Abstract

INTRODUCTION

The support employed in catalysts preparation usually affects the activity, selectivity and stability. In reforming catalysts, the support should fulfill with different requirements (i) favor the water dissociation in OH groups and their migration to the metallic particle; (ii) promote mainly the dehydrogenation reaction instead of the dehydration to mitigate the coke deactivation; and (iii) contribute to the metallic particles stabilization keeping the dispersion as high as possible during long reaction times. Complex oxides, spinel type (AB₂O₄, with a close-packed oxygen ion structure), have been employed as supports in many catalytic systems due to their lower acidity compared with Al₂O₃ and their high resistance to sintering and coking.¹1 Sehested, J.; Gelten, J. A. P.; Remediakis, I. N.; Bengaard, H.; Norskov, J. K.; J. Catal. 2004, 223, 432.^,22 Barroso, M. N.; Galetti, A. E.; Gomez, M. F.; Arrúa, L. A.; Abello, M. C.; Chem. Eng. J. 2013, 222, 142. In particular, the Mg spinel has shown to be a very good alternative to support Co and/or Ni for catalysts employed in the ethanol steam reforming reaction.³3 Barroso, M. N.; Gomez, M. F.; Arrúa, L. A.; Abello, M. C.; Int. J. Hydrogen Energy 2014, 39, 8712.^,44 Galetti, A. E.; Barroso, M. N.; Gomez, M. F.; Arrua, L. A.; Monzón, A.; Abello, M. C.; Catal. Lett. 2012, 142, 1461.

The support can be doped with different additives which are incorporated for instance to change the metal-support interaction, the acid-base properties and to increase tolerance to sintering and coke. CeO₂ is considered a powerful promoter to modify the structural and electronic properties of catalysts. It has been widely used due to the attractive acid-base and redox properties. Ceria could affect the thermal and structural stability of catalytic support and the dispersion of the active phase. Besides, as a consequence of the well-known capacity to deliver and store oxygen and to the presence of Ce³⁺/Ce⁴⁺ couple in oxidant atmospheres, CeO₂ increases the tolerance to carbon deposition. The addition of CeO₂ on Ni/MgAl₂O₄ catalysts has shown a positive effect for increasing the carbon deposition resistance.⁴4 Galetti, A. E.; Barroso, M. N.; Gomez, M. F.; Arrua, L. A.; Monzón, A.; Abello, M. C.; Catal. Lett. 2012, 142, 1461. The deactivation in the ethanol steam reforming is a great inconvenience for technological applications. The influence of CeO₂ addition will depend on its loading and the synthesis method, which affects the metallic dispersion and reducibility of active phase.⁵5 Luisetto, I.; Tuti, S.; Battocchio, C.; Lo Mastro, S.; Sodo, A.; Appl. Catal., A 2015, 500, 12.

In the literature, the use of chelating agents has been reported in the preparation of hydrodesulfurization catalysts,⁶6 Escobar, J.; Barrera, M. C.; de los Reyes, J. A.; Toledo, J. A.; Santes, V.; Colin, J. A.; J. Mol. Catal. A: Chem. 2008, 287, 33.^,77 Peña, L.; Valencia, D.; Klimova, T.; Appl. Catal., B 2014, 147, 879. of reforming reactions⁸8 Karnjanakom, S.; Guan, G.; Asep, B.; Dua, X.; Hao, X.; Samart, C.; Abudula, A.; Energy Conversion Manage. 2015, 98, 359.

9 Lu, X.; Chen, J-F.; Tan, Y.; Zhang, Y.; Catal. Commun. 2012, 20, 6.

10 Bang, Y.; Park, S.; Han, S-J.; Yoo, J.; Song, J-H.; Choi, J. H.; Kang, K. H.; Song, I. K.; Appl. Catal., B 2016, 180, 179.^-1111 Daza, C. E.; Gallego, J.; Mondragón, F.; Moreno, S.; Molina, R.; Fuel 2010, 89, 592. and for the Fischer-Tropsch synthesis,¹²12 Mochizuki, T.; Hara, T.; Koizumi, N.; Yamada, M.; Appl. Catal., A 2007, 317, 97.^,1313 Girardon, J-S.; Quinet, E.; Griboval-Constant, A.; Chernavskii, P. A.; Gengembre, L.; Khodakov, A. Y.; J. Catal. 2007, 248, 143. among others. The use of aqueous solutions of chelated metal complexes in the wet impregnation method is very interesting, as it maintains the simplicity of the technique; it allows a high reproducibility of synthesis, uniform distributions of active phase and higher metallic dispersions. One characteristic of these solutions is the increase of viscosity during solvent removal in the drying step, inhibiting the distribution of surface species and forming poorly crystallized compounds with high dispersion.¹⁴14 van Dillen, A. J.; Terorde, R. J. A. M.; Lensveld, D. J.; Geus, J. W.; de Jong, K. P.; J. Catal. 2003, 216, 257. Several factors should be taken into account in the preparation with chelating ligands; for instance, the pH of solution which determines the complexing ability, the point of zero charge (PZC) of the support,¹³13 Girardon, J-S.; Quinet, E.; Griboval-Constant, A.; Chernavskii, P. A.; Gengembre, L.; Khodakov, A. Y.; J. Catal. 2007, 248, 143. the nature of the ligand, the thermal precursor decomposition and the drying procedure. The pH of the solution plays a significant role in the complex compound formation, in the surface speciation on the support and in the control of metal-support interactions.¹⁵15 Suarez Toriello, V. A.; Santolalla Vargas, C. E.; de los Reyes, J. A.; Vazques Zavala, A.; Vrinat, M.; Geantet, C.; J. Mol. Catal. A: Chem. 2015, 404-405, 36. The chelating agents most widely used in preparation of supported catalysts are: ethylendiaminetetraacetic acid (EDTA), nitrilotriacetic acid (NTA) and citric acid (CA). This class of ligands forms soluble and very stable complexes with a wide range of metals. Besides, the obtained precursors contain C, H, N or O, thereby avoiding any contamination. The thermal decomposition of the complexes is completed at moderate temperatures, and the residual carbon contamination on the support surface is negligible.¹⁶16 Wullens, H.; Leroy, D.; Devillers, M.; Int. J. Inorg. Mater. 2001, 3, 309.

The existence of a correlation between the Ce³⁺/Ce⁴⁺ surface ratio and the carbon amounts deposited in the ethanol steam reforming reaction over Ni/CeO₂-MgAl₂O₄ catalysts was reported in previous works.¹⁷17 Tarditi, A.; Barroso, M. N.; Galetti, A. E.; Arrúa, L. A.; Cornaglia, L.; Abello, M. C.; Surf. Interf. Anal. 2014, 46, 521.^,1818 Villagrán-Olivares, A.; Gomez, M. F.; Barroso, M. N.; Abello, M. C.; IJIC 2018, 9, 61. The reduction of surface ceria was facilitated by the presence of Ni.¹⁹19 Galetti, A. E.; Gomez, M. F.; Arrúa, L. A.; Abello. M. C.; Appl. Catal., A 2010, 380, 40. This synergetic effect was observed upon establishment of interactions between dispersed nickel oxide and ceria oxide. The NiO-CeO₂ interaction and concomitantly the Ce³⁺/Ce⁴⁺ surface ratio could increase with an enhancement in CeO₂ dispersion (lower particle sizes). Considering the advantages of using chelating agents in the impregnation step of catalysts and the possibility of Ce to form complexes with NTA,²⁰20 Suzuki, Y.; Nankawa, T.; Francis, A. J.; Ohnuki, T.; Radiochim. Acta 2010, 98, 397. EDTA²¹21 Muñoz, M.; Moreno, S.; Molina, R.; Catal. Today 2013, 213, 33.^,2222 Abbaspour, A.; Mehrgardi, M.; Talanta 2005, 67, 579. and CA,²³23 Verma, A.; Bakhshi, A. K.; Agnihotry, S. A.; Sol. Energy. Mater. Sol. Cells 2006, 90, 1640. in this work the properties of Mg spinel doped by Ce complexes were studied. As far as we know, it has not been reported the effect of using Ce complexes on the interaction with Mg spinel. The results presented are part of a larger study related to the development of Ni catalysts supported in MgAl₂O₄ for obtaining hydrogen from the reaction of ethanol reforming with steam.

EXPERIMENTAL

Samples preparation

The MgAl₂O₄ used as support was synthetized using the citrate method under the experimental conditions described in reference 4. The CeO₂ addition (nominal loading 5 wt.%) was carried out by the chelating agents-assisted impregnation method. Three chelating agents: EDTA (Sigma-Aldrich, 99%), NTA (Sigma-Aldrich, 99%) or CA (Sigma-Aldrich, 99,5%) with a metal to ligand molar ratio 1:1 were used. Two types of aqueous solutions of Ce(NO₃)₃·6H₂O (Aldrich, 99%) with chelating agents were prepared: (i) acid solutions obtained by the dissolutions of chelating ligands with the cerium salt (pH between 1.5-3, Table 1) and (ii) basic solutions obtained from those prepared in (i) by the NH₄OH addition (pH between 8-9.4, Table 1). These complex aqueous solutions were added to 300 mg of MgAl₂O₄ spinel under stirring at room temperature. The solvent was removed by evaporation in a rotavapor at 75 °C under a pressure between 8-10 mmHg. The sample was dried in a vacuum oven at 100 °C overnight. The calcination was carried out in static air from room temperature to 600 °C at 10 °C min^-1, and then 1 h at 600 °C. The ceria-doped spinel carriers were named as CeL(x) being L = EDTA, NTA or CA and x = a or b, if the impregnation solution was acid or basic, respectively. Then, CeCA(a) means the MgAl₂O₄ spinel doped with a Ce complex obtained from Ce(NO₃)₃ and citric acid at an acid pH. As reference, a sample of MgAl₂O₄ doped with CeO₂ from an aqueous solution of Ce(NO₃) (free of chelating agent) was also prepared. This sample was designated Cenitrate.

Characterization of samples

Point of Zero Charge: PZC value of the spinel was determined using the salt addition method.²⁴24 Mahmood, T.; Saddique, M. T.; Naeem, A.; Westerhoff, P.; Mustafa, S.; Alum, A.; Ind. Eng. Chem. Res. 2011, 50, 10017. The pH of 25 mL KNO₃ 0.1 M solutions was adjusted with KOH and HNO₃ in a pH range of 2 to 12. The pH of each solution (pH_initial) was measured by a pHmeter (Lutron PH-230 SD with a Van London glass electrode). 25 mg of powder sample were suspended in each solution under vigorous stirring of 175 rpm for 24 h in a universal stirrer (Edmund Buhler KL-2). After that, the pH of each suspension was measured (pH_end). Then, ΔpH (estimated as pH_end - pH_initial) was plotted as a function of pH_initial. The pH_initial value at ΔpH = 0 was taken as the PZC.

Chemical species in the impregnation solution: The distinct species present in the impregnation solutions were determined using Medusa software.²⁵25 Puigdomenech, I.; Medusa Software, Chemical Equilibrium diagrams 2, 2013, available at http://www.kth.se/en/che/medusa/chemeq-1.369367, accessed July 2018.
http://www.kth.se/en/che/medusa/chemeq-1... Ce³⁺, the deprotonated chelate and the ionic strength were considered.

Specific surface area: Specific surface areas of samples (S_BET) were determined by the BET method from adsorption measurement of N₂ at -196 °C, using a Micromeritics Gemini V. The samples were previously degassed at 300 °C for 16 h in a N₂ flow. Six points were recorded until P/P₀= 0.3. Values of C constant varied between 83 and 120.

Thermogravimetric analysis: The decomposition of precursors was studied using a TGA 51 Shimadzu equipment. The weight loss was recorded under an air flow (50 mL min^-1) from room temperature until 1000 °C at 10 °C min^-1.

X-ray diffraction: Diffraction patterns of samples, XRD, were obtained using a diffractometer Rigaku, D-Max III C, operated at 30 kV and 20 mA. A radiation CuKα (γ = 0.15418 nm) with a Ni filter and a horizontal goniometer were employed. Step-scans were taken over a range of 2θ from 10° to 70° in step of 3° min^-1. The data were collected every 0.05°. The crystalline phase identification was made by matching with JCPDS files. The crystallite sizes of CeO₂ were determined using the Scherrer equation for the (111) diffraction peak at 2θ = 28.6°. These calculations were estimated from patterns recorded between 2θ = 25.5° and 31.5° at 0.01° at a fixed time of 5 s, using a Si monocrystal.

Temperature programmed reduction (TPR): The redox properties of samples were examined using a conventional reduction equipment operated with a thermal conductivity detector. Before TPR experiments, the samples were previously treated under an O₂/He flow (36 mL min^-1) at 300 °C for 1 h. After cooling in an He flow until 25 °C, the samples were reduced in an H₂(5 vol.%)/N₂ flow from room temperature to 700 °C at 10 °C min^-1.

Temperature programmed desorption of CO₂ (CO₂-TPD): The basic properties of ceria doped spinel were studied by CO₂-TPD employing a conventional desorption equipment with a thermal conductivity detector. 80 mg of sample were previously reduced in an H₂(5 vol.%)/N₂ flow at 650 °C for 30 min. The adsorption was carried out in a pure CO₂ flow for 1 h. After a purge stage in He, the desorption was performed under an He flow (30 mL min^-1) from room temperature to 700 °C at 10 °C min^-1. The total integrated area of the CO₂ band was considered as a measure of total basicity. CO₂ uptake expressed as µmoles CO₂ per g_cat or µmoles CO₂ per m² were estimated after CO₂ calibration.

Scanning electron microscopy and energy dispersive X-ray spectroscopy (SEM-EDX). SEM images were obtained in a LEO 1450 VP equipped with an energy dispersive X-ray microanalyzer (EDAX Genesis 2000). A Si(Li) detector was used. The fresh samples were coated with a gold film.

RESULTS AND DISCUSSION

The diffraction pattern of Mg spinel obtained by the citrate method is shown in Figure 1. The peaks at 2θ = 19°, 31°, 37°, 45°, 56°, 59° and 65° were assigned to MgAl₂O₄ (JCPDS-21-1152). The XRD intensity ratio I₄₀₀/I₃₁₁ was 1.2. This value was higher than others in the literature (I₄₀₀/I₃₁₁= 0.65 for the pure stoichiometric spinel)²⁶26 Zhang, H.; Jia, X.; Liu, Z.; Li, Z.; Mater. Lett. 2004, 58, 1625. and it is probably associated with defects in the spinel structure induced by the preparation method. The N₂ adsorption-desorption isotherm (not shown) is type IV, characteristic of mesoporous materials with a hysteresis loop H1 type according to IUPAC classification. The specific surface area of prepared spinel was 139 m² g^-1. In the literature, values of specific surface area of 154 m² g^-1 (after a calcination at 800 °C) and 52 m² g^-1 (after a calcination at 900 °C) have been reported.²⁷27 Sanjabi, S.; Obeydavi, A.; J. Alloys Compd. 2015, 645, 535.

The spinel was doped by wet impregnation method using aqueous solutions of Ce complexes. The Ce³⁺ complexes in solution were obtained from different chelating agents and Ce(NO₃)₃. The main difference between the preparation with chelating agents and the reference sample (synthesized from an aqueous solution of Ce(NO₃)₃) is the nature of the impregnation ion, which is mainly anionic in the first case and cationic in the second one. For instance, Ce could be complexed with EDTA into the chelate [Ce(EDTA)]^-. As it was mentioned, support-complex interactions depend on many factors as the isoelectric point of the support, the pH of the aqueous solutions and the nature of the impregnation reagents. PZC of prepared MgAl₂O₄ was determined by salt addition method. The ΔpH as a function of initial pH is shown in Figure 2. The PZC for the spinel was 9.4 at room temperature which is similar to others reported in the literature.²⁸28 Ganesh, I.; Olhero, S.; Torres, P.; Ferreira, J.; J. Am. Ceram. Soc. 2009, 92, 350. This PZC value is between those of alumina and magnesium oxide and it is similar to PZC of Al₂O₃-(20%)MgO mixed oxides.²⁸28 Ganesh, I.; Olhero, S.; Torres, P.; Ferreira, J.; J. Am. Ceram. Soc. 2009, 92, 350.

The pH of impregnation solution used for preparing the ceria doped spinel was kept lower or equal to the spinel PZC to favor the absorption of the formed chelate, Table 1. Solutions with metal complex formed between Ce(NO₃)₃ and EDTA, NTA or CA were colorless except for the Ce-CA in a basic medium which was yellowish showing the complex formation.

Figure 3 shows representative curves of TG analysis corresponding to dried samples. The weight loss until 100 °C indicates desorption of water whereas those until 600 °C could be attributed to decomposition/oxidation of the metal chelates and NO₃^2- remain groups. The weight was almost constant from 600 °C. This temperature was selected as the appropriate one for the decomposition process, allowing the obtaining of supports with high surface areas with an acceptable residual carbonaceous contamination (as it was observed by FTIR, see Supplementary Material section). Besides, this temperature is in the temperature range where the ethanol steam reforming reaction is usually carried out. TGA showed weight losses of 16.8% for Cenitrate, 22.2% for CeEDTA(a) and 21.2% for CeCA(a). These values were lower than those expected considering possible structures of complex and the chelating nature. This behavior could be explained if the decomposition begins during the drying step. In fact, signals corresponding to CeO₂ with fluorite structure (2θ = 28.6°, 33°, 47° and 56°, JCPDS-34-0394) were observed in the XRD pattern of a dried sample at 100 °C for 20 h in a vacuum (without calcination), Figure 4. Similar results have been reported by Daza et al. on Ni-containing Mg-Al mixed oxides obtained from hydrotalcite precursors and doped with different loads of [Ce(EDTA)]^-.¹¹11 Daza, C. E.; Gallego, J.; Mondragón, F.; Moreno, S.; Molina, R.; Fuel 2010, 89, 592.

S_BET values corresponding to ceria doped spinel shown in Table 1 were high and did not present significant differences by changing the chelating agent. A decrease between 18% and 10% was observed after the addition of CeO₂ as a dopant. S_BET values are also not affected significantly by the pH change. Damyanova et al.²⁹29 Damyanova, S.; Perez, C. A; Schmal, M.; Bueno, J. M. C.; Appl. Catal., A 2002, 234, 271. have reported a decrease in the specific surface area around 15% for a CeO₂(12 wt.%)/Al₂O₃ sample due to the plugging of the pores with cerium oxide species.

In Figure 1, the diffraction patterns of calcined samples are shown. After the thermal decomposition in air the XRD reveal peaks corresponding to MgAl₂O₄ and CeO₂. From the analysis of CeO₂ characteristic peak at 2θ = 28.6°, moderate changes in crystallite sizes of CeO₂ could be inferred due to the use of chelating agents in the impregnation step. The $d_{{\mathit{CeO}}_2}^{\mathit{XRD}}$ varied between 5 and 6.8 nm being 25% lower for the spinel doped by Ce-citric acid complex, Table 1. The presence of amorphous particles or very small crystals lower than 4 nm undetectable by XRD cannot be ruled out.

In Figure 5, the TPR profiles are shown. All samples exhibited broad peaks of consumption in the temperature range of 450 to 670 °C, assigned to the Ce⁴⁺ surface reduction to Ce³⁺. As it was expected, the reduction profile of spinel was flat in the used temperature range in TPR. It is known that surface Ce⁴⁺ species are reduced at lower temperature than the one predicted by thermodynamic for bulk CeO₂ and its reduction is affected by the textural and morphological properties of oxide.³⁰30 Boaro, M.; Vicario, M.; de Leitenburg, C.; Dolcetti, G.; Trovarelli, A.; Catal. Today 2003, 77, 407. The maximum temperatures in TPR considered as an indirect measurement of CeO₂-spinel interaction extent are shown in Table 2. The support prepared by impregnation without chelating agent showed a T_max= 570 °C. This temperature was changed between 538- 607 °C for the other samples. The sample prepared in the presence of citric acid at a basic pH presented the highest reducibility. The reducibility and H₂ consumption did not show a clear dependence with the crystallite size, $d_{{\mathit{CeO}}_2}^{\mathit{XRD}}$. However, a connection among the species present in the impregnation solution and the ceria-spinel interaction could be found. In Table 2, the main species in solution at the corresponding preparation pH are shown. TPR profiles for CeEDTA(a) and CeEDTA(b) are similar and in both the main species is [CeEDTA]^-. When the main species are [Ce(H₂O)_x]³⁺ as Cenitrate and CeCA(a) the maximum in TPR peak is 570-579 °C. The main species in the citric acid solution at acidic pH is [Ce(H₂O)_x]³⁺ due to the dissociation of citric acid is not thermodynamically favored at low pH. Comparable results were reported in the literature.¹⁵15 Suarez Toriello, V. A.; Santolalla Vargas, C. E.; de los Reyes, J. A.; Vazques Zavala, A.; Vrinat, M.; Geantet, C.; J. Mol. Catal. A: Chem. 2015, 404-405, 36.

The maximum temperature in TPR is higher when the species are anionic indicating a stronger interaction with the spinel whereas the temperature is lower in neutral and cationic species, in agreement with the PZC of MgAl₂O₄.

The basic properties were investigated by CO₂ desorption. The profiles of CO₂-TPD illustrated in Figure 6 are qualitatively similar with a wide desorption peak in the temperature range of 25-700 °C. They suggest a heterogeneous distribution of basic sites, with predominant weak and medium-strength basic sites (surface species bicarbonate and bidentate carbonate).³¹31 Di Cosimo, J. I.; Diez, V. K.; Xu, M.; Iglesias, E.; Apesteguía, C.; J. Catal. 1998, 178, 499. A slight change in the weak basicity strength could be inferred by the shift in temperature. This change was probably induced by the presence of chelating agents during preparation, despite the precursors are almost completely decomposed in the calcination step. There are not significant changes in medium and strong basicity. The total basicity determined by integration of CO₂-TPD curves did not show substantial changes, Table 2.

In Figure 7, SEM micrographs of representative samples are shown. In all SEM images irregular particles are present. The chemical mapping carried out by EDX spectroscopy in different zones of the sample reveals a quite uniform chemical composition which indicates a good distribution of Ce species on the spinel surface regardless the chelating agent used in preparation step.

From the result analysis, it could be inferred that the use of chelating agents during the impregnation step decreased the CeO₂ crystallite sizes with slight changes in the redox and basic properties of spinel support. The decreasing of $d_{{\mathit{CeO}}_2}^{\mathit{XRD}}$ was higher for the complex Ce-citric acid being of 25% lower than the reference sample. The samples prepared from citric acid at pH= 8 showed the lowest interaction with spinel support. The use of Ce complexes in the impregnation step did not lead higher changes in the physicochemical properties, likely due to the high calcination temperature required to thermally stabilize the support. Since CeO₂ is partially formed during the drying step (Figure 4), the strategy of using the CeO₂ doped spinel in dried form could induce more significant changes in the final catalysts. This study is under investigation in our laboratory.

CONCLUSIONS

MgAl₂O₄ spinel was doped by the 5 wt.% CeO₂. Aqueous solutions of Ce³⁺ in the presence of different chelating agents (EDTA, NTA or CA) were used in the impregnation step. Ceria nanoparticles between 5 to 6.8 nm were obtained after a thermal decomposition in air at 600 °C. The use of citric acid at pH=8 led to the lowest crystallite sizes of CeO₂ being also low the interaction with the spinel. In all the samples surface CeO₂ was reduced in a temperature range of 450 to 670 °C. It was not observed a clear dependence of H₂ consumption under reduction conditions or in the degree of CeO₂-spinel interaction with the crystallite size. The use of chelating agents did not change the total basicity although a slight increase in weak base strength could be inferred.

ACKNOWLEDGMENTS

Financial supports are acknowledged to CONICET, ANPCyT and Universidad Nacional of San Luis. The authors would like to thank to Lic. Esther Fixman for her assistance in CO₂-TPD determinations.

SUPPLEMENTARY MATERIAL

IR spectroscopy spectra confirming carbon contamination in calcined samples (Figure 1S) can be found at http://quimicanova.sbq.org.br in PDF format with free access.

REFERENCES

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