT), Politecnico di Torino, Turin, Italy
  • 2Department of Chemistry, University of Torino, Turin, Italy
  • 3Center for Sustainable Future Technologies (CSFT), Istituto Italiano di Tecnologia, Turin, Italy
  • 4Ecole Doctorale de Chimie, Université Claude Bernard Lyon 1, Lyon, France

In the present work, the activity of Ce and Er-doped ZrO2 nanopowders for sun-driven photocatalytic water oxidation has been investigated. ZrO2 powders with tunable amounts of tetragonal, monoclinic and cubic polymorphs have been synthesized by introducing Ce and Er (from 0.5 to 10 mol % on an oxide basis) through hydrothermal method. The aim of this work is to investigate the role of rare earth (RE) ions rich of electrons (Er3+) and with entirely empty levels (Ce4+) in the ZrO2 matrix for the sun-driven photocatalytic water oxidation reaction. The samples have been characterized by means of UV-Vis spectroscopy, X-Ray diffraction (XRD), N2 adsorption, X-ray photoelectron spectrophotometry (XPS) and transmission electronic microscopy (TEM) with energy dispersive spectroscopy (EDS). With respect to the bare ZrO2 mainly containing monoclinic (m-) phase, an increasing amount of rare-earth (RE) dopant was found to improve the specific BET surface area and to stabilize the tetragonal (t-) or cubic (c-) polymorphs of ZrO2 at room temperature. XRD data confirmed that dopants were mainly inserted in the t-ZrO2 phase. The photocatalytic O2 evolution from water under AM 1.5 G simulated sunlight illumination of the prepared samples have been correlated with their optical, structural and chemical properties. The effect of the dopant concentration on the chemical-physical and photocatalytic properties of the Er- and Ce-doped ZrO2 materials was elucidated. The samples with 5% of RE oxide were the most active, i.e., three times more than pure zirconia. Their superior photocatalytic activity was found to be mainly correlated to two factors: (i) an optimal surface concentration of RE ions of about 3.7%, which increased charge carriers separation in the photocatalysts surface due more superficial defects of the t-ZrO2 and a higher surface area, thus enhancing the reaction kinetics, (ii) a controlled amount of monoclinic vs. tetragonal (or cubic) polymorphs of zirconia with an optimum ratio of about 70/30 of t-ZrO2/m-ZrO2. Instead, the increased ability of the RE-doped ZrO2 to harvest visible light was found to have a secondary role on the photocatalytic activity of the Ce-doped ZrO2 material.

Introduction

It is nowadays a scientific goal to develop clean energy technologies that satisfy the growing energetic demand and reduce the economic and environmental impacts of the use of fossil fuels at a global scale. Since solar radiation on the earth's surface has the potential to provide 2,850 times the current global energy needs (Ellabban et al., 2014), it pushes the idea of improving solar-driven systems for energy production and storage.

Several efforts have been done in the research community to enhance the performance of photocatalytic systems that are able to exploit solar-light irradiation for industrial applications such as pollutant abatement (Suib, 2013) and solar fuels production (Maeda and Domen, 2010). The latter process can be achieved by photocatalytic water splitting with the production of O2 and H2, or other C-containing fuels if the reducing power is used to directly reduce CO2. With respect to the hydrogen evolution half-reaction, water oxidation to O2 is more challenging because it is an up-hill reaction that involves multiple proton-coupled electron transfer processes (Armandi et al., 2013) and is considered as the bottleneck of the whole water splitting process.

The fundamental characteristic of a photoactive material (e.g., metal oxides or semiconductor photocatalysts) is that it can generate electric potential by using light as energy source. To photoexcite a photocatalyst and produce electron-hole pairs with enough oxidation and reduction potentials, the absorbed photon energy (hv) must be higher than its band gap energy (Eg). Hence, the so-called first generation photoactive materials have been metal oxides or semiconductors with large band gaps and favorable flat band potentials for photocatalytic reactions, e.g., TiO2. However, most of them absorb only high-energy photons, i.e., UV light, which limits the utilization of solar energy to about 4%. On the other hand, semiconductors with a narrow band gap, compatible with visible light absorption, often may not generate sufficient potential for oxidation and reduction reactions.

One approach used in a second generation photoactive materials to overcome these limitations was tuning the band gap energy of semiconductors, mainly TiO2, by cation or anion doping in order to increase their visible light absorption by creating intra-band gap states near the top of the valence band or the bottom of the conduction band (Emeline et al., 2012). However, in most of the cases paradoxical consequences have been observed: (a) reduction of the photoactivity by extension of absorbance to the visible spectral region; (b) decrease of chemical activity of surface-active centers formed under visible light in comparison to those formed under UV illumination (Emeline et al., 2012). There are some examples in which anatase and rutile phases of TiO2 doped with metals such as Bi (Naik et al., 2011) and Mo (Li et al., 2011) have reported improved activity for photocatalytic water splitting under visible light irradiation by up to three times, but low productivities for H2 evolution have been reached.

A way to produce a next generation of photoactive materials is through band gap engineering of semiconductors with a high band gap, leading to the formation of new mid-gap states, either empty or partially populated. In that way, electron photoexcitation by low energy photons is promoted, but it is required that charges recombination involving such dopant band states have to be negligible (Emeline et al., 2012). To satisfy this condition, the energy difference between intrinsic bands and dopant band positions must be larger than 2 eV to efficiently avoid band-to-band non- radiative recombination. Modification of TiO2 (Eg ≈ 3.2 eV) often cannot guarantee an optimum photochemical response; therefore, wider band gap metal oxides like ZrO2 (Eg ≈ 5 eV) should be considered as an appropriate matrix to be modified for developing this new kind of visible light active photocatalysts (Emeline et al., 2012).

In the past decade, attention has been paid to the development of third generation visible-light-active photocatalysts based on ZrO2 due to its suitable flat band potentials for many reduction and oxidation reactions, low cost and high thermal and chemical stability (Ni et al., 2007). For instance, rare earth metals [e.g., Ce, (Gnanamoorthi et al., 2015), Er, Yb (Meza et al., 2010), Y, Eu, Sm and Tb (Bugrov et al., 2016)] have been employed to modify the microstructural and optical properties of ZrO2. Moreover, ZrO2 powders doped with metals, i.e. Ce and Er (Gionco et al., 2016), and non-metals, i.e. C (Poungchan et al., 2016) and N (Sudrajat et al., 2016), as well as ZrO2/graphene composites (Rani et al., 2016), have demonstrated photocatalytic activity for dyes degradation (such as methylene blue or rhodamine B) under visible light irradiation. Sun driven photocatalytic water splitting for direct H2 production from aqueous solutions, of methanol or isopropyl alcohol, has also been proved by using oxygen-deficient black ZrO2−x (Sinhamahapatra et al., 2016) and ZrO2-Me2O3 system (where Me = Y, Eu, Tb, Sm, Er) (Bugrov et al., 2016). However, for the best of our knowledge, there are no works in which the photocatalytic water oxidation under sunlight irradiation have been demonstrated with modified ZrO2 samples.

In recent works (Gionco et al., 2014, 2015), some of us have shown that the dispersion of small amounts (0.5 mol %) of Ce ions in the ZrO2 matrix significantly modify its optical properties, becoming photoactive in visible light (at wavelengths higher than 420 nm). Further studies (Gionco et al., 2016) have shown that not only Ce but also Er doping (up to 5 mol %) improved the photoactivity of ZrO2 for methylene blue removal in aqueous solution under visible light. These evidences suggested further research on rare earth-doped ZrO2 as a potential photocatalyst for solar-driven water splitting applications.

In the present work, the activity of RE-doped ZrO2 powders for sun-driven photocatalytic water oxidation has been investigated. In accordance to our previous works (Gionco et al., 2014, 2016), ZrO2 powders containing Ce and Er (from 0.5 to 10 mol % on a RE oxide basis) have been synthesized by hydrothermal method, with the aim of testing ions rich of electrons (Er3+) and with entirely empty levels (Ce4+). The chemical, structural and optical properties of the samples have been fully studied by means of UV-Vis spectroscopy, X-Ray diffraction (XRD), N2 adsorption, field emission scanning electronic microscopy (FESEM) with energy dispersive X-ray spectroscopy (EDS), transmission electronic microscopy (TEM), and X-ray photoelectron spectrophotometry (XPS). Finally, the photocatalytic results have been correlated with the physico-chemical properties of the ZrO2-based samples, in order to elucidate the effect of the Ce and Er dopants concentration on the performance of this third generation photocatalysts for the sun-driven water oxidation reaction in the presence of an electron acceptor.

Experimental

Synthesis of ZrO2-Based Powders

Pure ZrO2 and RE-doped ZrO2 samples with a molar percentage of dopant of 0.5, 1, 5, and 10%, calculated on a rare earth oxide (REO) basis, were synthesized according to a published hydrothermal procedure with few modifications (Gionco et al., 2015). All reactants were purchased from Sigma-Aldrich. No further purification treatments were done before employing the reactants.

RE-doped materials were prepared starting from a 1.0 M aqueous solution, containing ZrOCl2·8H2O and Ce(SO4)2 or Er(NO3)3·5H2O in stoichiometric ratio. The pH of the solution was then adjusted to 11 by adding 4.0 M NaOH aqueous solution. The resulting gel was transferred into a 125 ml Teflon-lined stainless-steel autoclave. The autoclave was filled up to 70% of the total volume and then heated in an oven at 175°C overnight. The obtained precipitates were centrifuged and washed three times with deionized water. Lastly, the samples were dried at 60°C, then grounded and calcined at 500°C for 2 h.

Each sample was labeled according to its REO (CeO2, Er2O3) content, by using Z for ZrO2, C for CeO2, and E for Er2O3. The numbers in the label indicates the molar percentage of REO over ZrO2.

Physico–Chemical Characterization

Semi-quantitative chemical composition analyses of the photocatalysts were evaluated by using a field emission scanning electronic microscope (FESEM, Zeiss Merlin) equipped with an electron energy-dispersive X-ray spectroscopy (EDS, Oxford X-Act) detector. EDS data was acquired on two different spots of each sample and the results are reported considering the standard deviation of those measurements.

A PHI 5000 Versaprobe scanning X-ray photoelectron spectrometer (monochromatic Al Kα X-ray source with 1486.6 eV energy), was employed to check the superficial composition of the samples. High resolution (Pass energy: 23.5 eV) and survey spectra (Pass energy: 187.85 eV) were collected by using a beam size of 100 μm. A combination of an electron gun and an Ar ion gun was used as neutralizer system to compensate the positive charging effect during the measurement. Fitting procedure and deconvolution analyses were done by using the Multipak 9.6 dedicated software. All core level peak energies were referenced to C1s peak at 284.5 eV (C-C/C-H sp2 bonds).

Insights into the crystalline structure of the ZrO2 powders were obtained through X-Ray Diffraction (XRD) by using a PANalytical PW3040/60 X'Pert PRO MPD with a copper Kα radiation source (0.15418 nm) and Bragg Brentano geometry. X'Pert High-Score software was used for data handling. The diffraction patterns were processed with the Rietveld refinement method to determine the crystallite size and relative abundance of phases using the MAUD 2.2 software (Lutterotti, 2010). In addition, both morphology and crystalline structure of the ZrO2 samples were also characterized by means of transmission electron microscopy (TEM) made with a FEI Tecnai F20ST operating at 200 kV. For the TEM analyses, the powders were dispersed in ethanol (purity >99.8 %, Sigma-Aldrich) by sonication for 5 min and then put in a TEM grid.

Diffuse Reflectance Spectroscopy (DRS) data were recorded by using a Varian Cary 5000 spectrometer, coupled with an integration sphere for diffuse reflectance studies, using Cary win UV/scan software. A sample of PTFE with 100% reflectance was used as reference.

Specific surface area of all the samples was calculated from N2 adsorption measurements of 9 p/p0 points carried out with a Micromeritics ASAP 2020 instrument and by using the Brunauer-Emmett-Teller (BET) model. Prior to the adsorption run, all the samples were outgassed at 300°C for 3 h.

Photocatalytic Water Oxidation Tests

A custom device was used for the photocatalytic water oxidation experiments (see Figure 1), consisting of a stirred bubbling reactor system, described in detail in previous works (Thalluri et al., 2014). In these tests, O2 concentration was measured online in both liquid and gas phases by means of a Clark electrode (Mettler Toledo InPro 6050/120) and a micro-Gas Chromatograph (Varian 490-GC equipped with a 10 m Molsieve 5A column and a micro-TCD), respectively. Inlet temperature and pressure were also checked, in order to maintain constant operational conditions as well as assuring the absence of leakages in the system.

FIGURE 1
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Figure 1. Photocatalytic bubbling reactor used for the water oxidation experiments.

The same quantity of catalyst was used for each photocatalytic test, corresponding to 100 mg of powder. The bubbling reactor was partially filled with 110 ml of AgNO3 50 mM solution, which was used as electron acceptor to assess O2 evolution from water oxidation reaction. Then, the photocatalyst powders were dispersed in the liquid phase, thus resulting in a concentration of 0.91 gcatalyst/lsolution. A temperature range between 16 and 18°C was maintained in the liquid phase by using a cooling jacket. The solution pH varied between 5.5 and 7.0, depending on the tested photocatalyst. The stirring rate was set at 1,300 rpm and an overpressure of 300 mbar was kept inside the reactor during all the experiments.

At the beginning of each test, the air inside the system was purged with Ar gas up to concentrations of around 0.04 mg/l of O2 in the liquid phase. Then a stripping Ar was fixed at a flow rate of 18 Nml/min, by using a Bronkhorst Mass Flow Controller. A solar-light simulator with AM 1.5G spectra, model LIFI STA-40 by LUMIX (courtesy of Solaronix), was used to irradiate the reactor during a period of 70 min. The incident light irradiance was measured to be 100 mW cm−2 (1 sun) by using a photo-radiometer by Delta Ohm. Experimental data (dissolved O2, pH, temperature and pressure) were recorded by means of a LabView-based software each 4 s. Outlet gas was analyzed with the micro-GC and recorded by means of Galaxy software, which was used to register the oxygen concentrations in the gas phase each minute. The O2 flow produced during the reaction was calculated from micro-GC analyses every minute during the time course of the tests (see Figure S1). All the tests were repeated twice and the experimental error of the cumulative O2 evolved was < 10%.

Results and Discussion

Chemical Characterizations

Semi-quantitative elemental composition analyses of both the bulk and surface of the ZrO2 powders were obtained by means of FESEM-EDS and XPS analyses, respectively. Table 1 presents the RE atomic percentages of the samples calculated on a Zr base and theoretical values are compared to the average values obtained from both EDS and XPS. Overall, an increase in the RE currently present in the samples was observed by increasing the theoretical amount of both Ce- and Er-dopant. From bulk EDS analyses it was confirmed that almost all the samples retained similar dopant amounts to the theoretically introduced, with exception of the sample CZ10 that retained only the 60%.

TABLE 1
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Table 1. Chemico-physical characteristics of doped and non-doped ZrO2 samples theoretically calculated and obtained from XPS, FESEM-EDS, XRD, UV-Vis spectroscopy, and N2 absorption measurements.

The quantitative study of the XPS spectra revealed that in the Ce-doped materials, the superficial atomic percentage of Ce was close to the respective bulk values in the CZ05, CZ1 and CZ5 samples, in contrast to the CZ10 and the Er-doped ZrO2 samples, which evidenced about a half of the bulk RE amounts. This could be attributed to an easier distribution of Ce atoms (at the lowest percentages) than of Er during the hydrothermal synthesis process. The full-scan XPS spectrum for Ce- and Er-doped materials are presented in the (Figures 2A,B), respectively. The main peaks on the spectrum were identified Zr (Zr3p, Zr3d), O (O1s), Ce (Ce3d), and Er (Er4d). Some impurities were also found in both XPS and EDS analyses, ascribable to synthesis residues, corresponding to Na and Cl.

FIGURE 2
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Figure 2. Wide-scan XPS spectra of pure ZrO2 and RE-doped ZrO2 [(A) RE = Ce, (B) RE = Er] with increasing concentration of RE dopant, as labeled in each spectrum.

Figures 3, 4 show the high-resolution (HR) XPS spectra and the curves fitting, corresponding to the Ce3d and Er4d binding energies of the samples CZ5 and EZ5, as an example. The Er4d and Ce3d peaks were examined, and identified following literature data, in order to determine the oxidation states of both dopants in the ZrO2 matrix. Ce3d doublets, present in all the Ce-doped samples, can be attributed to Ce3+ and Ce4+ oxidation states (Zhang et al., 2010), which confirm once again that Ce-doping actually incorporates metal ion impurities into the ZrO2 structure. In the case of Er4d peaks, fitting of XPS data resulted in a 168.4 eV centered peak (as shown in Figure 4), for both the EZ5H and EZ10H samples, which can be attributed to Er3+. The sharp peak at 167.2 eV, which should be present for Er0 was absent. Instead, as broad peak that is typical of a surface oxidation was observed for all the samples (Wang et al., 2015).

FIGURE 3
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Figure 3. XPS high-resolution spectrum on Ce3d for 5% Ce-doped zirconia.

FIGURE 4
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Figure 4. XPS high resolution spectrum on Er4d for 5 and 10% Er-doped zirconia.

It is known that only from XPS data it is not possible to distinguish between Er3+ ions in the zirconia matrix (with oxygen vacancies as consequence of the charge imbalance) and Er2O3 in the catalyst surface (Bourbia et al., 2005). Nevertheless, XRD, TEM, and UV-Vis spectroscopy data (discussed in the next sections) were performed in order to verified the inclusion of Er ions in the Er-doped ZrO2 samples.

Structural and Morphological Analyses

Figure 5 shows the XRD patterns obtained for the pure zirconia, the Ce-doped (Figure 5A) and Er-doped (Figure 5B) ZrO2 samples. The hydrothermally synthetized ZrO2 samples showed a crystalline structure, with two polymorph variations; the tetragonal and the monoclinic phase. As shown in Table 1, XRD measurements evidenced that an increase in the RE-dopant content favored the formation of the tetragonal phase (t-ZrO2) over the monoclinic phase (m-ZrO2): the pure ZrO2 sample mainly contains monoclinic phase but, by increasing the amount of RE-dopant, the predominant ZrO2 phase becomes the tetragonal one. In the case of the EZ10 sample the insertion of Er probably bring to the stabilization of the cubic polymorph of ZrO2, as reported in literature (Jørgensen and Rittershaus, 1967). Indeed, the intensity ratio between the peaks at around 50° and around 35° has been calculated for the samples containing 5% and 10% of dopants (the other samples contain too much m-ZrO2 whose peaks overlap with those of t-ZrO2 and c-ZrO2 and, thus, a reliable analysis is not possible). Such ratio for c-ZrO2 is lower (around 1.8, ICDD Ref. code 00-049-1642) than for t-ZrO2 (around 2.5, ICSD Ref. code 01-079-1770). The ratio of CZ5 (2.00), CZ10 (2.23) and EZ5 (2.04) suggest the presence of t-ZrO2 probably with a tiny amount of c-ZrO2 that lowers the ratio respect to the expected one, while the ratio found for EZ10 (1.79) suggests the presence of c-ZrO2. Therefore, the Rietveld refinement analysis for this sample (EZ10) was performed using the latter phase instead of the tetragonal one. Crystals size of t-ZrO2 slightly increased (up to about 6 nm) with the introduction of both Ce- and Er-dopants. None of the samples shows the presence of diffraction peaks amenable to the formation of REO phases, indicating that likely the dopants (Er included) were successfully inserted in the ZrO2 matrix. Moreover, Figure S1 shows the enlargement of XRD patterns in the 26–34 2θ range. Figure S1 shows that whilst there's no evident shift in the position of the peaks related to the monoclinic phase, there's a small shift in the position of the 100% intensity peak of the tetragonal (or cubic) phase, especially for the higher dopant contents. This indicates that the RE ions were more likely inserted in the lattice of the t-ZrO2 or c- ZrO2 phases.

FIGURE 5
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Figure 5. XRD patterns of pure ZrO2 (a, black) and RE-doped ZrO2 [(A) RE = Ce, (B) RE = Er] with increasing concentration of RE dopant: 0.5 mol % (b, red), 1 mol % (c, blue), 5 mol % (d, green), and 10 mol % (e, magenta).

TEM analyses were performed to further confirm the effective doping of ZrO2 samples and the dopants distribution. Figures 6, 7 report the TEM images of the pure ZrO2 and the 5 and 10 mol % Ce- and Er-doped ZrO2 powders, in representation of the doped samples.

FIGURE 6
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Figure 6. TEM (left column) and HR-TEM (center and right columns) images of pure ZrO2 (A) and RE-doped samples with 5 mol % of Ce and Er: CZ5 (B) and EZ5 (C), respectively.

FIGURE 7
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Figure 7. (A,B) TEM (left column) and HR-TEM (center and right columns) images and (C,D) STEM images with EDS maps of RE-doped samples with 10 mol % of Ce and Er: CZ10 (A,C) and EZ10 (B,D), respectively.

From the low-magnification TEM images, two different grain morphologies could be distinguished, in both doped and non-doped samples. These are, a population of homogeneous nanocrystallites with 10 nm in diameter approximately and grains of < 100 nm in diameter. These two sorts of grains were analyzed in deep by high-resolution TEM (HRTEM). For pure ZrO2, it was found that 10 nm grains correspond to a mix of nanocrystallites of both tetragonal and monoclinic ZrO2 (Figure 6A). On the other hand, it was found that bigger grains correspond only to monoclinic phase, where many of these presented the characteristic twins (i and ii in Figure 6A) produced by the martensitic transformation tetragonal-monoclinic.

In general, the pure ZrO2 and most of the RE-doped samples evidenced the same kind of morphologies and crystalline phases at the TEM: (a) a mix of nanometric monoclinic and tetragonal grains of about 10 nm (similar to pure ZrO2 and RE-doped samples at 5%); (b) twinned grains corresponding to monoclinic phase, with a relatively larger dimension (from 15 to 60 nm), (c) bigger crystals (of about 100 nm) of only monoclinic phase. The only exception was for the EZ10 sample that was mainly formed by cubic ZrO2 nanocrystals with a size lower than 10 nm (in accordance to XRD data).

By increasing both Ce and Er dopants amounts to 5 and 10 mol %, the tetragonal (or cubic in the case of the EZ10 sample) phase crystals evidently increased in number with respect to the monoclinic ones (in concordance with XRD analysis). In addition, in the samples CZ5, EZ5, and CZ10, the presence of large flat monoclinic grains (Figures 6B,C, 7A) indicates that they were nucleated as monoclinic phase and then grew up, being not the product of the martensitic tetragonal-monoclinic transformation. This result is worth of notice since, in previous works, the synthesis of RE-modified ZrO2 samples (i.e., Y2O3-ZrO2) (Bugrov et al., 2016) with similar dopant contents have led to the stabilization of the tetragonal phase. Instead, the here reported hydrothermal synthesis method allowed to tune the amount of tetragonal phase vs. the monoclinic one, by varying the Ce or Er dopant content. Besides, it is noteworthy that, due to the use of Er-dopant at a concentration of 10 mol % (theoretical value based on Er oxide content), it was possible to stabilize the cubic phase of ZrO2 at room-temperature, while it is usually obtained at much higher temperatures (>1,000°C).

Finally, no other phases different than zirconia were found by TEM analyses. Hence, in agreement with the XRD and XPS results, no segregation of Ce or Er oxide phases were evidenced at any of the dopant concentrations, neither at the highest dopant level as shown in Figures 7A,B. This was further confirmed by STEM-EDS maps performed for all the samples. For instance, the EDS maps of the 10 mol % RE-doped ZrO2 samples are shown in the Figures 7C,D, where a uniform distribution of both Ce and Er dopants in the ZrO2 matrix can be observed, confirming that the dopants are present in all the crystalline phases of the ZrO2 constituting the samples.

In general, the SBET in the RE-doped samples increased with respect to the pure ZrO2 (see Table 1). This can be ascribed to the rise in the amount of tetragonal (or cubic) ZrO2 phase crystals (smaller than the monoclinic ones) present in the doped materials, as it was confirmed by XRD and TEM analyses, which resulted in a reduction of the average value of ZrO2 crystals size. Indeed, the specific surface area (SBET) of bare ZrO2 and the low content (0.5 and 1%) Ce-doped samples was similar, while it increased in about 50 and 60% for the CZ5 and CZ10 materials, respectively. In addition, all Er doped samples presented higher SBET values than bare ZrO2: for instance, it was enhanced in 16, 43, and 120% in the Er-doped samples with 0.5, 1.0, and 5%, respectively. All those results are in accordance to the increase of the proportion of tetragonal phase. Instead, the sample containing 10% of Er-dopant showed a slightly lower SBET than the EZ5 sample that can be ascribed to the slightly bigger cubic crystals constituting the EZ10 sample.

Optical Characterization

Diffuse Reflectance UV-Vis spectroscopy proved that the addition of RE dopants into the ZrO2 matrix had a significant effect on the optical properties of the materials. Results can be seen in the Figure 8, where the spectra recorded for pure ZrO2 is compared with those of the doped materials.

FIGURE 8
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Figure 8. Diffuse reflectance absorbance spectra of pure ZrO2 (a, black) and RE-doped ZrO2 [(A) RE = Ce, (B) RE = Er] with increasing concentration of RE dopant: 0.5 mol % (b, red), 1 mol % (c, blue), 5 mol % (d, green), and 10 mol % (e, magenta).

Ce-doped ZrO2 samples showed a red shift of the absorption edge, which increased proportionally with the amount of dopant. In the case of Er-doped ZrO2, the absorption edge, and consequently the energy gap, was not shifted, on the other hand a series of sharp absorption bands in the visible region ascribable to the f-f transitions of the Er3+ ion appeared. The spectrum of pure ZrO2 is reported in both panels of Figure 8 for the sake of comparison.

The energy gap (Eg) value was calculated for each sample by using the Tauc plot and linearizing (αhv)2 vs. hv, due to the direct band gap transition characteristic of ZrO2. The results are presented in Table 1 together with the surface area determined by the BET model. An increase in the concentration of Ce dopant from 0.5 to 10% caused a narrowing of the Eg. In contrast, the percentage of Er in the samples have no effect on the energy bands position of the semiconductor material, since the bare ZrO2 energy gap value of around 5.1 eV was preserved for all the Er concentrations. These data is in agreement with previously reported UV-Vis analyses on similar samples with concentration of REO dopants up to 5% (Gionco et al., 2016).

Photocatalytic Water Oxidation Activity Outcomes

The performance of RE-doped and non-doped ZrO2 for particulate photocatalytic water oxidation (WO) in the presence of sacrificial electrons acceptor (AgNO3) was assessed in the bubbling reactor system as described in the section Experimental. Figure 9 reports the cumulative curves of the O2 evolved during the time-course of the tests and the overall O2 evolution measured by using the pure ZrO2 and Ce- and Er-doped samples, after 1 h of simulated solar light irradiation. These data were obtained by integration of the O2 flow produced during the reaction and measured by micro-GC analyses every minute during the time course of the tests (see Figures S2), as made in previous works of some of us (Hernández et al., 2014; Thalluri et al., 2016).

FIGURE 9
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Figure 9. Time course of cumulative O2 evolved over the (A) Ce-doped and (B) Er-doped samples. (C) Total O2 evolved per gram of catalyst after 1 h of photocatalytic test of the RE-doped ZrO2 samples. Dopant molar percentages of 0.5, 1, 5, and 10% on a REO base. Photocatalytic test conditions: 100 mg of catalyst, 110 ml of 50 mM AgNO3 solution, simulated solar light irradiation (AM 1.5 G, 100 mW cm−2).

Pure hydrothermally synthetized ZrO2 exhibited some photocatalytic activity for solar-driven O2 evolution, although lower than 3 μmol h−1 g−1 catalyst, which is reasonable due to the high band gap of this material (i.e., 5 eV). In a similar way, negligible results were obtained by testing TiO2 Aeroxide (Degussa P25) with the same AgNO3 solution and simulated sunlight conditions (data not shown). Instead, the RE-doped ZrO2 samples evidenced a higher activity than the control ZrO2 and TiO2 samples. Both the CZ5 and EZ5 samples were the best performing photocatalysts, producing around 9 μmol g−1 oxygen after 1 h of irradiation, which is three times higher than that of the pure ZrO2. The photocatalytic activity of the Ce- and Er-doped ZrO2 samples was proportional to the RE content. This could be related to the enhancement of the specific surface area of these samples, in agreement with previous works on ZrO2 powders doped with some REO (i.e., RE = Y, Eu, Tb, Sm, Er), in which a direct correlation between SBET and photocatalytic H2 evolution activity, during the water splitting reaction under a sacrificial electrons donor, has been observed (Bugrov et al., 2016). However, such trend was not absolute in the present case, because the performance of CZ05 and CZ1 samples was superior than such of the pure ZrO2 although they have similar surface area values and both CZ10 and EZ10 samples (with an enhanced SBET) approached the photocatalytic activity of pure ZrO2.

The photoactivity of the samples can be correlated to different factors and the first one is the optical properties. If the actual superficial amount of RE dopant is considered, the photocatalytic activity of the Ce-doped samples was relatively higher than that of the Er-doped ZrO2, up to the optimum RE ions concentration (5 mol% in REO basis). This could be explained since the Ce ions could help the absorption of visible light photons through their f states, i.e., mid gap states acting as a “ladder” (new intra band gap states that support electron transitions at lower energies), as demonstrated by DFT calculations (Gionco et al., 2014) and schematized in Figure 10A, improving the charge carriers photogeneration. Instead, in the case of the Er ions, only the f-f internal absorption bands could be exploited (see Figure 10B) acting as “antennas” for the absorption of visible light, as expected from the sharp absorption bands in the visible region of the Er-doped samples shown in Figure 8B. To confirm if the photoactivity of the ZrO2-doped samples is related to their visible light absorption, IPCE measurements at different wavelengths were done with the most performing RE-doped samples (i.e., CZ5 and EZ5) and on the bare ZrO2 deposited on FTO/glass conductive substrates (see SI for experimental details). Normalized IPCE results (shown in the Figure S3) demonstrated that, among the used RE, only the Ce-doping effectively increased the ZrO2 photoactivity toward the visible light region. This result agrees with the higher visible light adsorption and the lowest band gap of the Ce-doped samples than of the bare ZrO2 shown in the Table 1 and Figure 8A. Nevertheless, since the Er-doped samples also reported better performances than the bare ZrO2, the photoactivity of the here reported RE-doped ZrO2 cannot only be explained by an enhanced visible light adsorption, which instead seems to have a secondary role.

FIGURE 10
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Figure 10. Schema of solar-driven photocatalytic water oxidation in the presence of Ag+ as electron scavenger under sunlight illumination over the Ce-doped ZrO2 (A) and Er-doped ZrO2 (B) samples, where it is evident the enhanced charges separation due to the presence of two ZrO2 polymorphs (i.e., tetragonal or cubic and monoclinic phases).

As a second factor, it seems evident that the water oxidation kinetics is improved in both tetragonal and cubic crystals of zirconia more than in the monoclinic ones. To confirm that, photoelectrochemical tests were performed on pure m-ZrO2 and t-ZrO2 powders deposited on FTO/glass conductive substrates (see experimental procedures in the Supporting Information). Indeed, the linear sweep voltammetries reported in the Figure S4, performed under AM 1.5G simulated sunlight illumination, demonstrated that the t-ZrO2 has a better photoactivity than the m-ZrO2 powder. This behavior could be explained by a better mobility of charges in t-ZrO2 than in m-ZrO2. However, the donor density values (calculated from Mott-Schottky plots and reported in Figure S5) of m-ZrO2 resulted to be higher than the one of t-ZrO2, which indicates that the charge transport in the bulk of the here presented t-ZrO2 samples is not better than such of the m-ZrO2 one and the same behavior was observed for the CZ5 and EZ5 samples in comparison to the bare ZrO2. Thus, the other possible explanation of the superior activity of the t-ZrO2 phase (and of the doped samples) is an improved kinetics for the water oxidation reaction due more defects on its surface and its higher surface area.

To check this possibility, XPS measurements have been performed on both pure m-ZrO2 and t-ZrO2 samples. As reported in Figure S6A, the Zr3d doublet of t-ZrO2 is shifted toward lower binding energies (BE, lowest BE peak at 181.2 eV) and can be deconvoluted by only two components (for Zr3d5/2 and Zr3d3/2—not reported), which can be ascribed to non-stoichiometric ZrOx (Galtayries et al., 1998). Instead, the m-ZrO2 shows a shift toward higher BE values (lowest BE peak at 181.6 eV) and an enlarged doublet, which can be deconvoluted by four components: two for the ZrOx phase (66.6%) and two for the ZrO2 one (33.4%). These results are in accordance with the hypothesis that a higher degree of defects, due to surface alteration or disorder associated with oxygen vacancies, can be found on the t-ZrO2 surface. We also analyzed the valence band region of those samples by XPS, in order to calculate the valence band maximum (VBM) value, which is correlated with the superficial electronic conduction of the material. As reported in Figure S6B, the two VBM values (extrapolated by a linear fit in the descending side of the curve toward the Fermi Level at 0 eV) are: 1.53 eV for t-ZrO2 and 1.72 eV for m-ZrO2, which also confirm the relative positions of the valence bands reported in the Figure 10. This difference in the VBM, even if not so huge, represents a hint that the t-ZrO2 is more conductive on its surface, electronically speaking, than the monoclinic one, as reported by Dash et al. (2004) This behavior has also been observed in theoretical studies in which the electronic structure and density of states (DOS) of ZrO2 polymorphs have been investigated by DFT or LCAO calculations (Zandiehnadem et al., 1988; Vempati et al., 2015; Sinhamahapatra et al., 2016). The main result is that both materials possess a flat valence band, which is in accordance with the semiconducting behavior, however, the t-ZrO2 polymorph presents a higher amount of unoccupied states than m-ZrO2 (at around 5 eV above the Fermi level) and the O deficiency creates new available states in the gap region (Dash et al., 2004).

To further elucidate differences in the charge transfer properties of the two ZrO2 polymorphs, electrochemical impedance spectroscopy (EIS) measurements were performed with their photoelectrodes under simulated sunlight irradiation. Indeed, Nyquist plots of EIS shown in the Figure S7 evidence lower impedance values for the t-ZrO2 electrode than for the m-ZrO2 photoelectrode in the low frequency region (between 1 and 0.1 Hz), which correspond to slow processes happening at the electrode surface (Hernández et al., 2015, 2016) and confirm an improved charge transfer (i.e., kinetics of reaction) of the tetragonal phase during water oxidation.

From these results it is evident that both the presence of t-ZrO2 and the surface composition of the ZrO2-doped samples plays a fundamental role on their superior photocatalytic activity. Indeed, XRD data demonstrated that the dopants are mainly present in the tetragonal phase and it has been reported (Thalluri et al., 2016) that the superficial quantity of dopants plays a more important role than their total bulk amount for the water oxidation activity of visible light active powder photocatalysts, e.g. BiVO4. Up to a certain amount, dopants can enhance the charge carriers (e/h+) separation and transfer from the water (e donor) to the catalyst surface and from the latter to the e acceptor (AgNO3). According to the photocatalytic tests (Figure 9C), the optimal dopant concentration for the here reported samples, lies around 3.7% of RE/Zr atomic ratio (i.e. the mean value of Er and Ce superficial amounts measured by XPS analyses on the CZ5 and EZ5 samples, see Table 1). However, an excess amount of Er+3 or Ce+3/Ce+4 also could induces the formation of a higher number of oxygen vacancies that compensate the charges in the ZrO2 matrix, which can also cause a higher recombination rate. Therefore, when the optimal concentration is exceeded, the dopant ions or oxygen vacancies probably acts as recombination centers, dramatically lowering the photoactivity.

This last consideration could explain the low activity demonstrated by the samples containing the highest amount of dopants (CZ10 and EZ10), which are mainly constituted by tetragonal or cubic phase of ZrO2, respectively. However, it also can be explained by an optimum ratio between the tetragonal and monoclinic ZrO2 phases of about 2.3 (mean value of the CZ5 and EZ5 samples, see Table 1). Hence, another effect that could influence the photocatalytic activity of the here reported RE-doped ZrO2 samples could be an enhanced charges separation at the interface between two zirconia polymorphs, monoclinic and tetragonal (or cubic) phases. This phenomenon has been observed for the water splitting reaction on commercial P25 TiO2 with mixed anatase and rutile crystalline phases (Masolo et al., 2015), in which the creation of a heterostructure between the two polymorphs leads on an improved interface that allow a fast separation of the photogenerated charges with a consequent reduction of recombination processes. In the present case, although the band gap values of the various phases of ZrO2 are quite similar (Dash et al., 2004), the VB and CB potentials of ZrO2 polymorphs are different, as shown in Figure 10, where a schematic representation of the relative VB and CB positions of m-ZrO2 vs. the t-ZrO2 and c-ZrO2 were drawn considering the VBM experimentally obtained by XPS (Figures S6) and theoretical works (Zandiehnadem et al., 1988; Hernández et al., 2015; Vempati et al., 2015).

Conclusions

In this work, Ce- and Er- doped ZrO2 were successfully synthesized through hydrothermal method, with molar concentration up to 10% on a REO basis. The samples were characterized with different techniques. The addition of rare earth ions to the zirconia matrix stabilizes the tetragonal (Ce, Er) and cubic (Er, 10 mol %) polymorphs of ZrO2. The structural and morphological analyses point out that the rare earth ions have actually been inserted in the matrix, while the optical analysis confirms that the doping has increased the ability of zirconia of harvesting visible light.

The samples were tested for the photocatalytic water oxidation reaction by using solar simulated light in presence of a sacrificial electron acceptor. All the samples resulted active in the production of oxygen from water, with the samples containing the 5% of RE oxide being the most active (three times more than pure zirconia). We found that the highest photocatalytic activity of those samples is well correlated to an optimal amount of t-ZrO2 to m-ZrO2 phases of about 2.3 and a surface concentration of RE ions of about 3.7 mol %, which increased the charge carriers separation in the photocatalysts surface or through the interface between the monoclinic and tetragonal (or cubic) polymorphs of zirconia. Instead, the increased ability of the RE-doped ZrO2 to harvest visible light was found to have a secondary role in the overall photoactivity of only the Ce-doped ZrO2 samples.

The here presented results are of high relevance in the perspective of further optimization of a high-band gap photocatalysts as ZrO2 for the utilization of its high redox potential coupled to the visible light absorption for solar fuels production or other environmental applications.

Author Contributions

SH and TH tested all the photocatalysts for the sun-driven water oxidation reaction and correlated their activity to the physicochemical properties of the samples. CG synthesized the ZrO2 powders and performed XRD and UV-vis spectroscopy characterizations. MC did and analyzed XPS measurements. JM-T performed TEM imaging and analyses. KT did the photoelectrochemical measurements and data analysis. NR contributed with the XRD and XPS data analysis. EG, MP, and NR supervised the experimental work. All the authors contributed with discussion of results and writing of the manuscript.

Conflict of Interest Statement

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

The reviewer MR and handling Editor declared their shared affiliation.

Acknowledgments

We acknowledge support from a Marie Curie International Research Staff Exchange Scheme Fellowship (MAT4TREAT, proposal no. 645551) within the Horizon 2020 European Community Framework Programme, the EACEA Erasmus + SINCHEM Grant (FPA 2013-0037) and the Italian MIUR through the PRIN Project 2015K7FZLH SMARTNESS Solar driven chemistry: new materials for photo- and electro-catalysis.

Supplementary Material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fchem.2018.00368/full#supplementary-material

The Supporting Information contains two sections: (i) Materials and Methods describing synthesis of pure t-ZrO2 and m-ZrO2 samples, preparation of the photoelectrodes and photoelectrochemical (PEC) tests and (ii) Figures of XRD data (magnification), example of O2 molar concentration calculated from continuous micro-GC analyses during the time-course of photocatalytic experiments, PEC results and XPS plots of pure t-ZrO2 and m-ZrO2 samples.

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Keywords: ZrO2, rare-earth dopants, water splitting, third-generation photocatalysts, O2 evolution photocatalyst

Citation: Hernández S, Gionco C, Husak T, Castellino M, Muñoz-Tabares JA, Tolod KR, Giamello E, Paganini MC and Russo N (2018) Insights Into the Sunlight-Driven Water Oxidation by Ce and Er-Doped ZrO2. Front. Chem. 6:368. doi: 10.3389/fchem.2018.00368

Received: 04 March 2018; Accepted: 30 July 2018;
Published: 22 August 2018.

Edited by:

Kamila Kočí, VŠB-Technical University of Ostrava, Czechia

Reviewed by:

Martin Reli, VŠB-Technical University of Ostrava, Czechia
Fatwa Abdi, Helmholtz-Zentrum Berlin für Materialien und Energie, Germany

Copyright © 2018 Hernández, Gionco, Husak, Castellino, Muñoz-Tabares, Tolod, Giamello, Paganini and Russo. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Simelys Hernández, c2ltZWx5cy5oZXJuYW5kZXpAcG9saXRvLml0
Chiara Gionco, Y2hpYXJhLmdpb25jb0B1bml0by5pdA==

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