Abstract
Nanocomposites of magnetite anchored on reduced graphene oxide with different magnetite:reduced graphene oxide mass ratios were synthesized and evaluated in indigo carmine photo Fenton discoloration. All nanocomposites are magnetic and showed comparable amounts of magnetite and hematite with a higher level of hematite for low iron contents. The highest value of 63.6 emu g−1 was obtained for the nanocomposite with the highest magnetite content. The nanocomposites presented high dispersion of iron oxide particles, at about 12 nm on reduced graphene oxide surface sheets. The samples also showed bandgap energies below that found for bulk magnetite, showing an important effect of reduced graphene oxide. The nanocomposite with an iron nitrate precursors mass ratio of 17:1 showed the best performance (99.7% of indigo carmine discoloration (2.1 × 10−5 mol L−1) at 30 min of reaction, hydrogen peroxide (2.3 × 10−1 mol L−1), and a catalyst dosage of 0.67 g L−1). Reusability tests were performed, and this nanocomposite was shown to be active for at least three recycles. X-ray photoelectron spectrum of Fe2p3/2 showed that the FeIII/FeII ratio was maintained even after three recycles (4 runs), meaning that reduced graphene oxide is responsible for stabilizing magnetite particles, thus maintaining its photocatalytic activity.
Keywords:
iron oxides; reduced graphene oxide; heterogeneous photocatalysis; indigo carmine
Introduction
Water contamination is one of the major environment-related issues, and it is associated not only with health problems but with severe socioeconomic impacts.11 Mathur, N.; Bhatnagar, P.; Nagar, P.; Bijarnia, M. K.; Ecotoxicol. Environ. Saf. 2005, 61, 105. [Crossref]
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Indigo carmine (IC) is an artificial vibrant blue dye, spread worldwide due to its use in denim making. It is an indigoid organic dye and its molecule possesses two sulfonic groups. Besides, it is well known that IC brings health risks because it is toxic, mutagenic, and very stable in nature.77 Younes, S. B.; Sayadi, S.; J. Mol. Catal. B: Enzym. 2013, 87, 62. [Crossref]
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These characteristics are driving forces to develop new technologies to mitigate water pollution by synthetic organic dyes.
Different techniques are investigated to remediate dying wastewater pollution, such as ultrafiltration, electrochemical, and adsorption.88 Dastgerdi, Z. H.; Meshkat, S. S.; Esrafili, M. D.; J. Nanostructure Chem. 2019, 9, 323. [Crossref]
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However, heterogeneous photocatalysis of organic dyes emerges as a promising approach due to its advantages, such as catalyst recovery and reuse, use in mild conditions, pollutant chemical transformation, and others.99 Zaied, M.; Chutet, E.; Peulon, S.; Bellakhal, N.; Desmazières, B.; Dachraoui, M.; Chaussé, A.; Appl. Catal., B 2011, 107, 42. [Crossref]
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These reactions are considered advanced oxidative processes (AOPs), where hydroxyl radicals (•OH) are generated from H2O2 decomposition, assisted by a light source and a semiconductor oxide.1111 Al Kausor, M.; Chakrabortty, D.; Inorg. Chem. Commun. 2021, 129, 108630. [Crossref]
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These structures are then responsible for attacking the organic pollutant molecules, breaking the molecule bonds until mineralization (transforming a pollutant organic molecule into CO2, H2O, and mineral acids).
An attractive abundant semiconductor oxide studied in heterogeneous photocatalysis reactions is magnetite (Fe3O4).1212 Khan, M. A. M.; Khan, W.; Ahamed, M.; Alhazaa, A. N.; Mater. Sci. Semicond. Process. 2019, 99, 44. [Crossref]
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This mixed oxide has a FeIII/FeII ratio of 2:1 and narrow bandgap values.1313 Radón, A.; Drygala, A.; Hawełek, Ł.; Łukowiec, D.; Mater. Charact. 2017, 131, 148. [Crossref]
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The first characteristic is responsible for the aforementioned •OH radical generation. The second, is related to the compound electronic activation, an important parameter to be considered in photocatalysts.1515 Sakar, M.; Prakash, R. M.; Do, T. O.; Catalysts 2019, 9, 680. [Crossref]
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However, if non-supported iron oxides are employed in aqueous medium, its particles tend to aggregate quickly.1616 Kong, C.; Li, M.; Li, J.; Ma, X.; Feng, C.; Liu, X.; RSC Adv. 2019, 9, 20582. [Crossref]
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Also, the FeII oxidation to FeIII results in a deactivated passive oxide layer.1717 Gonçalves, N. P. F.; Minella, M.; Fabbri, D.; Calza, P.; Malitesta, C.; Mazzotta, E.; Prevot, A. B.; Chem. Eng. J. 2020, 390, 124619. [Crossref]
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Both phenomena are bound to the •OH generation suppression, hindering the capability of decomposing the pollutant. Therefore, supporting iron nanoparticles in materials that stabilize them and improve their physical-chemical properties is a good alternative to mitigate these issues.1818 Zheng, M.; Ma, X.; Hu, J.; Zhang, X.; Li, D.; Duan, W.; RSC Adv. 2020, 10, 19961. [Crossref]
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Due to their remarkable optical,1919 Bagri, A.; Mattevi, C.; Acik, M.; Chabal, Y. J.; Chhowalla, M.; Shenoy, V. B.; Nat. Chem. 2010, 2, 581. [Crossref]
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electronic,2020 Zhu, Y.; Murali, S.; Cai, W.; Li, X.; Suk, J. W.; Potts, J. R.; Ruoff, R. S.; Adv. Mater. 2010, 22, 3906. [Crossref]
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and textural properties,2121 Zhao, G.; Jiang, L.; He, Y.; Li, J.; Dong, H.; Wang, X.; Hu, W.; Adv. Mater. 2011, 23, 3959. [Crossref]
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graphene derived compounds, such as graphene oxide (GO), and reduced graphene oxide (RGO), have been used to immobilize semiconductor oxide particles, avoiding particle agglomeration, and to improve their photocatalytic activity in various organic dyes removal systems.1818 Zheng, M.; Ma, X.; Hu, J.; Zhang, X.; Li, D.; Duan, W.; RSC Adv. 2020, 10, 19961. [Crossref]
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,2525 Zarrabi, M.; Haghighi, M.; Alizadeh, R.; Mahboob, S.; Mater. Res. Bull. 2022, 153, 111907. [Crossref]
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For instance, Zarrabi et al.2525 Zarrabi, M.; Haghighi, M.; Alizadeh, R.; Mahboob, S.; Mater. Res. Bull. 2022, 153, 111907. [Crossref]
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produced a ZnO-GO-Fe3O4 nanocomposite, and achieved 97% of methylene blue (MB) discoloration. Yet for this dye, Umar et al.2626 Umar, A.; Kumar, S. A.; Inbanathan, S.S.R.; Modarres, M.; Kumar, R.; Algadi, H.; Ibrahim, A. A.; Wendelbo, R.; Packiaraj, R.; Alhamami, M. A. M.; Baskoutas, S.; Ceram. Int. 2022, 48, 29349. [Crossref]
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obtained 91% of conversion within 30 min of reaction, with a Fe3O4-GO nanocomposite. For methyl orange dye (MO), Liu et al.2727 Liu, H.; Wang, K.; Zhang, D.; Zhao, D.; Zhai, J.; Cui, W.; Mater. Sci. Semicond. Process. 2023, 154, 107215. [Crossref]
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synthesized an organic-inorganic polyonic liquid-functionalized graphene oxide (PGO) PGO-TiO2/Fe3O4, reaching 95% of MO removal. Using a monolithic 3D RGO-Fe3O4 aerogel, Sadegh et al.2828 Sadegh, F.; Politakos, N.; Roman, E. G. S.; Sanz, O.; Perez-Miqueo, I.; Moya, S. E.; Tomovska, R.; RSC Adv. 2020, 10, 38805. [Crossref]
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observed 100% of acid red 1 (AR1) dye discoloration. Silva et al.2929 da Silva, M. P.; De Souza, A. C. A.; Ferreira, L. E. L.; Pereira Neto, L. M.; Nascimento, B. F.; de Araújo, C. M. B.; Fraga, T. J. M.; Sobrinho, M. A. M.; Ghislandi, M. G.; Environ. Adv. 2021, 4, 100064. [Crossref]
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tested an amino-Fe3O4 functionalized graphene oxide, named AmGO, and observed 97% of reactive black 5 (RB5). Besides their remarkable dye removal results, another important highlight reported by these works is that these nanocomposites can be simply synthesized by diverse approaches. In addition, the magnetic character of these nanocomposites leads to simpler catalyst recovery methods and possibilities for further reuse. Thus, the combination of these features results in promising materials to be used for a wide range of wastewater pollutants removal.
Recently, our group described dispersed Fe3O4 nanoparticles anchored on RGO sheets,3030 Gonçalves, A. H. A.; Siciliano, P. H. C.; Alves, O. C.; Cesar, D. V.; Henriques, C. A.; Gaspar, A. B.; Top. Catal. 2020, 63, 1017. [Crossref]
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synthesized by a facile redox synthesis adapted from the Stőber method, where Fe(NO3)3.9H2O oxidates to Fe3O4 and GO is reduced to RGO.3131 Qiu, B.; Li, Q.; Shen, B.; Xing, M.; Appl. Catal. B: Environ. 2017, 183, 216. [Crossref]
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In this way, a nanocomposite with approximately 90 wt.% of Fe3O4 and 10 wt.% of RGO was employed to treat an IC solution (2.1 × 10−5 mol L−1) in a photo-Fenton system. Within 5 min after the light was turned on, a rapid and complete discoloration of the IC solution was observed. Its remarkable characteristics such as less negative zeta potential, narrow bandgap, and the persistent cycle conversion process of FeIII/FeII promoted by RGO; explained its outstanding activity. Furthermore, due to its strong magnetic character, the nanocomposite could be easily recovered and reused. These observations supported that the Stőber-like method is a powerful synthesis to immobilize Fe3O4 nanoparticles on RGO, improving its photocatalytic properties.
In this sense, the present work aims to expand the study of IC photo-Fenton discoloration with Fe3O4/RGO nanocomposites produced by the adapted Stöber-like method. Nanocomposites with different ratios of Fe3O4:RGO were synthesized, characterized, and evaluated in the IC photo-Fenton discoloration. The nanocomposite with the best performance was selected to perform a study varying the oxidant reactant (H2O2) and nanocomposite loads, providing kinetic data. Furthermore, reusability tests were conducted to highlight the photocatalyst stability.
Experimental
Synthesis of the materials
Graphite (Grafine 996100), provided by Nacional de Grafite (São Paulo, Brazil), was oxidized by the modified Hummers method.3232 Soares, C. P. P.; Baptista, R. L.; Cesar, D. V.; Mater. Res. 2018, 21, e20170726. [Crossref]
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At 0 °C, assisted by an ice bath, 11.5 mL of H2SO4 (95 wt.%, Vetec, Rio de Janeiro, Brazil), and 270 mg of NaNO3 (98 wt.%, Isofar, Rio de Janeiro, Brazil) were added to 220 mg of graphite under magnetic stirring. Then, the temperature was set to 35 ± 5 °C and six portions of 250 mg of KMnO4 (99 wt.%, Isofar, Rio de Janeiro, Brazil) were slowly added into the mixture, which remained under stirring for 1 h. After that, distilled water was added, and the temperature was raised to 98 ± 5 °C and kept for 15 min. Next, 60 mL of H2O2 (10 wt.%, Isofar, Rio de Janeiro, Brazil) were added to the system, and the temperature was lowered to 20 °C and maintained for 1 h. After the oxidation procedure, the slurry was washed to remove impurities. Each washing cycle was performed as follows: the slurry was filtered and the solid obtained was washed with 20 mL of H2O2 (10 wt.%), then with 20 mL of H2SO4 (5 wt.%), centrifuged, and washed with distilled water until pH = 6.0.
The synthesis of the Fe3O4/RGO magnetic nanocomposites was performed by varying the iron precursor solution concentration in the adapted Stöber-like method.3131 Qiu, B.; Li, Q.; Shen, B.; Xing, M.; Appl. Catal. B: Environ. 2017, 183, 216. [Crossref]
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In a beaker, an ethanol/acetonitrile (3:1) solution was used to disperse 200 mg of GO for 90 min in an ultrasonic bath. After that, the beaker was placed on a magnetic plate, 1.33 mL of ammonium hydroxide (28 wt.%, Sigma-Aldrich, São Paulo, Brazil) was added, and the suspension stirred for 30 min. The desired solutions of Fe(NO3)3.9H2O (Sigma-Aldrich, São Paulo, Brazil) were added dropwise to the suspension and kept stirring for 30 min. Then, the mixture was transferred to a round bottom glass flask and a reflux system was assembled. The temperature was set to 60 °C, and the mixture was magnetically stirred for 40 h. At the end of this step, the iron oxide/GO solid was centrifuged from the solution, washed with ethanol to remove impurities, and dried in an oven. The iron oxide/GO solid was then heated to 500 °C (with a rate of 1.5 °C min−1) and treated for 2 h with a pure nitrogen flow of 50 mL min−1. Table 1 shows the precursor Fe(NO3)3.9H2O quantities used in each synthesis, and the respective names of the prepared samples. Also, an appropriate mass of GO was separated and thermally treated as the iron oxide/GO likewise to yield pure RGO. A sample of bulk Fe3O4 obtained as described by da Costa et al.3333 da Costa, T. R.; Baldi, E.; Figueiró, A.; Colpani, G. L.; Silva, L. L.; Zanetti, M.; de Mello, J. M. M.; Fioria, M. A.; Mater. Res. 2019, 22, e20180847. [Crossref]
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was also used as a standard.
Characterization
Microscopic studies of the iron oxide nanoparticles of the Fe3O4/RGO nanocomposites were performed using scanning transmission electron mode on a SEM microscope (STEM-in-SEM) operated at 30 kV, with a specific sample holder for conventional copper transmission electron microscopy (TEM) grids and a high angular STEM detector (HAADF-STEM) in a Helios Nanolab Dual Beam G3 CX equipment. Field emission gun scanning electron microscopy (FE-SEM) analysis was carried out in a Quanta FEG 450 equipment. Both microscopes are from FEI/Thermo Fischer (Waltham, USA). C, O, and Fe distribution and composition in the Fe3O4/RGO nanocomposites were determined by electron dispersive X-ray (FE-SEM-EDX). Particle size measurements were performed using ImageJ (1.52a) software.3434 Rasband, W. S.; ImageJ, version 152a; U. S. National Institutes of Health, Bethesda, Maryland, USA, 2018. The crystallinity of all materials was observed by X-ray diffraction (XRD). The diffractograms were obtained in a Rigaku Miniflex II (Tokyo, Japan), with Cu Κα radiation of 1.540562 Å, 30 kV voltage, and 15 mA current. The acquisition parameters were: 2θ (from 5 to 70°), a step of 0.05, and 2 degree min−1 per step. Textural analysis of RGO and the nanocomposites was performed in an ASAP 2020 from Micromeritics (Norcross, USA). Specific areas and pore volumes were estimated by N2 adsorption at −196 °C, using Brunauer-Emmett-Teller (BET) method for the estimation of the specific area, and Barrett-Joyner-Halenda (BJH) method for the estimation of the average pore diameter. The thermal stability of the materials was investigated using thermo gravimetric analysis (TGA), in which the measurements were performed in a STA 409 Pc Luxx (NETZSCH) equipment (Selb, Germany), from room temperature to 1000 °C with a 20 °C min−1 heating rate and 20 mL min−1 of airflow.
Diffuse reflectance spectroscopy (DRS) was performed to estimate the bandgap of the nanocomposites and the bulk Fe3O4. The materials were mixed with BaSO4 (1:25) and analyzed in a Varian Cary 5000 UV-Vis-NIR spectrometer from 200 to 1500 nm (Palo Alto, USA).
The magnetic properties of the Fe3O4/RGO nanocomposites were studied combining electronic paramagnetic resonance (EPR) and vibrating-sample magnetometer (VSM) techniques. EPR analysis was performed in an ESP 300e (Bruker, Billerica, USA) with band cavity-X of 9 GHz at room temperature. VSM measurements were obtained in a Physical Property Measurements System (PPMS) DynaCool, from Quantum Design (San Diego, USA).
57Fe Mössbauer absorption spectra were taken at room temperature in transmission mode using a standard spectrometer with sinusoidal velocity sweep of the 57Co/Rh source (about 5 mCi). The hyperfine parameters derived from the spectra allow to distinguish different iron oxide phases.
X-ray photoelectron spectroscopy was employed to evaluate the surface chemical environment of iron before and after reuse cycles. The spectra were recorded in a PHOIBOS 150 (SPECS, Berlin, Germany), without a monochromator, and Al Κα X-ray source. Adventitious carbon (C1s at 284.6 eV) was used to calibrate the whole spectra, whilst all mathematical treatment was performed with Casa XPS software (2.3.17).3535 CasaXPS, version 2.3.17; Casa Software Ltd., Teignmouth, UK, 2018. The pressure inside the analysis chamber during all measurements was in the range of 10−10 to 10−9 mbar.
Indigo carmine (IC) photocatalysis
The IC photo-Fenton discoloration was evaluated in a system set up into a box that prevents external light interference, with a 50 mL glass reactor surrounded by a cooling jacket, already described in previous works.3030 Gonçalves, A. H. A.; Siciliano, P. H. C.; Alves, O. C.; Cesar, D. V.; Henriques, C. A.; Gaspar, A. B.; Top. Catal. 2020, 63, 1017. [Crossref]
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,3636 Costa, G. P.; Rafael, R. A.; Soares, J. C. S.; Gaspar, A. B.; Catal. Today 2020, 344, 240. [Crossref]
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,3737 Rafael, R. A.; Noronha, F. B.; Gaspar, A. B.; Topics Catal. 2020, 63, 1066. [Crossref]
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Nanocomposite dosages of 0.67, 0.33, 0.17, and 0.07 g L−1, were dispersed in distilled water using an ultrasonic bath for 30 min. Then, 15 mL of IC solution (4.2 × 10−5 mol L−1) was aggregated to the dispersion to reach a final IC concentration of (2.1 × 10−5 mol L−1). This IC concentration was selected because it is reported to be within the typical textile wastewater range.3838 Aleboyeh, A.; Aleboyeh, H.; Moussa, Y.; Environ. Chem. Lett. 2003, 1, 161. [Crossref]
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Finally, the appropriate amounts of 30% H2O2 were transferred to the reactor, to complete a final volume of 30 mL and reach H2O2 concentrations of 2.3 × 10−1, 1.2 × 10−1, and 0.6 × 10−1 mol L−1. At first, the magnetic stirring started, the chamber door was closed, and the mixture remained stirring for 30 min in the dark to reach the dye-catalyst adsorption equilibrium. Then, the lamp Master HPI-T (400 W), from PHILIPS, which emits predominantly visible light in the range of 380-740 nm,3737 Rafael, R. A.; Noronha, F. B.; Gaspar, A. B.; Topics Catal. 2020, 63, 1066. [Crossref]
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was activated, and aliquots were extracted in periodic time intervals. The time when the lamp was turned on was denominated as 0 min. A magnet was used to separate the magnetic materials from the reaction medium. After that, the liquid was filtered with a Millipore filter (MILEX-GV PVDF-0.22 μm) and taken to a Varian Cary 500 UV-Vis spectrometer. Before each analysis, a calibration curve (Figure S1, Supplementary Information (SI) section) was performed by measuring the absorbance in the specific concentration at 611 nm, and this wavelength was used to monitor IC discoloration. Equation 1 was employed to calculate the IC discoloration.
where, CA is the calculated concentration of the specific aliquot and C0 is the initial concentration of indigo carmine dye.
The photocatalyst with the best performance was selected to perform reuse experiments. In this case, the nanocomposites magnetically separated from the reaction were washed with distilled water and dried in an oven at 100 °C overnight. Then, the dried catalyst was used in the following reuse cycle, with a fixed IC/nanocomposite mass ratio of 0.015.
Results and Discussion
Materials characterization
Figure 1 shows the microscopic analysis for bare RGO (FE-SEM), bulk Fe3O4 (SEM), and all nanocomposites (STEM-in-SEM). RGO (Figure 1a) has a compact sheet morphology, while bulk Fe3O4 (Figure 1b) is a powder characteristic with different sizes of agglomerates. Meanwhile, nearly spherical iron oxide nanoparticles were successfully anchored on RGO sheets for the three nanocomposites (Figures 1c 1d 1e). The nanoparticle counts by STEM-in-SEM (Figures 1c 1d 1e and Table 2) indicate that the anchored iron oxide particles mean sizes are 12 nm for nanocomposites 1 and 2, and 15 nm for nanocomposite 3. It is worth mentioning that even with higher Fe3O4 loads, all nanocomposites showed well dispersed Fe3O4 nanoparticles on RGO sheets. The high dispersion of the small particles of iron oxide was favored by the synthesis method used, as shown by Qiu et al.3131 Qiu, B.; Li, Q.; Shen, B.; Xing, M.; Appl. Catal. B: Environ. 2017, 183, 216. [Crossref]
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SEM images of bare reduced graphene oxide (a) and Fe3O4 (b). STEM-in-SEM micrographs for the nanocomposites with their histogram of particle size distribution: nanocomposite 3 (c), nanocomposite 2 (d) and nanocomposite 1 (e).
STEM-in-SEM particle counting, EDX iron content, crystallite size (by XRD), and textural data for all nanocomposites
FE-SEM-EDX (Table 2) iron semiquantitative analysis obtained from different regions, for nanocomposites 3 and 2 showed iron contents (wt.%) of 55.4 ± 2.8, and 41.6 ± 2.5, respectively. The observed deviation between each region is accepted due to the semiquantitative characteristic of this analysis and the heterogeneous nature of these nanocomposites. However, the FE-SEM-EDX iron content (wt.%) for nanocomposite 1 was found to be 29.1 ± 18.3, with a very pronounced discrepancy among the regions.
EDX mapping (Figure S2, SI section) was performed to investigate the Fe distribution in the photocatalysts. RGO sheets of nanocomposites 3 and 2 showed to be fully covered by Fe (not shown). However, due to a high discrepancy in the different points of EDX semiquantitative analysis for nanocomposite 1, two different Fe3O4/RGO aliquots were selected to perform the EDX mapping. As a result, site 1 map (Figure S2a) shows an iron oxide-rich sheet, where the circle clearly reveals a RGO sheet prolongation with no detectable iron oxide. On the contrary, site 2 map (Figure S2b) indicates an iron oxide poor RGO folded sheet. Therefore, although some heterogeneity in these materials is expected, nanocomposite 1 showed to contain manifold regions with very different characteristics, suggesting the insufficient filling of iron oxides on RGO sheets, probably due to the lower iron precursor content in this synthesis, which is 3 times lower than nanocomposite 3.
XRD patterns for all Fe3O4/RGO nanocomposites, and RGO are shown in Figure 2a. For nanocomposites 2 and 3, it can be seen the crystalline Fe3O4 diffraction peaks and their respective Miller indexes, which are: 29.9° (220), 35.4° (311), 43.1° (400), 56.9° (511), and 62.5° (440). The JCPDS 76-1849 diffraction peaks, highlighted by pink bars, confirm that Fe3O4 particles were successfully formed on RGO sheets. For nanocomposite 1, however, a considerable displacement of ca. 0.5° of these peaks to higher 2 theta values are observed. Also, the intensity of the peaks indicated by the asterisks at 2θ = 24.3, 33.3, 40.8, and 64.2° becomes higher with the decreasing of Fe3O4 contents, suggesting that hematite (a-Fe2O3) might be formed in lower Fe(NO3)3.9H2O loads (JCPDS 24-0072).3939 Han, R.; Li, W.; Pan, W.; Zhu, M.; Zhou, D.; Li, F.; Sci. Rep. 2014, 4, 7493. [Crossref]
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XRD patterns of RGO and all nanocomposites (a) and XRD patterns of all nanocomposites to highlight RGO halo (b). Pink bars and the asterisk are related to Fe3O4 and a-Fe2O3, respectively.
It is worth mentioning that nanocomposite 1, besides the characteristic magnetite black color, also presented portions with reddish color, which could be associated with the a-Fe2O3 formation. These observations agree with the study performed by Dong et al.,4040 Dong, X.; Li, L.; Zhao, C.; Liu, H. K.; Guo, Z.; J. Mater. Chem. A 2014, 2, 9844. [Crossref]
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who detected higher Fe2O3 amounts for the nanocomposites with higher RGO contents. In parallel, no diffraction peak at 2θ < 10° was detected for the three nanocomposites, indicating that GO in the three samples was reduced to RGO. Furthermore, for nanocomposites 2 and 1, the appearance of a halo with a maximum around 2θ = 25° is related to RGO. The crescent intensity of this halo was expected once the amount of RGO in these samples increased (Figure 2b).4141 Cheng, J. P.; Shou, Q. L.; Wub, J. S.; Liu, F.; Dravid, V. P.; Zhang, X. B.; J. Electroanal. Chem. 2013, 698, 1. [Crossref]
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The Scherrer equation was used to estimate the average crystallite size, using the most intense Fe3O4 peak (2θ = 35.4°) of the synthesized nanocomposites. The results are shown in Table 2, evidencing average crystallite sizes close to the particle size counting by STEM-in-SEM. These results suggest that no significant particle agglomeration occurs in this synthesis. It is noteworthy that nanocomposite 3 showed a slightly larger average crystallite size, as well as particle size (by STEM-in-SEM).
Figure 3 shows the TGA for RGO and the three Fe3O4/RGO nanocomposites. It was observed a mass gain up to 350 °C for nanocomposite 3. This phenomenon was already discussed elsewhere for nanocomposites of Fe3O4/RGO, and it is related to the oxidation of Fe3O4 particles.4242 Zhou, G.; Wang, D. W.; Li, F.; Zhang, L.; Li, N.; Wu, Z. S.; Wen, L.; Lu, G. Q. M.; Cheng, H. M.; Chem. Mater. 2010, 22, 5306. [Crossref]
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Considering the increasing XRD α-Fe2O3 diffraction peak intensities from nanocomposite 3 to nanocomposite 1, it can be argued that the samples with lower iron contents could possess more iron particles in higher oxidation states. These results could explain that the nanocomposites 2 and 1 did not present a mass gain. The maximum mass losses up to 1000 °C for nanocomposites 3, 2, and 1 were about 7, 18, and 26%, respectively. Once bare RGO has a total mass loss of about 95%, the iron oxide contents estimations for nanocomposites 3, 2, and 1 are 88, 77, and 69%, respectively.
The main aspects of the textural analysis of the nanocomposites are shown in Table 2. Isotherm plots Figure S3 (SI section) suggest that all nanocomposites are mesoporous (type IV isotherms). As shown in Table 2, the BET specific surface area of nanocomposite 3 is slightly lower than that of nanocomposite 2, 74 and 81 m2 g−1, respectively. Interestingly, nanocomposite 1 presented a much lower BET specific surface area (25 m2 g−1) than nanocomposites 3 and 2. XRD results showed the peaks related to the formation of a-Fe2O3, yet much larger for nanocomposite 1. A study performed by Jozwiak et al.4343 Jozwiak, W. K.; Kaczmarek, E.; Maniecki, T. P.; Ignaczak, W.; Maniukiewicz, W.; Appl. Catal., A 2007, 326, 17. [Crossref]
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reported a BET specific surface area for an a-Fe2O3, heat-treated at 600 °C, equal to 24 m2 g−1. Therefore, a plausible hypothesis is that the pronounced formation of a-Fe2O3 in nanocomposite 1 reduces its BET specific surface area.
DRS analysis was used to obtain the UV-Vis spectra of the nanocomposites and Fe3O4, aiming to use the Kulbelka-Munk and Tauc methods to extrapolate the indirect bandgap of the materials studied in this work.4444 Kubelka, P.; Munk, F.; Z. Tech. Phys. 1931, 12, 593. [Link] accessed in March 2024
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,4545 Tauc, J.; Grigorovici, R.; Vancu, A.; Phys. StatusSolidiB 1966, 15, 627. [Crossref]
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Figure 4 shows the curves of the indirect bandgap function (F(R)hv)1/2 versus energy for each synthesized nanocomposites and Fe3O4, while the UV-Vis spectra are shown inset. The estimated bandgap values (Table 3) for nanocomposites 3, 2, and 1 were 1.30, 1.41, and 1.50 eV, respectively. All bandgap values of the nanocomposites showed to be lower than the bulk Fe3O4 (1.66 eV), suggesting that RGO is responsible for reducing the gap between the valence and conduction bands.1818 Zheng, M.; Ma, X.; Hu, J.; Zhang, X.; Li, D.; Duan, W.; RSC Adv. 2020, 10, 19961. [Crossref]
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,4646 Jin, Y.; Zheng, Y.; Podkolzin, S. G.; Lee, W.; J. Mater. Chem. C 2020, 8, 4885. [Crossref]
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,4747 Sadiq, M. M. J.; Shenoy, U. S.; Bhat, D. K.; Mater. Today Chem. 2017, 4, 133. [Crossref]
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Furthermore, the bandgap energies of nanocomposites 2 and 1 are, respectively, 0.11 and 0.20 eV higher than for nanocomposite 3.
DRS spectra showing the indirect bandgap energy (F(R)hv)1/2 for all nanocomposites and bulk Fe3O4.
Wang et al.4848 Wang, L.; Nguyen, N. T.; Schmuki, P.; ChemSusChem 2016, 9, 2048. [Crossref]
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studied hematite photoanodes for water splitting, where a bandgap energy of 2 eV was observed for bulk α-Fe2O3. Therefore, these results might be linked to the more pronounced α-Fe2O3 formation in nanocomposites 2 and 1, already discussed in XRD results.
Electron paramagnetic resonance (EPR) and vibrating-sample magnetometry (VSM) were performed to investigate the magnetic properties of the nanocomposites. EPR parameters were obtained by analyzing Figure 5, considering the effective gyromagnetic factor (geff) and the asymmetry ratio (A), according to equations 2 and 3, respectively:
EPR spectra for all nanocomposites, and the visual indication of ΔHhigh, ΔHlow, and Heff values.
where, h, ν, and Heff are the Planck constant, microwave frequency, Bohr magneton and microwave absorption maximum, respectively.
where, AHhigh and AHlow are the half values of the full width at half maximum on the right and left of Heff as represented in Figure 5, respectively. Table 3 shows that the geff values are 3.74 (nanocomposite 3), 3.25 (nanocomposite 2), and 3.10 (nanocomposite 1). These results suggest the presence of larger Fe3O4 particles and/or aggregates in the nanocomposites with higher Fe3O4 contents, as discussed in XRD and STEM-in-SEM results. Also, A values for all nanocomposites are higher than 1, indicating cubic magnetocrystalline anisotropy for all nanocomposites.4949 Klencsár, Z.; Ábrahám, A.; Szabó, L.; Szabó, E. G.; Stichleutner, S.; Kuzmann, E.; Homonnay, Z.; Tolnai, G.; Mater. Chem. Phys. 2019, 223, 122. [Crossref]
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It is important to note that the Fe3O4/RGO nanocomposites were synthesized by an in situ one-step synthesis to anchor iron oxide on GO sheets, before obtaining Fe3O4 particles on RGO sheets. This process might lead to a non-uniform material, due to the heterogeneous nucleation, as discussed in a study performed by Bertran et al.5050 Bertran, A.; Sandoval, S.; Oró-Solé, J.; Sanchez, À.; Tobias, G.; J. Colloid Interface Sci. 2020, 566, 107. [Crossref]
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VSM curves of the magnetic nanocomposites are shown in Figure 6, and Table 3 shows the parameters obtained. The descending order of saturation magnetization (Ms) is: 63.6 emu g−1 (nanocomposite 3), 51.6 emu g−1 (nanocomposite 2), and 31.7 emu g−1 (nanocomposite 1). The coercive fields (HC) are 327.5 Oe (nanocomposite 3), and 136.4 (nanocomposites 2 and 1). These results, combined with the squareness ratio (MR/MS) indicate the better response of nanocomposite 3 to the applied magnetic field, probably due to the higher iron oxide content that results in larger Fe3O4 particles and/or aggregates.5151 Petrychuk, M.; Kovalenko, V.; Pud, A.; Ogurtsov, N.; Gubin, A.; Phys. Status Solidi A 2010, 207, 442. [Crossref]
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Even though it is clear that the magnetization saturation values decrease with lower Fe3O4 contents in the nanocomposites, the EPR and VSM results combination shows that all nanocomposites still maintain their pronounced ferromagnetic character.
VSM curves for all nanocomposites. The inset shows an amplification from −370 Oe to 370 Oe used to define Mr and Hc parameters.
Figure 7 shows the Mŏssbauer spectra of the nanocomposites taken at room temperature. It is well resolved magnetic hyperfine patterns with no indications for superparamagnetism on the time scale of nuclear Larmor precession (i.e., magnetic fluctuations must be slower than 10−8−10−9 s−1) as expected for the here investigated crystallite sizes (see Table 2). Under these conditions 57Fe Mössbauer spectra allow to discriminate various iron oxide phases by their different hyperfine parameters, i.e., primarily the isomer shift S (its value indicates the iron valency in various lattice sites), the nuclear electric quadrupole splitting QS (reflecting the deviations from cubic site symmetry), and the magnetic hyperfine field B. In addition to these for the different iron oxides specific parameters one can determine the population of lattice sites (e.g., the tetrahedral A and octahedral B sites in Fe3O4). Data analysis was performed using MossWinn 4.0i software.5252 Klencsár, Z.; Kuzmann, E.; Vértes, A.; J. Radioanal. Nucl. Chem. 1996, 210, 105. [Crossref]
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For the fit of the spectra we used a superposition of 4 magnetic sextet patterns: one for the trivalent A site of Fe3O4, one for its intermediate valent B site, a further pattern of minor intensity attributed to distorted and less magnetic sites B’, and one sextet for α-Fe2O3. The line shapes were assumed as Lorentzians with full width W. The magnetic hyperfine fields show a distribution (as typically found for nanoparticles) that is assumed to have Gaussian shape of width σ.
All magnetic patterns reveal indications for a non-random orientation of magnetic moments with respect to the gamma ray direction. This can be taken as an indication for a texture effect induced by the graphene sheet morphology.
For nanocomposites 1 and 2 (not 3) a further contribution is visible in the center of spectra that can be reproduced by a doublet pattern, i.e., a non-magnetic contribution, yet with a spectral weight of only a few percent, of a not well defined FeOx.
The hyperfine parameters are summarized in Table 4. The central result from these Mőssbauer data is the quantitative separation of the contributions by Fe3O4 and α-Fe2O3. The hyperfine parameters of both phases are in good agreement with literature values.5353 Murad, E.; Hyperfine Interact. 1998, 117, 39. [Crossref]
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,5454 Dézsi, I.; Fetzer, Cs.; Gombkötő, Á.; Szűcs, I.; Gubicza, J.; Ungár, T.; J. Appl. Phys. 2008, 103, 104312. [Crossref]
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The additional octahedral B’ site in Fe3O4 can be possibly associated with grain surface sites. The overall population of octahedral versus tetrahedral sites is about 1.7(2):1 and thus reduced against the ideal value of 2:1 for stoichiometric magnetite. A possible reason is that in our analysis we used the spectral areas as identical with site occupation without correction for differing Debye-Waller factors. While the nanocomposites 2 and 3 reveal comparable amounts of hematite, the amount in nanocomposite 1 is clearly enhanced which agrees with our XRD results.
IC photo-Fenton discoloration
IC discoloration in the absence of a heterogeneous catalyst
IC (2.1 × 10−5 mol L−1) discoloration results by varying the H2O2 inputs without any nanocomposites, named photolysis, are shown in Figure 8a. These tests were conducted prior to the heterogeneous photo-Fenton IC discoloration aiming to set the H2O2 starting concentration. It is important to highlight that, in the absence of a heterogeneous catalyst, the IC discoloration already occurs with H2O2, due to its decomposition, as reported elsewhere.3030 Gonçalves, A. H. A.; Siciliano, P. H. C.; Alves, O. C.; Cesar, D. V.; Henriques, C. A.; Gaspar, A. B.; Top. Catal. 2020, 63, 1017. [Crossref]
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,3838 Aleboyeh, A.; Aleboyeh, H.; Moussa, Y.; Environ. Chem. Lett. 2003, 1, 161. [Crossref]
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Table S1 (SI section) shows the apparent rate constant (kapp) obtained by applying the pseudo-first-order kinetics fitting,5555 Agorku, E. S.; Mamo, M. A.; Mamba, B. B.; Pandey, A. C.; Mishra, A. K.; Mater. Sci. Semicond. Process. 2015, 33, 119. [Crossref]
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,5656 Agorku, E. S.; Mamo, M. A.; Mamba, B. B.; Pandey, A. C.; Mishra, A. K.; J. Porous Mater. 2015, 22, 47. [Crossref]
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,5757 Eroi, S. N.; Ello, A. S.; Diabaté, D.; Ossonon, D. B.; S. Afr. J. Chem. Eng. 2021, 37, 53. [Crossref]
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,5858 Khanh, D. N. N.; Tho, N. T. M.; Thang, N. Q.; Tien, N. T.; Phong, C. T.; Cang, M. H.; Phuong, N. T. K.; Vietnam J. Sci. Technol. 2019, 57, 575. [Crossref]
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from the data displayed in Figure S4, for each test and their corresponding goodness of fit (R2) values. The descending order of kapp values with their respective H2O2 concentrations was: 1.65 × 10−2 min−1 (2.3 × 10−1 mol L−1) > 0.55 × 10−2 min−1 (1.2 × 10−1 mol L−1) > 0.31 × 10−2 min−1 (0.6 × 10−1 mol L−1). These results clearly indicate a significant contribution of the H2O2 as the oxidizing agent. However, UV-Vis spectra of the test with the highest IC discoloration (2.3 × 10−1 mol L−1 of H2O2) shows that, even in the highest [H2O2], the peak 611 nm does not decrease in a satisfactory magnitude, reflecting in a maximum IC discoloration below 50%.
IC discoloration with different H2O2 inputs, and without a photocatalyst (a), and UV-Vis spectra for photolysis test with the following concentrations: [IC] = 2.1 × 10−5 mol L−1, and [H2O2] = 2.3 × 10−1 mol L−1 (b).
IC discoloration in function of [H2O2] can be explained by the more available H2O2 molecules to be photo-decomposed, leading to higher •OH radical generation (equation 4).3838 Aleboyeh, A.; Aleboyeh, H.; Moussa, Y.; Environ. Chem. Lett. 2003, 1, 161. [Crossref]
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It is worth mentioning that no decrease was observed in IC discoloration with the increasing of H2O2 loading, as discussed elsewhere.3838 Aleboyeh, A.; Aleboyeh, H.; Moussa, Y.; Environ. Chem. Lett. 2003, 1, 161. [Crossref]
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If an excess of H2O2 is added to the photo-Fenton system, it may lead to the formation of hydroperoxyl radicals (•O2H) and water, described in equations 5 and 6.
Furthermore, if the system is saturated with •OH radicals, they may immediately combine to form hydrogen peroxide (equation 7).
With respect to photo-Fenton dye discoloration, products formed in equations 5, 6, and 7 are not desirable, since they are much less reactive than OH radicals.5959 Zhang, Y.; Li, D.; Chen, Y.; Wang, X.; Wang, S.; Appl. Catal., B 2009, 86, 182. [Crossref]
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,6060 Ji, F.; Li, C.; Zhang, J.; Deng, L.; Desalination 2011, 269, 284. [Crossref]
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For instance, •O2H and H2O2 have oxidation potentials of 1.4 and 1.8 V, respectively, while •OH radicals have a much higher oxidation potential of 2.8 V. According to Figures 8 and S4 (SI section), the highest H2O2 concentration tested in this work (2.3 × 10−1 mol L−1) seems to be below the H2O2 limit, this concentration being therefore selected to perform the heterogeneous photo-Fenton tests with the three synthesized nanocomposites and bulk Fe3O4.
Heterogeneous IC photo-Fenton discoloration
At first, the heterogeneous photocatalytic tests were carried out with a catalyst load of 0.67 g L−1, 30 mL of IC solution (2.1 × 10−5 mol L−1), and 30% H2O2 (2.3 × 10−1 mol L−1) (Figure S5, SI section). The choice of using this catalyst dosage was based on our previous study,3030 Gonçalves, A. H. A.; Siciliano, P. H. C.; Alves, O. C.; Cesar, D. V.; Henriques, C. A.; Gaspar, A. B.; Top. Catal. 2020, 63, 1017. [Crossref]
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which described a Fe3O4/RGO nanocomposite that discolored an IC solution (2.1 × 10−5 mol L−1) within 5 min. All nanocomposites showed to be very active in the IC photo-Fenton discoloration and presented superior IC discoloration performance than the photolysis with 2.3 × 10−1 mol L−1 of H2O2. However, with a catalyst dosage of 0.67 g L−1, it was impossible to note a significant difference among the three nanocomposites. Furthermore, due to the fast discoloration observed with all nanocomposites, a reliable acquisition of enough points to perform the kinetics calculations was prevented, thus no kinetic plots for 0.67 g L−1 are presented in this work. Aiming to investigate the IC photo-Fenton discoloration kinetics with the synthesized nanocomposites, the catalyst dosage was reduced by half. Figure 9 shows the IC discoloration with a catalyst dosage of 0.33 g L−1 and H2O2 (2.3 × 10−5 mol L−1), as well as the kinetic plots for each nanocomposite.
IC photo-Fenton discoloration for the different nanocomposites with a catalyst dosage of 0.33 g L−1.
In Figure 9, a noticeable difference can be observed among the three nanocomposites. IC discoloration at 5 min for nanocomposite 3 was 93.9%, followed by nanocomposite 2 (90.8%) and nanocomposite 1 (60.7%). It is also important to note that nanocomposite 3 reached a maximum IC discoloration of 99.7% at 30 min. Once again, even lowering the catalyst dosage by half, all nanocomposites showed to be far more active than photolysis with 2.3 × 10−1 mol L−1 of H2O2. Furthermore, nanocomposites 3 and 2 discoloration curves showed to be higher than for bulk Fe3O4. The data for the heterogeneous photo-Fenton tests (Figure S6, SI section) were also best fitted with the pseudo-first order model, as described for the tests without the heterogeneous photocatalysts. The kapp and R2 values for each nanocomposite and bulk Fe3O4 are presented in Table S1 (SI section). The kapp-descending ranking was as follows: nanocomposite 3 (8.99 × 10−2 min−1) > nanocomposite 2 (8.51 × 10−2 min−1) > Fe3O4 (6.13 × 10−2 min−1) > nanocomposite 1 (3.69 × 10−2 min−1). These results indicate that RGO improves the photocatalytic character of the Fe3O4 nanoparticles, except for nanocomposite 1.
This assumption can be supported by STEM-in-SEM particle counting and XRD crystallite size, which showed that Fe3O4 nanoparticles of 12-15 nm size (STEM-in-SEM) were successfully anchored on RGO sheets, resulting in more available particles to transform H2O2 molecule into •OH radicals. Furthermore, the narrower bandgap, estimated by DRS analysis, after Fe3O4 nanoparticles immobilization on RGO, leads to a more active photocatalyst. In addition, the slight difference in photocatalysis activity between nanocomposite 3 and 2 may be linked to their slightly different formation of a-Fe2O3, observed by XRD and Mŏssbauer analysis. Yet for these two nanocomposites, the appearance of a non-magnetic FeOx oxide in composite 2, confirmed by Mŏssbauer analysis, also supports its lower activity. According to Liu et al.,6161 Liu, Y.; Jin, W.; Zhao, Y.; Appl. Catal., B 2017, 206, 642. [Crossref]
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hematite presents lower activity than other iron oxide phases in the Fenton reaction because it exhibits a high electron-hole recombination rate. In addition, the bandgap for Fe2O3 reported in literature is wider than for Fe3O4.6262 Iqbal, R. M.; Wardani, D. A. P.; Hakim, L.; Damsyik, A.; Safitri, R.; Fansuri, H.; IOP Conf. Ser.: Mater. Sci. Eng. 2020, 833, 012072. [Crossref]
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DRS analysis also showed that nanocomposite 2 presented a higher bandgap value than nanocomposite 3, corroborating with the observed by XRD analysis. On the contrary, nanocomposite 1 did not perform better than bulk Fe3O4. This behavior can be explained by the combination of the results obtained in the characterization section. FESEM-EDX (Table 1) and EDX mapping (Figure S2) showed that nanocomposite 1 presented a high discrepancy in iron distribution through RGO sheets. This may lead to iron oxide agglomerates thus lowering its specific surface area, confirmed by textural analysis. Furthermore, the more pronounced formation of α-Fe2O3, and non-magnetic FeOx, observed by XRD analysis and Mössbauer spectroscopy, may contribute to lower performance, due to its wider bandgap and higher electron-hole recombination rates.
The photo-Fenton heterogeneous IC discoloration with the Fe3O4/RGO nanocomposites can be summarized by equations 8 9 10 11. Firstly, when Fe3O4/RGO nanocomposite is irradiated by visible light, it absorbs a photon, photo exciting an electron from valence band to the conduction band. This phenomenon is responsible for creating an electron hole in the valence band (equation 8). The promoted electron (e−) on RGO surface in contact with H2O2 and H+ generates the •OH radicals (equation 9), whereas the hole (h+) in Fe3O4 combined with the water OH−, also results in •OH radicals. These structures attack the IC molecule, generating degradation products, leading to the discoloration of the solution.
Due to the best performance in IC discoloration, nanocomposite 3 was selected and a nanocomposite dosage variation study was conducted considering IC discoloration (2.1 × 10−5 mol L−1) and H2O2 (2.3 × 10−1 mol L−1) (Figures 10, S7 and Table S1, SI section). All IC discoloration curves for the three loads of nanocomposite 3 showed to be higher than the photolysis, with emphasis on 0.33 g L−1 curve (IC discoloration of 99.7% at t = 30 min). Although nanocomposite 3 dosages of 0.17 and 0.07 g L−1 resulted in discoloration curves higher than the photolysis test until t = 20 min, they became significantly close at the succeeding times. Therefore, these loads were not enough to observe the photocatalyst activity, and the dosage of 0.33 g L−1 was fixed.
Figures 11, S8 and Table S1 show the photocatalytic tests and results of nanocomposite 3 for different H2O2 inputs, performed with a photocatalyst dosage of 0.33 g L−1 and 30 mL of IC solution (2.1 × 10−5 mol L−1) nanocomposite. In this sense, two more tests varying the H2O2 concentration, and another without H2O2 were executed to observe if the H2O2 amount could be reduced in the heterogeneous photo-Fenton IC photocatalysis, without losing significant discoloration results.
IC photo-Fenton discoloration with different H2O2 concentrations and nanocomposite 3 (0.33 g L−1) (a), UV-Vis absorption spectra obtained for each time interval for IC photo-Fenton discoloration with nanocomposite 3 (0.33 g L−1) with the following concentrations: [IC] = 2.1 × 10−5 mol L−1, and [H2O2] = 2.3 × 10−1 mol L−1.
As can be seen in Figure 11, S8, and Table S1 (SI section), reducing the H2O2 concentrations to 1.2 × 10−1 mol L−1 and 0.6 × 10−1 mol L−1, leads to a decrease in IC discoloration at t = 5 min, to 87.3% (kapp = 6.94 × 10−2 min−1) and 70.1% (kapp = 5.02 × 10−2 min−1), respectively for the nanocomposite 3. Furthermore, if H2O2 is completely removed from this system, a drastic activity drop is observed (IC discoloration at t = 5 min equal to 39.4% and kapp = 0.30 × 10−2 min−1). The results found for the H2O2 concentration study with nanocomposite 3 (0.33 g L−1), compared with the tests without a heterogeneous photocatalyst, clearly indicate that the presence of the Fe3O4/RGO nanocomposite is responsible for facilitating the •OH radical formation, thus improving the IC discoloration.
Fe3O4/RGO nanocomposite reuse tests
The reuse tests for nanocomposite 3 are shown in Figure 12. In Figure 12a, it is observed that nanocomposite 3 remained its outstanding activity (ca. 99%) after 30 min for, at least, three recycles or four runs, while Figure 12b reflects the UV-Vis spectra of the withdrawn aliquots.
IC photo-Fenton discoloration curves for nanocomposite 3 recycling tests (a), UV-Vis absorption spectra obtained for each time interval for IC photo-Fenton discoloration with the third reuse of nanocomposite 3 (0.33 g L−1) with the following concentrations: [IC] = 2.1 × 10−5 mol L−1, and [H2O2] = 2.3 × 10−1 mol L−1 (b).
Figures 13a-13b show the XPS analysis of fresh nanocomposite 3, and after its third recycle. The Fe2p spectra comparison (Figure 13a) indicates that Fe2p3/2 and Fe2p1/2 photoelectron peaks did not have any significant displacements for both samples, as well as the spin-orbit splitting, which remained at 13.6 eV. After a thorough Fe2p3/2 peak fitting with the parameters described by Biesinger et al.,6363 Biesinger, M. C.; Payne, B.; Grosvenor, A. P.; Lau, L. W. M.; Gerson, A. R.; Smart, R. S. C.; Appl. Surf. Sci. 2011, 257, 2717. [Crossref]
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it was observed that the FeIII/FeII ratio persisted at 1.9. These results are strong evidence that RGO stabilizes the FeIII/FeII pair, maintaining its activity, and by mitigating the electron (e−)-hole (h+) recombination, a critical phenomenon that is responsible for the deactivation of photocatalysts.5555 Agorku, E. S.; Mamo, M. A.; Mamba, B. B.; Pandey, A. C.; Mishra, A. K.; Mater. Sci. Semicond. Process. 2015, 33, 119. [Crossref]
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,5656 Agorku, E. S.; Mamo, M. A.; Mamba, B. B.; Pandey, A. C.; Mishra, A. K.; J. Porous Mater. 2015, 22, 47. [Crossref]
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,5858 Khanh, D. N. N.; Tho, N. T. M.; Thang, N. Q.; Tien, N. T.; Phong, C. T.; Cang, M. H.; Phuong, N. T. K.; Vietnam J. Sci. Technol. 2019, 57, 575. [Crossref]
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However, higher RGO amounts, as observed by XRD for nanocomposites 2 and 1, lead to a-Fe2O3 formation, changing the nanocomposite physical-chemical properties, thus reducing its photocatalytic activity. Moreover, other works that synthesized different semiconductor oxides/RGO nanocomposites observed that adding low amounts of RGO is crucial for maintaining their photocatalytic activity,2222 Su, G.; Liu, L.; Zhang, L.; Liu, X.; Xue, J.; Tang, A.; Environ. Sci. Pollut. Res. 2021, 28, 50286. [Crossref]
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,2424 Jiang, X.; Li, L.; Cui, Y.; Cui, F.; Ceram. Int. 2017, 43, 14361. [Crossref]
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,6464 Wei, Z.; Huang, S.; Zhang, X.; Lu, C.; He, Y.; J. Mater. Sci.: Mater. Electron. 2020, 31, 5176. [Crossref]
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supporting that higher RGO contents above an optimal RGO load result in lower performances.
Fe2p XPS photoelectron spectra (a), and Fe2p3/2 peak fitting (b) of fresh and reused (3 recycles, or 4 runs) nanocomposite 3.
Critical assessment of IC discoloration with Fe3O4/RGO nanocomposites
One concern about heterogeneous Fenton-like reactions with H2O2 is that the generated •OH radicals have very short half-life, meaning that these structures can be rapidly transformed before attacking the pollutant molecule in bulk solution, thus reducing the system efficiency.6565 Zhang, S.; Sun, M.; Hedtke, T.; Deshmukh, A.; Zhou, X. C.; Weon, S.; Elimelech, M.; Kim, J.-H.; Environ. Sci. Technol. 2020, 54, 10868. [Crossref]
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In this sense, Xu et al.6666 Xu, H.-Y.; Xu, Y.; Zhang, S.-Q.; Dai, L.-Y.; Wang, Y.; Mater. Lett. 2023, 337, 133985. [Crossref]
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designed a nanoreactor of halloysite nanotubes internally loaded with Fe3O4 nanoparticles (Fe3O4@HNTs), aiming to increase the reaction medium confinement, thus improving radicals utilization in methyl orange (MO) dye discoloration. This author indeed observed that in the condition with nanoconfinement, MO discoloration was significantly improved. Furthermore, by using radical scavenging experiments, this author also observed that besides •OH radical, the formation of 1O2 also has crucial role in MO discoloration. Therefore, the presence of other reactive oxygen species cannot be discarded. Thus, quenching experiments are suggested to improve understanding of the IC degradation mechanism for further works.6767 Li, B.; Xu, H.-Y.; Liu, Y. L.; Liu, Y.; Xu, Y.; Zhang, S. Q.; Chem. Eng. J. 2023, 467, 143396. [Crossref]
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Nevertheless, in our work, RGO was used to anchor and stabilize Fe3O4 nanoparticles, and especially for nanocomposite 3. Besides its high Fe3O4 load we can observe that it presented low nanoparticle mean size (Figure 1c and Table 1), improved textural properties such as high surface area (Table 1), and mesoporous structure (Figure S3, SI section). Thus, these properties may provide favorable conditions to the continuous reactive oxygen species generation and its further utilization, as well as the IC dye adsorption onto Fe3O4/RGO active sites, once these reactions are known to occur mostly on the heterogeneous catalyst surface.6868 Xu, H.-Y.; Zhang, S.-Q.; Wang, Y.-F.; Xu, Y.; Dong, L. M.; Komarneni, S.; Appl. Surf. Sci. 2023, 614, 156225. [Crossref]
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This hypothesis can be endorsed by Figure 11a, which shows that the increase in [H2O2] for nanocomposite 3 reflects in a higher and faster IC discoloration.
Table 5 brings information about IC discoloration in the presence of distinct photocatalysts from other works. References,6969 Coelho, M. G.; de Lima, G. M.; Augusti, R.; Maria, D. A.; Ardisson, J. D.; Appl. Catal., B 2010, 96, 67. [Crossref]
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,7070 Oliveira, W. L.; Ferreira, M. A.; Mourão, H. A. J. L.; Pires, M. J. M.; Ferreira, V.; Gorgulho, H. F.; Cipriano, D. F.; Freitas, J. C. C.; Mastelaro, V. R.; Nascimento, O. R.; Ferreira, D. E. C.; Fioravante, F. R.; Pereira, M. C.; de Mesquita, J. P.; J. Colloid Interf. Sci. 2021, 587, 479. [Crossref]
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,7171 Hadjltaief, H. B.; Bairq, Z. A. S.; Shi, C.; Benzina, M.; Surf. Interfaces 2021, 26, 101395. [Crossref]
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,7272 Ray, S. K.; Dhakal, D.; Lee, S. W.; Mater. Sci. Semicond. Process. 2020, 105, 104697. [Crossref]
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not discussed in the text, are displayed only in Table 5 for comparison purposes. Considering the maximum discoloration, the time to reach it, and the kapp values, the present work shows quick IC photo-Fenton discoloration, and very active Fe3O4/RGO nanocomposites, with emphasis on nanocomposite 3. Furthermore, some works listed in Table 5 also performed photocatalyst recovery and new IC discoloration cycles. As aforementioned, our Fe3O4/RGO nanocomposites possess a strong magnetic character, providing an easy recovery method for succeeding IC discoloration cycles. Comparing it with the literature on the recycling capability of nanocomposite 3, one can infer that this is promising. In addition, this work did not use any initial pH correction or sonification and was carried out at room temperature, leading to a simpler IC discoloration system.
Indigo carmine (IC) heterogeneous catalysis discoloration results of different works found in literature
A facile two-step method to anchor and disperse high loads of Fe3O4 over RGO sheets was successfully adapted from the Stöber-like3131 Qiu, B.; Li, Q.; Shen, B.; Xing, M.; Appl. Catal. B: Environ. 2017, 183, 216. [Crossref]
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method, resulting in very active nanocomposites for IC discoloration. With this approach, we were able to employ cost-effective reagents and mild temperature (60 °C) during iron particles nucleation, which are important aspects that could result in scalable processes for environmentally friendly nanocomposites production, as discussed elsewhere.7373 Ansari, S. A.; Kumar, R.; Barakat, M. A.; Cho, M. H.; J. Mater. Sci.: Mater. Electron. 2018, 29, 7792. [Crossref]
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,7474 Parveen, N.; Alqahtani, F. O.; Alsulaim, G. M.; Alsharif, S. A.; Alnahdi, K. M.; Alali, H. A.; Ahmad, M. M.; Ansari, S. A.; Nanomaterials 2023, 13, 2835. [Crossref]
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,7575 Ansari, S. A.; Ceram. Int. 2023, 49, 17746. [Crossref]
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,7676 Ansari, S. A.; Parveen, N.; Alsulaim, G. M.; Ansari, A. A.; Alsharif, S. A.; Alnahdi, K. M.; Alali, H. A.; Reddy, V. R. M.; Surf. Interfaces 2023, 40, 103078. [Crossref]
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In this sense, the facile synthesis, physical-chemical properties, reusability, and simplicity of the photo-Fenton system described, is a set of features that can be considered, aiming to contribute to the remediation of dye-containing wastewater. Furthermore, adding low amounts of RGO to iron oxide/RGO nanocomposites might be attractive once iron oxides are abundant, thus cost-effective.
Conclusions
Fe3O4/RGO nanocomposites were synthesized with different precursor ratios (Fe(NO3)3.9H2O:GO) and evaluated in the photo-Fenton discoloration of indigo carmine. The materials were characterized, and their physical-chemical properties were associated with their performances in the indigo carmine photo-Fenton discoloration.
Microscopic analysis showed that the nanocomposites with higher iron precursor loads resulted in well-distributed iron oxide nanoparticles on RGO sheets. In parallel, XRD patterns and Mössbauer spectra showed that lowering the Fe(NO3)3.9H2O:GO ratio leads to the formation of a crystalline a-Fe2O3 phase, and formation of a non-magnetic FeOx.
The photocatalyst with the best performance in indigo carmine (2.1 × 10−5 mol L−1) photo-Fenton discoloration was the nanocomposite 3 ((Fe(NO3)3.9H2O:GO) mass ratio of 17:1). With a photocatalyst dosage and H2O2 concentration of 0.33 g L−1 and 2.3 × 10−1 mol L−1, respectively, IC discoloration reached 99.7% (kapp = 8.99 × 10−2 min−1), at 30 min of reaction. The well-dispersed Fe3O4 nanoparticles can explain this outstanding activity on RGO sheets, BET surface area (74 m2 g−1), and narrower bandgap.
The magnetic properties of the nanocomposites, proven by the VSM analysis, contributed to facilitate their removal from the system in the reuse tests. Nanocomposite 3 could be reused at least three times without significant activity loss. XPS analysis showed that the FeIII/FeII surface ratio did not change after the third recycle, meaning that RGO sheets are responsible for stabilizing the Fe3O4 nanoparticles by hindering electron-hole recombination.
In conclusion, Fe3O4/RGO nanocomposites are proving to be promising photocatalysts. Their physical-chemical properties lead to remarkable dye discoloration results, and their reusability is important in reducing operational costs. Furthermore, their facile synthesis could motivate new studies such as scalability and other applications.
Supplementary Information
Supplementary information (EDX mapping, BET surface area and pore size distribution, IC discoloration curves and data) is available free of charge at http://jbcs.sbq.org.br as PDF PDF file.
Acknowledgments
The authors acknowledge the Kinetics and Catalysis Laboratory (LCC/UERJ) staff for the XRD results, the Polymeric Materials Technology Laboratory (LAMAP/DIPCM/INT) staff for the TGA analyses, the Center of Characterization in Nanotechnology for Materials and Catalysis (CENANO/INT), National System of Nanotechnology Laboratories (MCTI/SisNANO/INT-CENANO-CNPq Process No. 442604/2019-0), for the STEM-in-SEM, Francisco L. C. Rangel for the FESEM, Fabiana M. T. Mendes and Erika B. Silveira for the XPS analyses, Brazilian Center for Physical Research (CBPF) for the EPR and VSM measurements, and Marcos A. da Silva (NUCAT/PEQ/COPPE/UFRJ) for the DRS analyses. The authors also acknowledge FINEP (01.22.0282.00) and CNPq (408369/2022-1) for the financial support.
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Edited by
Publication Dates
-
Publication in this collection
26 Apr 2024 -
Date of issue
2024
History
-
Received
12 Nov 2023 -
Accepted
03 Apr 2024