Hydrodeoxygenation of 2,5-dimethyltetrahydrofuran over bifunctional Pt–Cs2.5H0.5PW12O40 catalyst in the gas phase: enhancing effect of gold |
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| Authors: | Hanan Althikrallah Elena F Kozhevnikova Ivan V Kozhevnikov |
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| Institution: | University of Liverpool, Department of Chemistry, Liverpool L69 7ZD UK.; Department of Chemistry, King Faisal University, College of Science, P.O. Box 400, Al-Ahsa 31982, Saudi Arabia, |
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| Abstract: | 2,5-Dimethyltetrahydrofuran (DMTHF) is deoxygenated to n-hexane with >99% selectivity at mild conditions (90 °C, 1 bar H2 pressure, fixed-bed reactor) in the presence of the bifunctional metal-acid catalyst Pt–CsPW comprising Pt and Cs2.5H0.5PW12O40 (CsPW), an acidic Cs salt of Keggin-type heteropoly acid H3PW12O40. Addition of gold to the Pt–CsPW catalyst increases the turnover rate at Pt sites more than twofold, whereas the Au alone without Pt is not active. The enhancement of catalyst activity is attributed to PtAu alloying, which is supported by STEM-EDX and XRD analysis.Addition of gold to the Pt–CsPW catalyst has an enhancing effect on the HDO of DMTHF, with a twofold increase of turnover rate at Pt sites.Biomass-derived furanic compounds are of interest as a renewable feedstock, which can be processed into a range of value-added chemicals and green fuels via catalytic hydroconversion.1–8 Hydrodeoxygenation (HDO) of furanic compounds using bifunctional metal–acid catalysis has been demonstrated to be an effective strategy to produce green fuels under mild conditions3,4,6,8–12 and references therein. The HDO over bifunctional metal-acid catalysts is much more efficient compared to the reaction over monofunctional metal catalysts.11,12 Previously, we have reported HDO of a wide range of oxygenates in the gas phase to produce alkanes in the presence of bifunctional catalysts comprising Pt, Ru, Ni and Cu as metal components and Keggin-type heteropoly acids, with their activity decreasing in the order Pt > Ru > Ni > Cu.13,14 Pt–CsPW comprising Pt and strongly acidic heteropoly salt Cs2.5H0.5PW12O40 (CsPW) has been reported to be a highly efficient catalyst for the HDO of 2,5-dimethylfuran (DMF) and 2,5-dimethyltetrahydrofuran (DMTHF) to produce n-hexane with 100% yield at 90–120 °C and ambient pressure.11,12 The HDO of DMTHF over Pt–CsPW occurs through a sequence of hydrogenolysis, dehydration and hydrogenation steps catalysed by Pt and proton sites of the bifunctional catalyst (). These include the ring opening of DMTHF to form 2-hexanol on Pt sites followed by its dehydration on proton sites of CsPW to hexene, which is finally hydrogenated to n-hexane on Pt sites.12 It is the facile dehydration of the secondary alcohol intermediate that drives the HDO process forward.11,12 The rate-limiting step is either the ring hydrogenolysis or 2-hexanol dehydration depending on the ratio of accessible surface metal and acid sites Pt/H+.12 Other platinum group metals such as Pd, Ru and Rh, that have high selectivity to ring hydrogenation rather than ring hydrogenolysis,2,7 have low activities in HDO of DMF and DMTHF.11Open in a separate windowReaction pathway for hydrodeoxygenation of DMTHF over Pt–CsPW.Bimetallic PtAu and PdAu catalysts have been reported to have an enhanced performance in comparison to monometallic Pt and Pd catalysts,15–31 for example, in hydrogenation,16,21,29 hydrodesulphurisation,27,28 oxidation,22,24 isomerisation15,19,30,31 and other reactions.17,18,20,25,26 The enhancement of catalyst performance by addition of gold can be attributed to geometric (ensemble) and electronic (ligand) effects of the constituent elements in PtAu and PdAu bimetallic species.25,26Here we looked at the effect of Au on the performance of Pt–CsPW catalysts in the HDO of DMTHF in the gas phase (see the ESI for experimental details†). The CsPW heteropoly salt is a well-known solid acid catalyst; it possesses strong proton sites, large surface area and high thermal stability (∼500 °C decomposition temperature).9,32–34 Supported bimetallic catalysts PtAu/SiO2 and PtAu/CsPW were prepared by co-impregnation of H2PtCl6 and HAuCl3 onto SiO2 and CsPW followed by reduction with H2 at 250 °C (ESI†). This method gives supported bimetallic PtAu nanoparticles of a random composition together with various Pt and Au nanoparticles.15,16,31 Information about the catalysts studied is given in | Open in a separate windowaBET surface area.bSingle point total pore volume.cAverage BET pore diameter.dMetal dispersion.eMetal particle size.fCalculated from the equation d (nm) = 0.9/D.gMetal particle diameter from powder XRD (Scherrer equation).hPt dispersion determined by H2/O2 titration (average from three measurements); for PtAu catalysts, assumed negligible H2 adsorption on gold (see the ESI).iFrom STEM.Powder X-ray diffraction (XRD) has been widely used for the characterization of supported Au alloy catalysts.26 The XRD patterns for the silica-supported catalysts 6.4% Pt/SiO2, 6.5% Au/SiO2 and 6.6% Pt/5.9% Au/SiO2 are shown in . As expected, the 6.4% Pt/SiO2 and 6.5% Au/SiO2 catalysts display the fcc pattern of Pt and Au metal nanoparticles. The Pt peaks are broader than the Au peaks, which indicates a higher dispersion of Pt particles, with an average particle size of 8.0 nm for Pt and 46 nm for Au, which is in agreement with the STEM values (Open in a separate windowPowder XRD patterns of 6.4% Pt/SiO2, 6.5% Au/SiO2 and 6.6% Pt/5.9% Au/SiO2; the pattern for 6.6% Pt/5.9% Au/SiO2 shows broad 111], 200], 220] and 311] fcc PtAu alloy peaks in the range 38–40°, 44–48°, 65–68° and 78–81°, respectively.The pattern for the 6.6% Pt/5.9% Au/SiO2 catalyst clearly shows the presence of PtAu bimetallic particles with broad 111], 200], 220] and 311] diffraction peaks of the fcc PtAu alloy between the corresponding diffractions of the pure metals in the range 38–40°, 44–48°, 65–68° and 78–81°, respectively. shows the high-angle annular dark field (HAADF) STEM images of the three silica-supported catalysts 6.4% Pt/SiO2, 6.5% Au/SiO2 and 6.6% Pt/5.9% Au/SiO2 with metal nanoparticles indicated as bright spots on the darker background. In the Pt/SiO2 catalyst, there are two populations: small Pt particles of 5 nm size and coalesced Pt particles of a larger size. The Au/SiO2 catalyst displays Au particles of spherical, rectangular and triangular morphology, with an average size of 38 nm. The bimetallic PtAu/SiO2 catalyst shows a high agglomeration and different kinds of morphology of metal particles.Open in a separate windowHAADF-STEM images of (a) 6.4% Pt/SiO2, (b) 6.5% Au/SiO2 and (c) 6.6% Pt/5.9% Au/SiO2 catalysts, showing noble metal nanoparticles as bright spots.The energy dispersive X-ray spectroscopic analysis (EDX) of metal particles in the PtAu/SiO2 catalyst shows that these particles contain both platinum and gold. EDX elemental mapping clearly demonstrates that Pt and Au maps cover the same areas of PtAu/SiO2 catalyst (), indicating PtAu alloying with formation of a non-uniform bimetallic PtAu particles. More EDX mapping is presented in the ESI (Fig. S1†).Open in a separate windowHAADF-STEM image of 6.6% Pt/5.9% Au/SiO2 catalyst and the corresponding STEM-EDX elemental maps showing the spatial distribution of Au (red) and Pt (green) in the sample.STEM–EDX for CsPW-supported Pt, Au and PtAu catalysts has been reported elsewhere.16 These STEM images are difficult to analyse due to W, Pt and Au having similar large atomic numbers Z (74, 78, and 79, respectively). Crystalline CsPW containing 70 wt% of W displays a strong background which makes it difficult to discern smaller Pt and Au particles from the Z-contrast HAADF images and determine accurately metal particle size. Nevertheless, the STEM-EDX analysis indicates the presence of bimetallic PtAu particles in the PtAu/CsPW catalyst with a wide range of Pt/Au atomic ratios.16Representative results for HDO of DMTHF in the presence of bifunctional metal-acid catalysts Pt–CsPW and PtAu–CsPW, which were used as physical mixtures of metal and acid components at similar Pt loadings, are shown in ). The molar ratio of surface metal and proton sites in the catalysts was chosen low enough (Pt/H+ = 0.03–0.1) to ensure the reaction being limited by the DMTHF ring opening step.12 The density of surface Pt sites was estimated from the Pt dispersion ( and the CsPW surface area of 135 cm2 g−1 ( |
