Open Access Article
This Open Access Article is licensed under a
Creative Commons Attribution 3.0 Unported Licence

Core–shell silica@CuxZnAl LDH catalysts for efficient CO2 hydrogenation to methanol

Meng Lyu a, Jianwei Zheng b, Claire Coulthard a, Jing Ren c, Yufei Zhao c, Shik Chi Edman Tsang b, Chunping Chen *a and Dermot O'Hare *a
aChemistry Research Laboratory, Department of Chemistry, University of Oxford, 12 Mansfield Road, Oxford, OX1 3TA, UK. E-mail: chunping.chen@chem.ox.ac.uk; dermot.ohare@chem.ox.ac.uk; Tel: +44(0)1865 272686
bWolfson Catalysis Centre, Department of Chemistry, University of Oxford, Oxford OX1 3QR, UK
cState Key Laboratory of Chemical Resource Engineering, Beijing University of Chemical Technology, 100029 Beijing, P. R. China

Received 2nd May 2023 , Accepted 2nd August 2023

First published on 1st September 2023


Abstract

The efficient production of methanol by reduction of CO2 using green hydrogen is a promising strategy from both a green chemistry and a carbon net zero perspective. Herein, we report the synthesis of well-dispersed core–shell catalyst precursors using silica@CuxZnAl-LDHs that can convert CO2 to methanol. The catalyst precursors can be formed using either a commercially available silica (ES757) or a mesoporous silica (e.g. MCM-48). These hybrid materials show significantly enhanced catalytic performance compared to the equivalent unsupported CuxZnAl LDH precursor. Space-time yields of up to 0.7 gMeOH gcat−1 h−1 under mild operating conditions were observed.


To reverse the rapid increase in atmosphere CO2 concentrations it is both urgent and critical we develop efficient strategies to reduce carbon emissions and reach a carbon net zero goal. To date, prodigious efforts have been devoted to developing alternative renewable non-fossil fuel energy sources, as well as CO2 capture and utilization strategies. Some of the most important approaches involve the conversion of CO2 into liquid hydrocarbons, formic acid, and methanol.1 In particular, hydrogenation of CO2 to methanol using renewably sourced hydrogen will be strategically a very important component in the portfolio of processes to reach both our emission and decarbonisation targets.2–4 Today, hydrogen can be produced from sustainable resources by utilising hydropower, solar energy, and biomass, thus offering the potential for a green “methanol economy”.5

CuxZnyAlOz based-catalysts are some of the most widely used catalysts for methanol synthesis from CO2.6,7 Metallic Cu nanoparticles are generally recognised as the active species, while ZnO and Al2O3 act as both electronic and geometric promoters for Cu. Several synthetic methods have been developed to assemble these compositions.6–8 Layered double hydroxides (LDHs) are a family of anionic 2D layered materials with the general formula, image file: d3sc02205f-t1.tif, where M and M′ are typically divalent and trivalent metal cations, octahedrally coordinated by hydroxyl groups and An represents the charge-compensating intercalated anion.8 Cu2+, Zn2+ and Al3+ cations can be incorporated into the LDH structure and used as precursors to CuxZnyAlOz catalysts for methanol synthesis. To obtain a robust catalyst exhibiting high activity, selectivity and lifetime for CO2 hydrogenation, two main strategies have been explored for CuxZnyAlOz catalysts derived from LDHs; (i) incorporation of elemental promoters such as Y, Zr, Ga into the CuxZnyAl LDH;9–11 and (ii) exfoliation and dispersion of the LDH layers using the aqueous miscible organic solvent treatment (AMOST) method.8 These strategies strive to generate high surface area metallic Cu and also inhibit the Cu nanoparticles from sintering as it is generally accepted that the catalytic activity is a function of exposed metallic Cu surface area to volume ratio. In practise, unsupported CuxZnyAl LDH platelets tend to stack/aggregate together and following calcination and reduction this results in a decrease in the exposed metallic Cu surface area to volume ratio which limits subsequent catalytic activity.

Herein, we report a new catalyst strategy by synthesising CuxZnAl–CO3 LDH precursors supported on a both commercially available silica (ES757) and some mesoporous silica (e.g. MCM48, SBA-16) cores, to form an SiO2@CuxZnAl LDH core@shell structure. The core@shell catalyst precursors formed using a commercially available silica (ES757) as the core show significantly enhanced catalytic performance compared to the equivalent unsupported CuxZnAl LDH precursor. Using the larger pore volume core silica such as MCM48 provides even further improvements in catalytic performance. The general synthesis procedure of core–shell catalyst is shown in Fig. 1a using ES757 as an exemplar core. ES757 is initially dispersed in Na2CO3 solution, then CuxZnAl–CO3 LDH is generated using an in situ co-precipitation approach, the CuxZnAl–CO3 LDH nucleates and then grows on both the external and internal surfaces of the ES757 particles to form ES757@CuxZnAl LDH. Calcination at 330 °C for 4 h produces ES757@CuxZnAl LDO, in which the LDH shell is transformed into uniform mixed metal oxide, often referred to as layered double oxide (LDO). The final active catalyst is prepared by reduction of ES757@CuxZnAl LDO under a dilute hydrogen atmosphere (5% H2/N2) at 290 °C for 2 h. We refer to the finished active catalyst as ES757@Cux.


image file: d3sc02205f-f1.tif
Fig. 1 (a) Synthesis scheme of Cu nanoparticles from ES757@CuxZnAl LDH. SEM images of (b and f) ES757; (c and g) ES757@Cu1.3ZnAl LDH; (d and h) ES757@Cu1.3ZnAl LDO and (e and i) ES757@Cu1.3. TEM images of (j) ES757; (k) ES757@Cu1.3ZnAl LDH; (l) shell of ES757@Cu1.3ZnAl LDO; (m) shell of ES757@Cu1.3.

As shown in Fig. 1b, ES757 is supplied as large spherical agglomerates (ca. 25 μm diameter) with a relatively smooth surface (Fig. 1f and S1a). The spherical agglomerates are decorated with a number of tiny silica nanoparticles (ca. 10–20 nm diameter) as indicated in Fig. 1j. When Cu1.3ZnAl LDH is carefully co-precipitated in the presence of a suspension of ES757 the LDH nucleates and grows from the silica surface. For the LDH coating, we observe a rosette platelet morphology with individual platelets between 300–500 nm (Fig. S2a and d). In our optimised synthesis conditions, the LDH platelets cover the entire surface, the LDH platelets grow hierarchically from the ES757 surface forming uniform core–shell particles (Fig. 1c and k) and a honeycomb surface (Fig. 1g and S1b) texture. As a control, a physical mixture of ES757 and Cu1.3ZnAl–CO3 LDH (prepared by manually mixing the two solids in 40[thin space (1/6-em)]:[thin space (1/6-em)]60 the weight ratio) shows separated particles that retain their individual morphological features (Fig. S1c and d). After calcination at 330 °C, the unsupported Cu1.3ZnAl LDO platelets condense and aggregate together (Fig. S2b and e). In contrast, calcination of ES757@Cu1.3ZnAl LDH produces LDO platelets still immobilised on the ES757 and retaining their honeycomb structure (Fig. 1d and h). Further reduction by hydrogen, produces metallic Cu nanoparticles embedded on the LDO matrix which we refer to as ES757@Cu1.3.8,12 In ES757@Cu1.3, the metallic Cu(0) nanoparticles are well dispersed with size distribution of 3.9 ± 1.6 nm (Fig. 1m). In comparison, hydrogen reduction of the unsupported Cu1.3ZnAl LDH (named as Cu1.3) produces nanoplatelets stacked together (Fig. S2c and f), with lower exposed metallic Cu(0). The electron mapping images (Fig. 2a–e) of ES757@Cu1.3ZnAl LDH demonstrate that Cu, Zn and Al from the Cu1.3ZnAl LDH and Si from ES757 are homogeneously dispersed across the whole spherical particle.


image file: d3sc02205f-f2.tif
Fig. 2 Structural evolution during the preparation of ES757@Cu1.3. (a) Electron image with Zn, Al, Cu, Si element mapping; (b) Si; (c) Cu; (d) Zn; (e) Al of ES757@Cu1.3ZnAl LDH; (f) powder X-ray diffraction patterns; (g) FTIR spectra; (h) Fourier transformed magnitudes of the experimental Cu K-edge EXAFS spectra; (i) normalised Cu K-edge XANES spectra.

Powder X-ray diffraction data (Fig. 2f) for ES757 exhibits a broad feature between 2θ = 15–35° typical of an amorphous silica-based material. The XRD of ES757@Cu1.3ZnAl LDH shows this amorphous background superimposed with the characteristic (00l) and (110) Bragg reflections associated with the crystalline LDH layer. The d-spacing of the (003) Bragg reflection of ES757@Cu1.3ZnAl LDH at 2θ = 7.58 Å, indicates a carbonate-intercalated LDH.13 After calcination, the characteristic LDH Bragg reflections disappear and they are replaced by a broad weak Bragg reflection at 2θ ≈ 38° (Fig. 2f and S8b). This feature can be assigned to the formation of copper oxide. Following reduction by hydrogen, a very weak Bragg reflection at 2θ ≈ 43° corresponding to (111) reflection from metallic copper is observed.

The FTIR spectrum (Fig. 2g) of ES757@Cu1.3ZnAl LDH exhibits both the characteristic IR vibrations bands of ES757 (the Si–O stretching at 1050 cm−1) and LDH shell (the metal–oxygen (M–O) vibration at 750 cm−1 and the O–H stretching of M-OH and water at 3440 cm−1, and water bending at 1600 cm−1).13–15 Upon calcination, the water bending absorbance (1600 cm−1) disappears and the O–H stretching band (3500 cm−1) reduces in intensity due to dehydration and dihydroxylation of the LDH shell. A sharp band at 1350 cm−1 in ES757@Cu1.3ZnAl LDH confirmed the presence of intercalated carbonate ions.16,17,19

The chemical composition of both unsupported Cu1.3ZnAl LDH and ES757@Cu1.3ZnAl LDH were investigated using elemental analyses and thermogravimetric analysis (TGA). The Cu/Al ratio of both pristine Cu1.3ZnAl LDH and the core–shell materials was determined by inductively coupled plasma optical emission spectrometry (ICP-OES). The data agree with the predicted values (Table S1). The TGA data (Fig. S3) for ES757@Cu1.3ZnAl LDH show the typical weight loss stages for an LDH, we can also use the TGA data to determine the ES757[thin space (1/6-em)]:[thin space (1/6-em)]LDH ratio in the core–shell materials as 40[thin space (1/6-em)]:[thin space (1/6-em)]60, again in agreement with the predicted value. The formula of Cu1.3ZnAl LDH and ES757@Cu1.3ZnAl LDH can be obtained from elemental analysis and TGA, which are [Cu1.31Zn0.93Al(OH)6.49(CO3)0.49·4H2O] and [SiO2]3.85[Cu1.29Zn1.03Al(OH)6.64(CO3)0.50·1.49H2O]1.05, respectively.10

N2 adsorption and desorption isotherms were used to investigate the porosity of the samples. The specific surface areas (Fig. S5a) of ES757 and Cu1.3ZnAl LDH using BET analysis are 273 m2 g−1 and 48 m2 g−1, respectively. Upon forming ES757@Cu1.3ZnAl LDH, the BET surface area becomes 189 m2 g−1, which is still higher than the theoretical surface area (138 m2 g−1) considering the 40[thin space (1/6-em)]:[thin space (1/6-em)]60 weight ratio (ES757[thin space (1/6-em)]:[thin space (1/6-em)]LDH). As shown in Fig. S4a, Cu1.3ZnAl LDH exhibits a type II isotherm with a H3 loop, indicating the agglomerate of platelets with slit-like pores. The BJH derived pore size distribution for Cu1.3ZnAl LDH (Fig. S4b) shows a wide pore size distribution with no clear maxima due to intense interplatelet aggregation.20 ES757 presents a type II isotherm with a H2b hysteresis loop, indicating that it is a mesoporous material in which the pore body is slightly larger than the pore neck. The pores in ES757 have a diameter in the range of 25–125 nm. The N2 adsorption and desorption isotherms of ES757@Cu1.3ZnAl LDH are identical to that of ES757, demonstrating the overall pore structure is retained following the formation of the core–shell structure. The pore size of ES757@Cu1.3ZnAl LDH is smaller and in a narrower range (Fig. S4b), indicating some Cu1.3ZnAl LDH may slightly block some of the pore openings in ES757. These observations indicate that immobilising an LDH on a porous substrate can avoid the aggregation of LDH platelets and exposes more surface area. A similar trend was found in total pore volume (Fig. S5b). Finally, calcination followed by reduction by hydrogen did not cause significant changes to the overall structural morphology the hybrid materials (Fig. S4). We observe a slight increase in the specific surface area after calcination (Fig. S5) which is due to the formation of amorphous porous network for Cu1.3ZnAl LDO.

The X-ray absorption near-edge structure (XANES) spectroscopy and extended X-ray absorption fine structure (EXAFS) measurements were measured to probe the nature of Cu species in three catalysts prepared by calcination and reduction of (i) Cu1.3ZnAl LDH, (ii) ES757@Cu1.3ZnAl LDH and (iii) Cu1.3 + ES757 (a physical mixture of Cu1.3ZnAl LDH and ES757). All the samples show two characteristic features in the first shell (Fig. 2h). The most noticeable scattering was observed at 2.2 Å which is ascribed to the Cu–Cu separation. A weak feature at 1.7 Å is assigned to Cu–O. According to the fitting of the EXAFS (Fig. S6, S7 and Table S3), ES757@Cu1.3 has the lowest number of Cu–Cu nearest neighbour interactions, indicating ES757@Cu1.3 has the best dispersion compared to Cu1.3 and Cu1.3 + ES757. XANES spectra in Fig. 2i shows that the Cu K edge feature falls at the highest energy in ES757@Cu1.3 which suggests Cu is more electronic deficient (Cuδ+), these data are consistent with formation of well dispersed Cu nanoparticles in contact to the support through Cu–O interactions.

The catalytic performance of Cu1.3, ES757@Cu1.3 and Cu1.3 + ES757 for CO2 hydrogenation to methanol was evaluated. As shown in Fig. 3a, ES757@Cu1.3 and Cu1.3 + ES757 exhibit higher CO2 conversion (23% and 26%, respectively) than that of Cu1.3 (16%). It is believed that the introduction of ES757 has a synergistic effect benefiting mass transfer and therefore promote CO2 conversion.21 Noteworthy, the CO2 conversions of ES757@Cu1.3 and Cu1.3 + ES757 are approaching the equilibrium value under our catalytic testing conditions.22 More importantly, ES757@Cu1.3 shows the highest methanol selectivity of 48% (the only other C-product detected was CO) which is significantly higher than that of Cu1.3 + ES757 (28%). The particle sizes arelisted in Table S2, it indicates high dispersion of Cu species. It should be noted that the particle sizes derived from TEM are a bit larger than those from XRD. We believe that this may arise from the high copper dispersion as evidenced from EXAFS and the measured copper surface area (SCu). It is widely accepted that stable, well-dispersed metallic copper with a large SCu is linked to overall methanol productivity.23 N2O chemisorption was used to determine the SCu. The copper dispersion18 is then determined from exposed copper surface (SCu)24,25 and total copper loading. We found that both the copper dispersion and exposed copper surface area of ES757@Cu1.3 (25%, 32.14 m2 gcatalyst−1) is much higher than that of Cu1.3 (13.57%, 23.05 m2 gcatalyst−1) and Cu1.3 + ES757 (1.88%, 17.07 m2 gcatalyst−1) (Table S2). It is apparent that a catalyst prepared without a support or simply mixing the catalyst with porous silica cannot avoid the aggregation between LDH platelets, leading to much lower exposed copper surface. Immobilising and orienting the LDH catalyst precursor on the porous silica creates a highly dispersed and exposed surface bound active metallic copper sites, resulting in the superior CO2 conversion and methanol selectivity. This enables ES757@Cu1.3 to exhibit the highest space-time yield for methanol (STYMeOH 0.64 gmethanol gcat−1 h−1) among these three catalysts.


image file: d3sc02205f-f3.tif
Fig. 3 Catalytic performance and structure relationship. The effect of (a) core–shell structure, (b) Cu loading and Cu surface area and (c) specific surface area (insets are the HRSEM of core–shells) on the catalytic performance. Reaction condition: temperature = 270 °C, pressure = 45 bar, H2[thin space (1/6-em)]:[thin space (1/6-em)]CO2 (molar) = 3[thin space (1/6-em)]:[thin space (1/6-em)]1, WHSV = 18[thin space (1/6-em)]000 mL gcatalyst−1 h−1.

We further studied the effects of copper dispersion and SCu by preparing a series of ES757@CuxZnAl–CO3–LDH core–shells with different copper loadings. The core–shells were prepared using the same procedure as ES757@Cu1.3ZnAl LDH, the copper content was controlled by the ratio of metal salts used in the co-precipitation step. The series of precursors, ES757@CuxZnAl–CO3–LDH (x = 0.8–4) were prepared and following calcination and hydrogen reduction were named ES757@Cux (x = 0.8–4). HR-SEM images (Fig. S8) confirm the formation of core–shell structures and the powder XRD data (Fig. S9a) indicate no other crystalline impurities. Following calcination, ES757@CuxZnAl LDOs do not present any LDH Bragg reflections. Following hydrogen reduction, the intensity of metallic Cu 111 Bragg reflection increases in intensity with increasing copper loading. The copper loading, dispersion, SCu and the catalytic performance (turnover frequency (TOF) and space time yield STY) are summarised in Table S2. The relationship between STYMeOH and SCu is shown in Fig. 3b. It is found that both copper dispersion and SCu increase with increasing copper loading, reaching a maximum at ES757@Cu1.3. Further increasing the copper loading results in the decrease of copper dispersion and SCu due to the sintering of the metallic Cu nanoparticles at high loadings. The STYMeOH follows the same trend as copper dispersion and SCu. ES757@Cu1.3 with the highest copper dispersion and largest SCu exhibits the highest STYMeOH among all core–shell materials we have studied.

The catalytic effects of other porous silica cores were explored. We have use of SBA-16 and MCM-48 with specific surface areas of 688 and 1186 m2 g−1 respectively. The synthesis method is the same as that of ES757@CuxZnAl LDHs, the copper loading was kept constant at Cu[thin space (1/6-em)]:[thin space (1/6-em)]Zn[thin space (1/6-em)]:[thin space (1/6-em)]Al = 2[thin space (1/6-em)]:[thin space (1/6-em)]1[thin space (1/6-em)]:[thin space (1/6-em)]1. The calcined and reduced catalysts derived from SBA-16@Cu2ZnAl–CO3 LDH and MCM-48@Cu2ZnAl–CO3 LDH were named SBA-16@Cu2 and MCM-48@Cu2 respectively. As shown in Fig. 3c (inset HRSEM) and Fig. S9–14, these samples formed the similar core–shell structures as that of ES757@Cu1.3ZnAl LDH. A uniform distribution of Cu, Zn and Al is observed over the MCM-48 and SBA-16 particles as evidenced by EDX mapping. The influence of the specific surface areas of these cores on the catalytic performance of the final catalyst can be seen in Fig. 3c. Generally, the catalysts with higher surface area exhibit higher STYMeOH. It is possible that copper may distribute more evenly over the surface when employing a silica core with a higher surface area.21,26

The catalytic performance of the core–shell catalysts developed in this work were compared with those of an commercial Cu/ZnO/Al2O3 catalyst and our best Cu-catalyst (Cu1.3ZnGaOy) derived from the exfoliated Cu1.3ZnGa LDH precursor, under the same catalytic conditions.8 As shown in Table S3, both ES757@Cu1.3 and MCM-48@Cu2 exhibit higher CO2 conversion and methanol selectivity. These catalysts deliver superior STYMeOH of 0.64 and 0.7 gmethanol gcat−1 h−1, respectively more than Cu1.3ZnGa (STYMeOH = 0.59 gmethanol gcat−1 h−1), delivering nearly twice the commercial catalyst (STYMeOH = 0.38 gmethanol gcat−1 h−1) under our testing conditions. It is also important to note that the copper loadings in our core–shell catalysts is typically 19.81–24.5 wt%, significantly lower than that of Cu1.3ZnGa (33.5 wt%) and commercial catalyst (50.0 wt%). Therefore, on a per Cu atom basis these core–shell catalysts contain significantly more active individual catalytic sites.

Conclusion

We have developed effective syntheses of a series of core–shell catalysts using micro- and mesoporous silica cores and a CuxZnAl LDH as a functional shell. The silica cores have excellent coverage by the LDHs platelets and are robust to calcination. Hydrogen reduction of the silica@CuxZnAl LDO precursors produces robust and highly dispersed metallic Cu nanoparticles with high SCu. We believe this strategy delivers an effective pathway to prevent the aggregation of the active catalytic sites under catalytic conditions. ES757@Cu1.3 was found as our best performing catalyst to date among the ES757@Cux family, although this can be further improved by using a higher surface area silica core (e.g. MCM-48). The STYMeOH for these materials places them as some of the best performing catalytic systems for CO2 hydrogenation to MeOH, especially if you normalise on a per Cu basis.

Data availability

Experimental procedures, and spectroscopic data can be found in the ESI.

Author contributions

Meng Lyu and Jianwei Zheng, performed the synthetic and catalysis experimental work; Claire Coulthard assisted with the electron microscopy studies; Ren Jing, and Yufei Zhao recorded and interpreted the X-ray absorption analysis; Shik Chi Edman Tsang, Chunping Chen, and Dermot O'Hare conceptualised the research, acquired funding, and supervised the work; all authors revised and edited the manuscript. All authors have read and agreed to the published version of the manuscript.

Conflicts of interest

The authors declare no competing financial interests.

Acknowledgements

We would like to thank Beijing Synchrotron Radiation Facility for providing measurement at the 1W1B beamline. M. Lyu. acknowledges the Chinese Scholarship Council (CSC) for funding. C. Chen. and J. Zheng would like to thank SCG Chemicals Public Co., Ltd (Thailand) for funding.

Notes and references

  1. R.-P. Ye, J. Ding, W. Gong, M. D. Argyle, Q. Zhong, Y. Wang, C. K. Russell, Z. Xu, A. G. Russell and Q. Li, Nat. Commun., 2019, 10, 1–15 CrossRef PubMed.
  2. S. Kattel, P. J. Ramírez, J. G. Chen, J. A. Rodriguez and P. Liu, Science, 2017, 355, 1296–1299 CrossRef CAS PubMed.
  3. H. Bahruji, M. Bowker, G. Hutchings, N. Dimitratos, P. Wells, E. Gibson, W. Jones, C. Brookes, D. Morgan and G. Lalev, J. Catal., 2016, 343, 133–146 CrossRef CAS.
  4. O. Martin, A. J. Martín, C. Mondelli, S. Mitchell, T. F. Segawa, R. Hauert, C. Drouilly, D. Curulla-Ferré and J. Pérez-Ramírez, Angew. Chem., Int. Ed., 2016, 55, 6261–6265 CrossRef CAS PubMed.
  5. D. W. Stephan, Nature, 2013, 495, 54–55 CrossRef CAS PubMed.
  6. X. Jiang, X. Nie, X. Guo, C. Song and J. G. Chen, Chem. Rev., 2020, 120, 7984–8034 CrossRef CAS PubMed.
  7. F. Meshkini, M. Taghizadeh and M. Bahmani, Fuel, 2010, 89, 170–175 CrossRef CAS.
  8. M. M.-J. Li, C. Chen, T. c. e. Ayvalı, H. Suo, J. Zheng, I. F. Teixeira, L. Ye, H. Zou, D. O'Hare and S. C. E. Tsang, ACS Catal., 2018, 8, 4390–4401 CrossRef CAS.
  9. P. Gao, F. Li, F. Xiao, N. Zhao, W. Wei, L. Zhong and Y. Sun, Catal. Today, 2012, 194, 9–15 CrossRef CAS.
  10. P. Gao, F. Li, N. Zhao, F. Xiao, W. Wei, L. Zhong and Y. Sun, Appl. Catal., A, 2013, 468, 442–452 CrossRef CAS.
  11. S. Kühl, J. Schumann, I. Kasatkin, M. Hävecker, R. Schlögl and M. Behrens, Catal. Today, 2015, 246, 92–100 CrossRef.
  12. M. Behrens, F. Studt, I. Kasatkin, S. Kühl, M. Hävecker, F. Abild-Pedersen, S. Zander, F. Girgsdies, P. Kurr and B.-L. Kniep, Science, 2012, 336, 893–897 CrossRef CAS PubMed.
  13. F. Cavani, F. Trifiro and A. Vaccari, Catal. Today, 1991, 11, 173–301 CrossRef CAS.
  14. R.-P. Ye, L. Lin, C.-C. Chen, J.-X. Yang, F. Li, X. Zhang, D.-J. Li, Y.-Y. Qin, Z. Zhou and Y.-G. Yao, ACS Catal., 2018, 8, 3382–3394 CrossRef CAS.
  15. S. O. Akpotu and B. Moodley, J. Mol. Liq., 2018, 261, 540–549 CrossRef CAS.
  16. M. Smyrnioti, C. Tampaxis, T. Steriotis and T. Ioannides, Catal. Today, 2020, 357, 495–502 CrossRef CAS.
  17. J. Lavalley, Catal. Today, 1996, 27, 377–401 CrossRef CAS.
  18. R.-C. Zeng, X.-T. Li, Z.-G. Liu, F. Zhang, S.-Q. Li and H.-Z. Cui, Front. Mater. Sci., 2015, 9, 355–365 CrossRef.
  19. A. M. Cardinale, C. Carbone, S. Consani, M. Fortunato and N. Parodi, Crystals, 2020, 10, 443 CrossRef CAS.
  20. C. Chen, A. Wangriya, J.-C. Buffet and D. O'Hare, Dalton Trans., 2015, 44, 16392–16398 RSC.
  21. M. K. Koh, M. Khavarian, S. P. Chai and A. R. Mohamed, Int. J. Hydrogen Energy, 2018, 43, 9334–9342 CrossRef CAS.
  22. K. Stangeland, H. Li and Z. Yu, Ind. Eng. Chem. Res., 2018, 57, 4081–4094 CrossRef CAS.
  23. G. V. Sagar, P. V. R. Rao, C. S. Srikanth and K. V. Chary, J. Phys. Chem. B, 2006, 110, 13881–13888 CrossRef CAS PubMed.
  24. D. S. Brands, E. K. Poels, T. A. Krieger, O. V. Makarova, C. Weber, S. Veer and A. Bliek, Catal. Lett., 1996, 36, 175–181 CrossRef CAS.
  25. W. Robinson and J. Mol, Appl. Catal., 1990, 63, 165–179 CrossRef CAS.
  26. P. S. Murthy, W. Liang, Y. Jiang and J. Huang, Energy Fuels, 2021, 35, 8558–8584 CrossRef CAS.

Footnotes

Electronic supplementary information (ESI) available: XRD, SEM, TEM, FTIR, TGA, BET, EXAFS fitting, ICP-MS and elemental analysis. See DOI: https://doi.org/10.1039/d3sc02205f
Meng Lyu and Jianwei Zheng are co-first author as they contribute equally to this paper.

This journal is © The Royal Society of Chemistry 2023
Click here to see how this site uses Cookies. View our privacy policy here.