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Peroxomolybdate@MOFs as effective catalysts for oxidative desulfurization of fuels: correlation between MOF structure and catalytic activity

Yan Gao ab, Carlos M. Granadeiro a, Luís Cunha-Silva b, Jianshe Zhao *b and Salete S. Balula *a
aREQUIMTE/LAQV & Department of Chemistry and Biochemistry, Faculty of Sciences, University of Porto, 4169-007 Porto, Portugal. E-mail: sbalula@fc.up.pt
bKey Laboratory of Synthetic and Natural Functional Molecule Chemistry of Ministry of Education, Shaanxi Key Laboratory of Physico-Inorganic Chemistry, College of Chemistry & Material Science, Northwest University, Xi'an, Shaanxi 710127, China. E-mail: jszhao@nwu.edu.cn

Received 5th April 2023 , Accepted 24th June 2023

First published on 26th June 2023


Abstract

The highly active peroxomolybdate, TBA3{PO4[MoO(O2)2]4}·3H2O (abbreviated as PMo4), was incorporated for the first time in various porous MOF support structures (MIL-101, MOF-808, and ZIF-8) to form heterogeneous catalysts with different structural properties. These catalysts were used to treat a multicomponent model diesel via an oxidative desulfurization process. Sulfur-free diesel could be obtained after only 2 h depending on the porous MOF structural morphology. The size of the window entrance and the dimension of the pore from the MOF support had a remarkable influence on the catalytic performance of PMo4@MOF catalysts, and thus, the conditioning of reactant diffusion. PMo4@MIL-101 presented the highest catalytic efficiency (100% after 2 h), followed by PMo4@MOF-808 (73.1% at 2 h) and PMo4@ZIF-8 (68.1% at 2 h). Furthermore, the most active catalyst, PMo4@MIL-101, showed remarkable recycle capacity and structural stability (maintaining the activity and stability for 10 catalytic cycles). Appropriate window and pore size cavities from MIL-101 support were the most suitable for organosulfur oxidation. Smaller windows and pore sizes from the other MOFs caused a decrease in catalytic efficiency. The windows and porous dimensions from MOF-based catalysts have a direct effect on catalyst performance, and these must be adjusted to reactants and active guest centers to avoid leaching and allow a fluent diffusion of reactants, mainly the ones with large molecular sizes.


1. Introduction

Fossil fuel combustion still accounts for ∼85% of the world's energy production and the goal for 2040 is to decrease this to 20%.1,2 Therefore, crude oil is and will be the principal energy source for the chemical industry, transportation, and other human activities. Sulfur compounds form one of the major impurities present in crude oil, which are responsible for acid rains that cause a series of environmental and human health problems.3 Of the various sulfur compounds present in crude oil, organosulfur species are the most important. Sulfur present in fossil fuels can be higher than 35[thin space (1/6-em)]000 ppm. Consequently, legislation has been implemented to limit sulfur concentration in commercial road and maritime fuels, whereby maximum sulfur concentration in road diesel is limited to 10 ppm;4 more recently, in marine fuels, it has been limited to 500 ppm (100 ppm in the Baltic Sea, North Sea, and the English Channel) by the International Marine Organization.5 The efficiency of the current industrial hydrodesulfurization process is limited to some liquid fuels (gasoline and diesel) and must use more severe conditions (higher temperature and hydrogen pressure) to achieve 10 ppm of sulfur content. Therefore, the desulfurization of fuels is still a hot research topic that aims to develop effective processes to treat fuels mainly containing high-molecular-weight aromatic sulfur compounds.6,7 Various examples are reported using alternative desulfurization processes, such as oxidation, adsorption, extraction, and biodegradation technologies.8–13 Among these alternative methods, oxidative desulfurization is becoming a dominant technique to remove organosulfur compounds via oxidation to prepare ultra-low sulfur fuels under moderate experimental conditions.12,14–27 In an oxidative catalytic desulfurization system, the organosulfur compounds are oxidized to sulfoxide and/or sulfones, which are easily removed by extraction using an immiscible polar solvent. Another possibility for oxidative desulfurization is based on performing simultaneous extraction and oxidation catalytic processes using a biphasic system comprising fuel and an immiscible polar solvent (extractive/catalytic oxidative desulfurization system, ECODS). In this case, this polar solvent presents a double functionality of receiving the organosulfur compounds from the fuel phase and promoting a suitable medium for efficient oxidative catalysis.28–32 The strategic combination of a highly efficient catalyst and a sustainable extraction medium is needed to achieve deep desulfurization in a short period of time. Hydrogen peroxide has been demonstrated to be an effective oxidant for oxidative desulfurization processes that are catalyzed by polyoxometalates and are considered to produce no harmful by-products.16,18,22–25,29,33–40 POMs have proved to be an extraordinary class of catalysts with exceptional reactivity for ODS of fuels that use H2O2 as an oxidant.18,22–25,27,41–45 POMs are a class of highly ordered well-defined nanometer-sized inorganic cluster ionic compounds, normally presenting high solubility in various reaction media dependent on the nature of the counter-cation. Therefore, various strategic paths have been investigated to heterogenize POM units on solid supports, which should promote their stability and maintain their homogeneous catalytic activity. Amongst the several solid supports available, porous metal–organic frameworks (MOFs) feature important advantages over traditional inorganic and organic solid supports, such as ordered pore structure and suitable pore size that promotes uniform incorporation of POM units.46–50 The regular distribution of POMs within the MOF cavities can be enforced by easy pre-structural functionalization of the MOF structure. This procedure avoids POMs agglomeration and deactivation.49,51–53 In general, two main experimental methodologies have been applied in the preparation of the POM@MOF composite materials: the impregnation method and the one-pot approach, frequently named “bottle-around-the-ship”. Various examples are reported in the literature presenting POM@MOF composites as heterogeneous catalysts for oxidative desulfurization systems.2,54–62 The mechanism involved in oxidative desulfurization processes catalyzed by POMs is attributed to the generation of peroxopolyoxometalates (POOMs) as the active catalytic centers, where POOMs are formed by the interaction of the POM precursor and the H2O2 oxidant.2,63–66 However, active POOMs lack good recyclability and reusability due to their homogeneous nature which promotes high solubility in organic solvents. Therefore, it is essential to investigate procedures for the effective heterogenization of active POOMs; however, the work reported in this area is scarce.2,40 Our research group recently reported the immobilization of a peroxopolyoxotungstate, (nBu4N)3{PO4[WO(O2)2]4} (PW4) on the surface of a functionalized mesoporous SBA-15 support40 and also its encapsulation in a MOF structure with large pore cavities (MIL-101).2 Porous MOFs have the advantage of acting as nanoreactors for liquid phase catalytic systems; however, the size of their pore window and pore cavity must be adjusted to the catalytic active center to avoid its leaching and deactivation during the recycling processes.

Following our recent report on the encapsulation of a peroxopolyoxotungstate in the MOF, MIL-101, with large pore cavities,2 the highly active peroxophosphomolybdate with Venturello structure, (nBu4N)3{PO4[MoO(O2)2]4} (hereafter abbreviated as PMo4),17 was incorporated into three distinct MOFs (ZIF-8, MOF-808, and MIL-101) with diverse cavities/window dimensions. These composites were used as catalysts for the oxidative desulfurization of a multi-component diesel. The correlations between activity and structural features of the porous MOF supports were studied and discussed. In fact, the application of peroxomolybdate-based heterogeneous catalysts for the oxidative desulfurization of model fuels is herein reported for the first time. Interestingly, despite the structural similarity of both PMo4 and PW4, the peroxotungstate revealed the superior homogeneous catalytic performance in the oxidative desulfurization of model fuels.64 However, the heterogeneous catalyst based on the peroxopolyoxomolybdate, PMo4@MIL-101, investigated herein presented enhanced performance than the analogous PW4@MIL-101 that had been previously reported. Furthermore, higher structural stability and recycling ability were found in this work using the heterogeneous PMo4@MIL-101.2

2. Experimental section

2.1. Materials and methods

The reagents applied in the synthesis of the materials and used in desulfurization studies were utilized as received without further purification: phosphomolybdic acid hydrate (H3PMo12O40·nH2O, PMo12, 99.9%, Sigma-Aldrich), tetrabutylammonium chloride (TBACl, 98%, Sigma-Aldrich), hydrogen peroxide (H2O2, 30% w/w aq. Sigma-Aldrich), zirconium tetrachloride (ZrCl4, 99.5%, Aldrich), benzene-1,3,5-tricarboxylic acid (trimesic acid, C9H6O6 H3btc, 98%, Aldrich), zinc nitrate hexahydrate (Zn(NO)3·6H2O, 99.0%, Sigma-Aldrich), 2-methylimidazole (C4H6N2, 99%, Sigma-Aldrich), chromium(III) nitrate nonahydrate (Cr(NO)3·9H2O, 99%, Aldrich), benzene-1,4-dicarboxylic acid (terephthalic acid, C8H6O4, H2bdc, 98%, Aldrich), hydrofluoric acid (HF, 40–45%, Aldrich), acetic acid (CH3COOH, 99%, Sigma-Aldrich), 1-benzothiophene (1-BT, Fluka), dibenzothiophene (DBT, Aldrich); 4-methyldibenzothiophene (4-MDBT, Aldrich), 4,6-dimethyldibenzothiophene (4,6-DMDBT, Alfa Aesar), decane (98%), tetradecane (99%), 1-butyl-3-methylimidazolium hexafluorophosphate ([BMIM]PF6, Aldrich, 99%), polyethylene glycol (PEG, Sigma-Aldrich, BioUltra 200), and acetonitrile (MeCN, Sigma-Aldrich 99%).

Elemental analysis for C, H, and N was performed on a Leco CHNS-932 instrument to confirm the structural formula of PMo4. The content of metal elements, Mo and Cr, was determined by ICP-OES on a Perkin-Elmer Optima 4300 DV instrument. FT-IR spectra were recorded on a Jasco 460 Plus spectrometer with 64 scans in the region of 1800–400 cm−1. Powder XRD patterns were recorded in the 2–50° range on an X'Pert MPD Philips diffractometer with a scanning speed of 0.1° min−1 at 45 kV and 40 mA. Scanning electron microscopy (SEM) images were acquired on a JEOL JSM 6301F microscope using a 15 kV acceleration voltage equipped with an Oxford INCA Energy 350 energy-dispersive X-ray spectrometer at “Centro de Materiais da Universidade do Porto” (CEMUP, Porto, Portugal). Thermogravimetric analysis was carried out in a nitrogen atmosphere on a STA7200RV equipment at a heating rate of 5 °C min−1. These analyses were performed to test the stability of the materials from 30 to 1000 °C under a nitrogen atmosphere with a temperature increase at a rate of 5 °C min−1. N2 adsorption–desorption isotherms were collected at −196 °C with a gas porosimeter Micromeritics ASAP 2010. Pre-outgassing of the analyzed samples was carried out at 150 °C for 2 h. The concentration of sulfur-containing substances was monitored by GC-FID analysis on Bruker 430-GC-FID chromatograph equipped with fused silica Supel-Co capillary columns SPB-5.

2.2. Catalysts syntheses

2.2.1. Peroxophosphomolybdate. TBA3{PO4[MoO(O2)2]4}·3H2O (abbreviated as PMo4) was prepared following published procedures with minor changes.2 Briefly, aqueous H2O2 30% (10 mL, 98 mmol) was slowly dropped into an aqueous solution (10 mL) containing H3PMo12O40·nH2O (0.91 g, 0.50 mmol) under magnetic stirring for 60 min. Then, a solution of TBACl (0.45 g, 1.60 mmol) in deionized water (3 mL) was added dropwise into the mixture with vigorous stirring, and a yellow precipitate was generated during this process. The precipitate was collected by vacuum filtration, washed with deionized water, and dried at room temperature. The successful preparation of PMo4 was confirmed by 31P NMR, FT-IR, and elemental analysis. 31P NMR (161.9 MHz, CD3CN, 25 °C) presented δ = 8.23 ppm. FT-IR (cm−1) featured peaks at 2960 (w, νasym(CH3)), 2874 (w, νasym(CH2)), 1485 (m, ν(C–N)), 1070 (vs, ν(PO4)), 1039 (s, ν(PO4)), 961 (vs, ν(Mo[double bond, length as m-dash]O)), 867 (vs, ν(O–O)), 588 (s, νasym[Mo(O2)]), and 543 (s, νsym[Mo(O2)]). Elemental analysis (%) of TBA3{PO4[MoO(O2)2]4}·3H2O (1580.25) calculated C = 36.28, H = 6.93, and N = 2.61 and found: C = 36.48, H = 7.27, and N = 2.66.
2.2.2. MOFs as support materials.
ZIF-8. The porous ZIF-8 was synthesized by a method similar to that reported in the literature.67 2-methylimidazole (0.82 g, 0.01 mol) was dissolved in MeOH (25 mL) and then injected into a solution of Zn(NO3)2·6H2O (0.74 g, 2.5 mmol) in MeOH (25 mL) with magnetic stirring at room temperature. After stirring for 24 h, a white product was recovered by centrifugation and washed thrice with MeOH. Selected FT-IR (cm−1) was performed for: 1301(w), 1179(w), 1144(s), 994(w), 758(s), 692(w), 680(w), and 419(s).
MOF-808. Porous MOF-808 was prepared by a solvothermal method similar to that already described.68 A mixture of ZrCl4 (0.93 g, 4 mmol), H3btc (0.28 g, 1.24 mmol), acetic acid (24 mL, 0.42 mol), and DMF (40 mL, 0.52 mol) was treated by ultrasound to obtain a transparent solution, which was transferred to a Teflon-lined autoclave and heated at 130 °C for 48 h in an electric oven. A white solid was recovered by centrifugation and further washed with DMF and acetone (three washes). Selected FT-IR (cm−1) was performed for: 1656(w), 1620(w), 1570(w), 1445(s), 1379(s), 1078(w), 1047(w), 755(w), 719(w), 651(w), and 448(w).
MIL-101. Porous MIL-101 was synthesized by a reported solvothermal method69 as follows: Cr(NO3)3·9H2O (0.40 g, 1.00 mmol), H2bdc (0.166 g, 1.00 mmol), and hydrofluoric acid (100 μL) were added into H2O (10 mL) and stirred for 10 min at room temperature; the mixture was then transferred to a Teflon reactor and heated at 493 K for 9 h using an electric oven. After the reaction finished, the bottle-green product was isolated by filtration, washed with DMF and MeOH, and dried appropriately. Selected FT-IR (cm−1) was performed for: 1667(w), 1628(w), 1545(w), 1507(w), 1399(s), 1084(w), 1018(w), 972(w), 884(w), 835(w), 745(m), 658(w), and 583(m).
2.2.3. Composite PMo4@MOFs..
PMo4@ZIF-8. The incorporation of PMo4 in ZIF-8 was carried out with a procedure identical to that for ZIF-8, except a solution of PMo4 (77.3 mg, 0.04 mmol) in DMF (3 mL) was poured into the mixture during the synthesis of ZIF-8. After the reaction, the white solid was separated by centrifugation and washed with DMF and MeOH (thrice). The loading amount of PMo4 determined by ICP-OES analysis was 0.13 mmol g−1. Selected FT-IR (cm−1) was performed for: 1301(w), 1179(w), 1144(s), 994(w), 758(s), 692(w), 680(w), and 419(s).
PMo4@MOF-808. The encapsulation of PMo4 in MOF-808 was performed with a procedure similar to that for MOF-808, which was just the addition of PMo4 (0.12 mmol) during the synthetic process. The loading quantity of PMo4 evaluated by ICP-MS analysis was 0.17 mmol g−1. FT-IR (cm−1) analysis: 1656(w), 1620(w), 1570(w), 1445(s), 1379(s), 758(w), 719(w), 651(w), and 448(w).
PMo4@MIL-101. The insertion of PMo4 in the cavities of porous MIL-101 was executed via an impregnation method: PMo4 (0.27 g, 0.14 mmol) was dissolved in MeCN (10 mL). Porous MIL-101 (0.44 g) that had been previously dried and activated under vacuum for 12 h at 60 °C, was transferred into the solution and stirred at room temperature (72 hours). The solid material (PMo4@MIL-101) was recovered by filtration, washed with MeCN and EtOH three times, and dried. The loading amount of PMo4 calculated by ICP-MS analysis was 0.38 mmol g−1. FT-IR (cm−1) was performed: 1667(w), 1628(s), 1545(w), 1507(w), 1399(s), 1084(w), 1018(w), 972(w), 884(w), 835(w), 745(m), 658(w), and 583(m).

2.3. Desulfurization studies

A multicomponent model diesel with equal concentrations (with a total sulfur concentration of 2000 ppm) of 1-BT, DBT, 4-MDBT, and 4,6-DMDBT was prepared in decane to simulate model diesel. In a typical desulfurization run, two liquid-phases with equal volumes of model diesel and extraction solvent (MeCN, [BMIM]PF6, or TBACl/PEG) were adopted. Desulfurization was performed by the following procedure: a homogeneous catalyst, such as PMo4 (5 μmol), or a heterogeneous catalyst, such as PMo4@MOF (containing an equivalent amount of 5 μmol of PMo4), model diesel (0.75 mL, containing a total of 31 μmol of sulfur), and extraction solvent (0.75 mL) were added into a 5 mL closed borosilicate reactor with magnetic stirring; the mixture was immersed in an oil bath at 70 °C. After 10 min, H2O2 (0.26 mmol) was added to the mixture as the oxidant to initiate the oxidative catalytic desulfurization step. The model diesel was then withdrawn from the upper phase (20 μL) and analyzed with the addition of tetradecane as the standard by gas chromatography to quantify the total sulfur content. Finally, the desulfurization efficiency (%) was calculated according to the following formula.
image file: d3cy00467h-t1.tif
The error associated with at least three reproduced experiments was 3% of the total desulfurization. Reusability of homogeneous and heterogeneous catalytic systems was carried out for 10 consecutive desulfurization cycles under optimized conditions: PMo4 (7.5 μmol) or PMo4@MIL-101 (an equivalent amount containing 7.5 μmol of PMo4), model diesel (0.75 mL), [BMIM]PF6 (0.75 mL), and H2O2 (0.78 mmol). After each cycle, desulfurized diesel was removed and an equal amount of fresh untreated model diesel and oxidant were added to initiate the next cycle. The recyclability of heterogeneous catalysts was also evaluated by separating the solid catalyst after each cycle. The catalyst was washed with MeCN, dried, and then poured into a new reactor with fresh untreated diesel and [BMIM]PF6 to start a new cycle in the presence of H2O2.

3. Results and discussion

3.1. Structural characterization of materials

The encapsulation of PMo4 in the different MOFs was attained via adequate approaches according to the structural features of each MOF, specifically the pore and aperture (window) sizes in each porous material (Scheme 1). The main challenge was that the cavity should accommodate the soluble PMo4 to maintain high catalytic activity, while avoiding their leaching when used as heterogeneous catalysts. PMo4 can be easily encapsulated in MIL-101 with a larger window size via the facile impregnation method. However, due to the small window size of MOF-808 and ZIF-8, the PMo4 needs to be encapsulated by a one-pot procedure (Scheme 2).
image file: d3cy00467h-s1.tif
Scheme 1 The structural information from selected MOFs.

image file: d3cy00467h-s2.tif
Scheme 2 Representation of the two distinct experimental procedures applied for the preparation of the composite materials: one-pot method (used for the preparation of PMo4@MOF-808, top, and PMo4@ZIF-8) and the impregnation method (used to prepare PMo4@MIL-101, bottom).

The prepared composites, PMo4@ZIF-8, PMo4@MOF-808, and PMo4@MIL-101, were characterized by a myriad of complementary methods, where they were always compared with the respective pristine MOF using several methods: inductively coupled plasma-OES spectrometer (ICP-OES), Fourier transform-infrared spectroscopy (FT-IR), powder X-ray diffraction (PXRD), scanning electron microscopy (SEM), energy dispersive X-ray spectroscopy (EDX), thermogravimetric analysis (TGA), and N2 adsorption–desorption studies. Functional groups and relevant structural information on the PMo4, pristine MOFs, and the different composites were confirmed by FT-IR (Fig. 1). The results showed that practically all the vibrational bands of the pristine MOFs were still present in the spectra of the PMo4@MOFs composites, suggesting that the MOF structure is preserved after the incorporation procedure. However, the main characteristic bands assigned to PMo4 were located at 871, 962, 1036, and 1067 cm−1 and were not visible in the spectra of PMo4@MOFs, most likely due to the small relative content of PMo4 when compared with the amount of MOF. Nevertheless, ICP-OES analysis confirmed the presence of the peroxophosphomolybdate in all composites, leading to a PMo4 loading of 0.13, 0.17, and 0.38 mmol g−1 for PMo4@ZIF-8, PMo4@MOF-808, and PMo4@MIL-101(Cr), respectively. The phase purity of robust MOFs and their respective PMo4-containing composites was analyzed by powder XRD analysis (Fig. 1). The XRD patterns of pure MOFs were consistent with the simulated and experimental patterns that have been reported in the literature.70–72 Moreover, the XRD patterns of composites PMo4@MOFs were similar to the corresponding isolated support material and no additional peaks were found. These results confirm that the structures of supporting MOFs were maintained after introducing the PMo4 guest molecule and that the PMo4 active center was uniformly dispersed within the porous MOFs.


image file: d3cy00467h-f1.tif
Fig. 1 FT-IR spectra showed in the wavenumber range 1900–400 cm−1 (left-hand side) and powder XRD patterns showed between 2 and 40° (right-hand side) from PMo4, pristine MOFs, and PMo4@MOFs composites.

The SEM image of PMo4 showed that the particles of this peroxophosphomolybdate presented an irregular lamellar morphology (Fig. 2). Comparing SEM images of the pristine ZIF-8 and its composite demonstrated that the dodecahedral crystal structure of ZIF-8 was preserved well after encapsulation of the guest PMo4. In addition, the composites, PMo4@MOF-808 and PMo4@MIL-101, also maintained the typical octahedral shape as the original support materials. The similar morphology before and after the incorporation of PMo4, combined with XRD results, indicated that the crystalline structure of selected MOFs was stable and was not destroyed during the incorporation process. In addition, the EDX spectra (Fig. 2) also showed the presence of Mo element arising from PMo4, which further confirmed that the PMo4 was embedded in the MOFs framework.


image file: d3cy00467h-f2.tif
Fig. 2 SEM images of PMo4, the pristine MOFs (ZIF-8, MOF-808, and MIL-101), and the composites (PMo4@ZIF-8, PMo4@MOF-808, and PMo4@MIL-101) overlaid by the corresponding EDX spectra.

The thermal stability of all materials was investigated by TG measurements (Fig. 3). The TG curve of pristine PMo4 showed that three crystal waters were lost before 190 °C. Afterward, the decomposition of the tetrabutylammonium cation and the anion of PMo4 occurred from 190 to 412 °C. The total mass loss was 49.6%, and it can be inferred that the final products were MoO3 and P2O5. The trends of the variations in the catalyst mass of MOFs and the corresponding PMo4-containing composites were similar, and all prepared composites were stable at the temperature of the desulfurization test (70 °C).


image file: d3cy00467h-f3.tif
Fig. 3 TGA curves for PMo4 (top left), ZIF-8 and PMo4@ZIF-8 (top right), MOF-808 and PMo4@MOF-808 (bottom left), MIL-101(Cr) and PMo4@MIL-101(Cr) (bottom right).

The textural properties, including specific surface area, pore size, and pore volume, were obtained through the Brunauer–Emmett–Teller (BET) method (Fig. 4 and Table 1). The N2 adsorption isotherms of the isolated MOFs were in good agreement with previously reported data, with the results exhibiting type I isotherms for ZIF-8 and MOF-808, and type I with minor type IV features for MIL-101(Cr).73–75 The PMo4@MOFs composites maintained the shape of the adsorption isotherms of the initial MOF support. The PMo4@MIL-101(Cr), prepared by the impregnation method, and the PMo4@ZIF-8 and PMo4@MOF-808, prepared by the in situ method, showed a smaller specific surface area owing to the occupation of PMo4 in the respective porous channels or cavities.


image file: d3cy00467h-f4.tif
Fig. 4 Nitrogen adsorption–desorption isotherms at −196 °C for MOFs and the corresponding PMo4@MOFs composites.
Table 1 The specific surface area of pristine MOFs and corresponding PMo4@MOFs
Sample Specific surface area (m2 g−1)
ZIF-8 1242
PMo4@ZIF-8 846
MOF-808 1375
PMo4@MOF-808 885
MIL-101 4861
PMo4@MIL-101 2479


3.2. Desulfurization studies

The performance of the desulfurization systems was evaluated using a multicomponent model diesel composed by four refractory organosulfur compounds (1-BT, DBT, 4-MDBT, and 4,6-DMDBT), combining extraction and catalytic oxidative desulfurization steps (ECODS). The ECODS experiments were performed using biphasic liquid–liquid immiscible phases with equal volumes of the model diesel and the extraction solvent. The homogeneous PMo4 and heterogeneous PMo4@MOFs catalysts were tested using H2O2 as an oxidant at 70 °C (Scheme 3). The influence of using different extraction solvents (MeCN; the ionic liquid, i.e., [BMIM]PF6; and the deep eutectic solvent, i.e., TBACl/PEG) was investigated. The ECODS process consisted of two steps: extraction of sulfur compounds from diesel to the extraction phase and subsequent catalytic oxidation in the extraction phase. Initially, biphasic model diesel and extraction solvent were thoroughly stirred for 10 min to extract part of the sulfur compounds from the diesel phase to the polar extraction solvent phase. After this time, the extraction of the sulfur compounds reached an equilibrium, and the oxidative catalytic step was initiated by the addition of aqueous H2O2 (0.26 mmol) as the oxidant. When the sulfur compounds were oxidized, more sulfur components were transferred from diesel to the extraction phase (Scheme 3).
image file: d3cy00467h-s3.tif
Scheme 3 Illustration of the ECODS processes using heterogeneous PMo4@MOFs catalysts.
3.2.1. Optimization of the ECODS process. The influence of various parameters in the ECODS process was studied to improve total desulfurization efficiency. These include the nature of the extraction solvent, amount of catalyst, and oxidizing H2O2. This optimization study was performed at 70 °C, using PMo4 as a homogeneous catalyst. The reaction temperature was previously optimized using the peroxomolybdate/H2O2 ECODS system.38

To investigate the influence of different extraction solvents on the oxidative catalytic performance and sulfur extraction efficiency, acetonitrile, the ionic liquid, i.e., [BMIM]PF6, and the deep eutectic liquid, i.e., TBACl/PEG, were used and the results are displayed in Fig. 5a. From the results obtained using the homogeneous catalyst, PMo4, it could be verified that all three solvents resulted in a similar initial extraction obtained after 10 min, which indicated a similar extractive desulfurization efficiency (around 50%). However, distinct oxidative catalytic desulfurization was achieved after the first 10 min, where the highest desulfurization efficiency was found using the ionic liquid, [BMIM]PF6, and TBACl/PEG (66.8% after 2 h). These last extraction solvents presented similar desulfurization profiles. Using acetonitrile, the desulfurization practically stopped after initial extraction only, as only 2.4% of oxidative desulfurization resulted during the catalytic step after 2 h. This means that this solvent did not promote the catalytic activity of the PMo4 catalyst. These results are consistent with the results reported in our previous work.64 To further verify the superiority of the two-phase liquid system, a solvent-free contrast experiment was conducted under the same conditions as previously described. In this case, the desulfurization resulted only from the catalytic oxidation of sulfur compounds in the model diesel phase, which were then easily removed from the less polar phase (using, for example, acetonitrile). Considering the catalytic step alone, the system was able to remove ∼38% of sulfur from model diesel after 2 h of reaction. As previously reported by our group, the catalytic activity of these types of hybrid POMs under solvent-free conditions is strongly influenced by the type of cation.76


image file: d3cy00467h-f5.tif
Fig. 5 Desulfurization profile of a multicomponent model diesel (2000 ppm of S) catalyzed by the homogeneous PMo4 (5 μmol) and in the presence of different extraction solvents (0.75 mL) using 0.26 mmol H2O2 at 70 °C (a); the effect of the amount of H2O2 on oxidative desulfurization in the presence of [BMIM]PF6 (0.75 mL) using 5 μmol of PMo4 at 70 °C (b); the effect of the amount of PMo4 on oxidative desulfurization in the presence of [BMIM]PF6 (0.75 mL) using 0.78 mmol of H2O2 at 70 °C (c); and the desulfurization efficiency of each sulfur compound in the presence of [BMIM]PF6 (0.75 mL) using 0.78 mmol of H2O2 and 7.5 μmol of PMo4 at 70 °C (d).

The influence of the amount of oxidant on the desulfurization efficiency was addressed using [BMIM]PF6 as an extraction solvent (Fig. 5b). The results showed a significant positive effect on the desulfurization performance with increasing H2O2 amount. For an H2O2 dosage of 0.78 mmol, the total desulfurization rapidly increased to a maximum of 98.9% during the first hour of the reaction. However, with 1.04 mmol of H2O2, the efficiency was similar to that recorded with 0.78 mmol of H2O2. This result must be related to the introduction of an excess of aqueous solution (since the oxidant is 30% H2O2 in the aqueous phase) into the system that could have hindered the sulfur transfer from the model diesel to the extraction phase. Therefore, the amount of H2O2 should be reduced as much as possible under the premise of high efficiency and cost-effectiveness.

The Venturello peroxomolybdate contains active oxygen atoms that are capable of transferring oxygen to sulfur compounds. However, in the next step, the peroxo structure must be re-generated by the interaction of H2O2 oxidant via hydroxyl radicals formation, making the amount of H2O2 an important parameter for catalyst efficiency as suggested previously in the literature on the analogous peroxotungstate PW4.64,77

The effect of PMo4 amount was also studied to perform the desulfurization of model diesel using the optimized amount of H2O2 (0.78 mmol) and [BMIM]PF6 solvent. As shown in Fig. 5c, with the increase in PMo4 amount, the catalytic activity (after the initial 10 min) sharply increased up to the highest value and then remained constant. Practically complete desulfurization was achieved (99.4%) after the first hour using 7.5 μmol of PMo4.

Fig. 5d presents the individual removal efficiency of each organosulfur compound catalyzed by a homogeneous PMo4 catalyst under the optimized reaction parameters (0.78 mmol of H2O2, 7.5 μmol of PMo4, and [BMIM]PF6 as extraction solvent). During the initial extraction stage, the extraction capacity of the four sulfur components followed the order: 1-BT > DBT > 4-MDBT > 4,6-DMDBT, which is mainly correlated to the molecular size and the sulfur atom electronic density as previously described.30,78–80 Both the electron density and steric hindrance of sulfur atoms affect the efficiency of sulfur oxidation. The lower electron density of sulfur in 1-BT (5.739) results in the lowest activity for its oxidation. DBT, 4-MDBT, and 4,6-DMDBT possess similar electron densities around the sulfur atom, namely 5.758, 5.759, and 5.760, respectively, resulting in similar final desulfurization efficiency.80 Nevertheless, the steric hindrance caused by the methyl substituents in 4-MDBT and 4,6-DMDBT makes the oxidation of sulfur more difficult than in DBT.80

3.2.2. Stability of the PMo4/[BMIM]PF6 system. Due to the high solubility of the Venturello PMo4 catalyst in the [BMIM]PF6 extraction solvent, it cannot be removed and isolated from the ECODS system, but its stability was investigated by reusing the PMo4/[BMIM]PF6 extraction phase for 10 consecutive desulfurization cycles. Therefore, the desulfurized model diesel at the end of each cycle was separated from the extraction phase containing the soluble active catalytic center. In the next step, a fresh untreated model diesel (0.75 mL) and the oxidant H2O2 (0.78 mmol) were added to start a new ECODS cycle (Fig. 6). The results show that the sulfur removal performance of the PMo4/[BMIM]PF6 system was nearly constant for 10 ECODS cycles (always higher than 91%). The remarkable performance of the system allowed the removal of 94.2% of the sulfur from model diesel even at the end of the 10th consecutive cycle with the same initial portion of extraction solvent. These results indicate that no loss of homogeneous PMo4 occurred during the reuse process, and the visual accumulation of oxidized products in the extraction phase did not decrease the desulfurization efficiency of the PMo4/[BMIM]PF6 ECODS system.
image file: d3cy00467h-f6.tif
Fig. 6 Reusability of the homogeneous PMo4 (7.5 μmol) catalyst using 0.75 mL of [BMIM]PF6 extraction solvent, 0.78 mmol of H2O2, and 7.5 μmol of PMo4 at 70 °C. The results were obtained at 2 h.
3.2.3. Desulfurization using heterogeneous PMo4@MOFs. The heterogeneous catalysts were prepared by a strategic encapsulation of the active PMo4 in three different porous MOF frameworks (MIL-101, MOF-808, and ZIF-8). These heterogeneous catalysts were tested to desulfurize the multicomponent model diesel under the previously optimized conditions. The influence of the nature of the support on the catalytic performance of the active center was evaluated. Catalytic performance and the recycling capacity of the composite PMo4@MOF must be directly correlated to its structural properties, i.e., to the nature of the ligands and the metallic centers, as well as its cage and window sizes. Fig. 7a displays the desulfurization results obtained using the various heterogeneous PMo4@MOFs catalysts. After 2 h, the desulfurization obtained using PMo4@MIL-101, PMo4@MOF-808, and PMo4@ZIF-8 were 99.2; 73.1, and 68.1%, respectively. The most efficient catalyst was the one that presented the highest cage cavity and window entrance sizes. The window size of PMo4@MIL-101 (ca. 12–16 Å2) was larger than the molecular size of any of the sulfur substrates, which could help facilitate the diffusion of the reactants into the MOF cages, accelerating the reaction and leading to higher efficiency. The narrow window of ZIF-8 (ca. 3.4 × 3.4 Å2) might constrain access of the sulfur substrates into the MOF cavities, leading to the lowest activity. Interestingly, the overall desulfurization ability of the four sulfur substrates during the process catalyzed by PMo4@MIL-101 still followed the same trend as that described previously for the homogeneous PMo4 system: DBT > 4-MDBT > 4,6-DMDBT > BT. In contrast, the removal ability of the sulfur compounds for the PMo4@MOF-808 and PMo4@ZIF-8 systems followed the order: DBT > BT > 4-MDBT > 4,6-DMDBT (Fig. 7b and c), revealing a clear relationship between the window size of the porous framework and the molecular size of the sulfur substrates. Indeed, the narrower window sizes limit the diffusion of the larger 4-MDBT and 4,6-DMDBT molecules, while the small-sized 1-BT compounds can still be diffused into the porous cavities. Moreover, in the case of PMo4@ZIF-8, the extremely narrow windows of ZIF-8 may also hinder the diffusion of DBT as seen by its considerably lower desulfurization percentage (72% after 2 h, Fig. 7b). Therefore, a direct relationship between the sulfur molecule size and the cavity entrance size was found here, which may indicate that the active catalytic center is accessible only in the cages of MOF frameworks.
image file: d3cy00467h-f7.tif
Fig. 7 Desulfurization profile of the multicomponent model diesel (2000 ppm of S) catalyzed by PMo4@MOFs, containing 7.5 μmol PMo4 with 0.75 mL of [BMIM]PF6 as the extraction solvent and 0.78 mmol H2O2 at 70 °C (a). Desulfurization profile of each sulfur compound present in the model diesel catalyzed by PMo4@ZIF-8 (b), PMo4@MOF-808 (c), and PMo4@MIL-101 (d).

The high catalytic efficiency of the PMo4@MIL-101 heterogeneous catalyst motivated recycling studies on it. The catalyst was evaluated for 10 consecutive cycles using [BMIM]PF6 as extraction solvent under optimized conditions (Fig. 8). At the end of each ECODS cycle, the solid catalyst was recovered by centrifugation, washed with MeCN, and dried. It was then used in the next cycle, while maintaining the experimental conditions. Furthermore, the PMo4@MIL-101/[BMIM]PF6 system was reused and, in this case, only the desulfurized model diesel was removed from the system at the end of each cycle. Afterward, new portions of fresh untreated model diesel and oxidant were added to the remaining [BMIM]PF6 phase containing the solid catalyst to start the next ECODS cycle. As depicted in Fig. 8, this PMo4@MIL-101 composite showed remarkable stability and high recyclability during the 10 consecutive catalytic cycles without apparent reduction in its desulfurization performance. The results of the reusability studies show a reduction in the desulfurization ability after the 7th cycle. This is probably due to the continuous accumulation of oxidized products (precipitated sulfones) in the extraction layer, making the extraction of raw sulfides increasingly difficult. However, it is noteworthy that the reuse of the PMo4@MIL-101-catalyzed system could still remove 99.3% of the sulfur at the end of the 6th cycle, especially considering the continuous reuse of the initial volume of extraction solvent.


image file: d3cy00467h-f8.tif
Fig. 8 Recyclability and reusability of ECODS system using the PMo4@MIL-101 catalyst under the optimized conditions (catalyst containing 7.5 μmol of PMo4, 0.75 mL of extraction solvent [BMIM]PF6, and 0.78 mmol of H2O2 at 70 °C). Results were obtained after 2 h.
3.2.4. Comparison with other reported catalysts. Reports on the use of immobilized peroxopolyoxometalates as heterogeneous catalysts for desulfurization processes are scarce and absent in the case of peroxopolyoxomolybdate. Few examples can be found in the literature for the immobilization of the peroxopolyoxotungstate compound, {PO4[WO(O2)2]4}3− (PW4), on the surface of a functionalized mesoporous SBA-15 support40 and also its encapsulation in a MOF structure with larger pore cavities, such as MIL-101(Cr),80,81 and smaller cavities, such as UiO-66.81 Complete desulfurization of multicomponent sulfur model fuel has been observed using these peroxotungstate-based composites (Table 2). The first work was published in 2019 by Julião et al., when PW4 was immobilized on a propyltrimethylammonium (TMA)-functionalized SBA-15.40 Using this PW4@TMA-SBA-15 catalyst, complete desulfurization was achieved after 2 h using acetonitrile as the extraction solvent. Faster complete desulfurization of similar multi-component model fuels was achieved using porous metal–organic frameworks as the support material for the active center, PW4.2,82 Three different works have reported the use of [BMIM]PF6 ionic liquid as extraction solvent, and complete desulfurization was achieved after approximately 1 h. In this work, peroxomolybdate was used instead of the reported peroxotungstate. In this case, similar desulfurization efficiency was achieved using MIL-101 as the support material; however, in this work a simple procedure was followed to prepare PMo4@MIL-101-based solid catalyst, obtaining even a higher reutilization and recycling capacity than PW4@MIL-101 in consecutive reaction cycles.81
Table 2 Comparison of catalytic efficiency of heterogeneous peroxopolyoxometalate catalysts for desulfurization of multi-component model fuels (containing 1-BT, DBT, 4-MDBT, and 4,6-DMDBT) at 70 °C
Catalyst Time (h) Solvent Efficiency (%) Ref.
PW4@TMA-SBA-15 2 MeCN 100 40
PW4@MIL-101 0.7 [BMIM]PF6 99 2
PW4@Fe2O3/MIL-101 1 [BMIM]PF6 99 77
PW4@UiO-66-NH2 1 [BMIM]PF6 99 82
PMo4@MIL-101 1 [BMIM]PF6 97 This work
PMo4@MOF-808 1 [BMIM]PF6 69 This work
PMo4@ZIF-8 1 [BMIM]PF6 63 This work


3.3. Catalyst stability

The recovered PMo4@MIL-101 catalyst after being used for 10 consecutive ECODS cycles was characterized by various techniques. The FT-IR spectra and powder XRD patterns of PMo4@MIL-101 after recycling and reusing displayed profiles similar to the ones of fresh PMo4@MIL-101, suggesting that the structure of the composite was preserved during the continuous 10 catalytic cycles (Fig. 9a and b). Nonetheless, some additional FT-IR bands could be observed after catalytic use, mainly for reused PMo4@MIL-101, in the 1300–1000 and 550–450 cm−1 ranges. The morphology of recycled and reused catalysts retained the typical octahedral shape of the original material with no evidence of degradation having occurred (Fig. 9c and d). Small heteromorphic particles were detected in the reused catalyst, which correspond to some precipitated sulfones that remained adsorbed on the surface of the catalyst even after washing, as has been reported previously for different catalytic materials used in oxidative desulfurization.80 The previously described additional bands in the FT-IR spectrum of reused PMo4@MIL-101 can also be assigned to the presence of such adsorbed oxidized sulfides in the catalyst. From all of the above observations, the characterization data after catalytic use revealed that the PMo4@MIL-101 composite shows outstanding stability during the high-efficiency ECODS process.
image file: d3cy00467h-f9.tif
Fig. 9 Characterization data obtained for fresh, recycled, and reused PMo4@MIL-101 heterogeneous catalysts: FT-IR spectra (a), powder XRD patterns (b), and SEM images (c and d).

4. Conclusions

The active TBA3{PO4[MoO(O2)2]4} (PMo4) compound was successfully used in the desulfurization of a multicomponent model diesel and its homogeneous and heterogeneous performance was compared. The heterogenization of PMo4 was performed by its immobilization in different MOF supports. These presented distinct windows and cage cavity sizes (PMo4@MIL-101, PMo4@MOF-808, and PMo4@ZIF-8). Effective incorporation of PMo4 was achieved by following strategic procedures according to the MOF structural properties. The three prepared composites were characterized fully by several techniques, and the catalytic performance of the materials was tested. Optimization of the reaction conditions was performed using the PMo4 as the active catalytic center, resulting in total desulfurization after only 2 h using the [BMIM]PF6 ionic liquid as extraction solvent. Optimized conditions were applied to study the catalytic efficiency of PMo4@MOFs. The highest catalytic performance was found for PMo4@MIL-101, achieving near-complete desulfurization after 2 h. A significantly lower catalytic performance was obtained for PMo4@MOF-808 and PMo4@ZIF-8 (73.1 and 68.1%, respectively). Since the same amount of active center was used, the higher catalytic performance of the MIL-101 composite must be related to its higher window entrance and cavity sizes that promote a higher diffusion of molecules to the MIL-101 cavities and allow higher accessibility to the active catalytic centers. The PMo4@MIL-101 catalyst presented the highest activity associated with a high recycle capacity (10 reaction cycles without activity loss) and structural stability. Following the remarkable physicochemical properties and desulfurization efficiency exhibited by the PMo4@MIL-101 catalyst, further work will be developed to desulfurize real untreated fuel samples, such as diesel and heavy fuel oils.

Conflicts of interest

There are no conflicts to declare.

Acknowledgements

The authors thank the National Natural Science Foundation of China (Grant No. 21671157, 21371143, and 21501139) and the China Scholarship Council (No. 201906970032) for their financial support. We also acknowledge the projects, REQUIMTE-LAQV (UIDB/50006/2020, UIDP/50006/2020), financed by the Portuguese funds through the FCT/MCTES (Fundação para a Ciência e a Tecnologia – Ministério de Ciência, Tecnologia e Ensino Superior). C. M. G., L. C.-S. and S. S. B. thank FCT/MCTES for funding through the Individual Call to Scientific Employment Stimulus (Ref. 2022.02651.CEECIND/CP1724/CT0011, Ref. CEECIND/00793/2018 and Ref. CEECIND/03877/2018, respectively).

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