Frontiers of Chemical Science and Engineering >

2020 , Vol. 14 >Issue 6: 1052 - 1064

DOI: https://doi.org/10.1007/s11705-019-1908-y

RESEARCH ARTICLE

Mechanism of methanol decomposition on the Pd/WC(0001) surface unveiled by first-principles calculations

  • Jinhua Zhang 1,2 ,
  • Yuanbin She , 1
Expand
  • 1. College of Chemical Engineering, Zhejiang University of Technology, Hangzhou 310014, China
  • 2. School of Materials and Environmental Engineering, Chizhou University, Chizhou 247000, China

Received date: 24 Jul 2019

Accepted date: 27 Oct 2019

Published date: 15 Dec 2020

Copyright

2020 Higher Education Press and Springer-Verlag GmbH Germany, part of Springer Nature
Fold

Abstract

In this study, the decomposition of methanol into the CO and H species on the Pd/tungsten carbide (WC)(0001) surface is systematically investigated using periodic density functional theory (DFT) calculations. The possible reaction pathways and intermediates are determined. The results reveal that saturated molecules, i.e., methanol and formaldehyde, adsorb weakly on the Pd/ WC(0001) surface. Both CO and H prefer three-fold sites, with adsorption energies of −1.51 and −2.67 eV, respectively. On the other hand, CH3O stably binds at three-fold and bridge sites, with an adsorption energy of −2.58 eV. However, most of the other intermediates tend to adsorb to the surface with the carbon and oxygen atoms in their sp3 and hydroxyl-like configurations, respectively. Hence, the C atom of CH2OH preferentially attaches to the top sites, CHOH and CH2O adsorb at the bridge sites, while COH and CHO occupy the three-fold sites. The DFT calculations indicate that the rupture of the initial C–H bond promotes the decomposition of CH3OH and CH2OH, whereas in the case of CHOH, O–H bond scission is favored over the C–H bond rupture. Thus, the most probable methanol decomposition pathway on the Pd/WC(0001) surface is CH3OH → CH2OH → trans-CHOH → CHO → CO. The present study demonstrates that the synergistic effect of WC (as carrier) and Pd (as catalyst) alters the CH3OH decomposition pathway and reduces the noble metal utilization.

Key words: density functional theory; methanol; direct methanol fuel cells; WC(0001)-supported Pd monolayer; decomposition mechanism

Cite this article

Jinhua Zhang , Yuanbin She . Mechanism of methanol decomposition on the Pd/WC(0001) surface unveiled by first-principles calculations[J]. Frontiers of Chemical Science and Engineering, 2020 , 14(6) : 1052 -1064 . DOI: 10.1007/s11705-019-1908-y

Acknowledgements

This work was supported by the National Natural Science Foundation of China (Grant No. 21776259) and the Key Laboratory of Micro-Nano Powder and Advanced Energy Materials of the Anhui Higher Education Institutes, Chizhou University, China.

References

Publishing order | Descend order by publishing year | Descend order by cited within
1
Gomez J C C, Moliner R, Lazaro M J. Palladium-based catalysts as electrodes for direct methanol fuel cells: A last ten years review. Catalysts, 2016, 6(9): 1–20

2
Lian H Y, Li X S, Liu J L, Zhu A M. Methanol steam reforming by heat-insulated warm plasma catalysis for efficient hydrogen production. Catalysis Today, 2019, 337: 76–82

DOI

3
Garcia-Muelas R, Li Q, Lopez N. Density functional theory comparison of methanol decomposition and reverse reactions on metal surfaces. ACS Catalysis, 2015, 5(2): 1027–1036

DOI

4
Jiang Z, Wang B, Fang T. A theoretical study on the complete dehydrogenation of methanol on Pd (100) surface. Applied Surface Science, 2016, 364: 613–619

DOI

5
Lu X Q, Wang W L, Deng Z G, Zhu H Y, Wei S X, Ng S P, Guo W Y, Wu C M L. Methanol oxidation on Ru(0001) for direct methanol fuel cells: Analysis of the competitive reaction mechanism. RSC Advances, 2016, 6(3): 1729–1737

DOI

6
Zhang M, Wu X, Yu Y. A comparative DFT study on the dehydrogenation of methanol on Rh(100) and Rh(110). Applied Surface Science, 2018, 436: 268–276

DOI

7
Shen K C, Jia C G, Cao B X, Xu H, Wang J, Zhang L C, Kim K, Wang W M. Comparison of catalytic activity between Au(110) and Au(111) for the electro-oxidation of methanol and formic acid: Experiment and density functional theory calculation. Electrochimica Acta, 2017, 256: 129–138

DOI

8
Jiang Z, Guo S Y, Fang T. Theoretical investigation on the dehydrogenation mechanism of CH3OH on Cu(100) surface. Journal of Alloys and Compounds, 2017, 698: 617–625

DOI

9
Liu L N, Yao H D, Jiang Z, Fang T. Theoretical study of methanol synthesis from CO2 hydrogenation on PdCu3(111) surface. Applied Surface Science, 2018, 451: 333–345

DOI

10
Du P, Wu P, Cai C X. Mechanism of methanol decomposition on the Pt3Ni(111) surface: DFT study. Journal of Physical Chemistry C, 2017, 121(17): 9348–9360

DOI

11
Liu L N, Fan F, Bai M M, Xue F, Ma X R, Jiang Z, Fang T. Mechanistic study of methanol synthesis from CO2 hydrogenation on Rh-doped Cu(111) surfaces. Molecular Catalysis, 2019, 466: 26–36

DOI

12
Ou L H. Theoretical insights into the effect of solvation and sublayer Ru on Pt-catalytic CH3OH oxidation mechanisms in the aqueous phase. Journal of Physical Chemistry C, 2018, 122(26): 14554–14565

DOI

13
Jiang X, Nie X W, Wang X X, Wang H Z, Koizumi N, Chen Y G, Guo X W, Song C S. Origin of Pd-Cu bimetallic effect for synergetic promotion of methanol formation from CO2 hydrogenation. Journal of Catalysis, 2019, 369: 21–32

DOI

14
Ye J Y, Liu C J, Ge Q F. A DFT study of methanol dehydrogenation on the PdIn(110) surface. Physical Chemistry Chemical Physics, 2012, 14(48): 16660–16667

DOI

15
Meng J H, Carl A M, Zellner M B, Chen J G. Effects of bimetallic modification on the decomposition of CH3OH and H2O on Pt/W(110) bimetallic surfaces. Surface Science, 2010, 604(21-22): 1845–1853

DOI

16
Damte J Y, Lyu S L, Leggesse E G, Jiang J C. Methanol decomposition reactions over a boron-doped graphene supported Ru-Pt catalyst. Physical Chemistry Chemical Physics, 2018, 20(14): 9355–9363

DOI

17
Allian A D, Takanabe K, Fujdala K L, Hao X, Truex T J, Cai J, Buda C, Neurock M, Iglesia E. Chemisorption of CO and mechanism of CO oxidation on supported platinum nanoclusters. Journal of the American Chemical Society, 2011, 133(12): 4498–4517

DOI

18
Lu Y B, Wang J M, Yu L, Kovarik L, Zhang X W, Hoffman A S, Gallo A, Bare S R, Sokaras D, Kroll T, Dagle V, Xin H, Karim A M. Identification of the active complex for CO oxidation over single-atom Ir-on-MgAl2O4 catalysts. Nature Catalysis, 2019, 2(2): 149–156

DOI

19
Kubler M, Jurzinsky T, Ziegenbalg D, Cremers C. Methanol oxidation reaction on core-shell structured Ruthenium-Palladium nanoparticles: Relationship between structure and electrochemical behavior. Journal of Power Sources, 2018, 375: 320–334

DOI

20
Luo L M, Zhang R H, Chen D, Hu Q Y, Zhang X, Yang C Y, Zhou X W. Hydrothermal synthesis of PdAu nanocatalysts with variable atom ratio for methanol oxidation. Electrochimica Acta, 2018, 259: 284–292

DOI

21
Hosseini M G, Mahmoodi R, Daneshvari-Esfahlan V. Ni@Pd core-shell nanostructure supported on multi-walled carbon nanotubes as efficient anode nanocatalysts for direct methanol fuel cells with membrane electrode assembly prepared by catalyst coated membrane method. Energy, 2018, 161: 1074–1084

DOI

22
Jurzinsky T, Bar R, Cremers C, Tubke J, Elsner P. Highly active carbon supported palladium-rhodium PdXRh/C catalysts for methanol electrooxidation in alkaline media and their performance in anion exchange direct methanol fuel cells. Electrochimica Acta, 2015, 176: 1191–1201

DOI

23
Liu L N, Fan F, Jiang Z, Gao X F, Wei J J, Fang T. Mechanistic study of Pd‒Cu bimetallic catalysts for methanol synthesis from CO2 hydrogenation. Journal of Physical Chemistry C, 2017, 121(47): 26287–26299

DOI

24
Wu P P, Yang B. Theoretical insights into the promotion effect of subsurface boron for the selective hydrogenation of CO to methanol over Pd catalysts. Physical Chemistry Chemical Physics, 2016, 18(31): 21720–21729

DOI

25
Jiang X, Jiao Y, Moran C, Nie X W, Gong Y T, Guo X W, Walton K S, Song C S. CO2 hydrogenation to methanol on Pd‒Cu bimetallic catalysts with lower metal loadings. Catalysis Communications, 2019, 118: 10–14

DOI

26
Lu L, Sun X F, Ma J, Yang D X, Wu H H, Zhang B X, Zhang J L, Han B X. Highly efficient electroreduction of CO2 to methanol on palladium-copper bimetallic aerogels. Angewandte Chemie International Edition, 2018, 57(43): 14149–14153

DOI

27
Liu X, Men Y, Wang J G, He R, Wang Y Q. Remarkable support effect on the reactivity of Pt/In2O3/MOx catalysts for methanol steam reforming. Journal of Power Sources, 2017, 364: 341–350

DOI

28
Kruse N, Rebholz M, Matolin V, Chuah G K, Block J H. Methanol decomposition on Pd(111) single-crystal surfaces. Surface Science, 1990, 238(1-3): L457–L462

DOI

29
Jiang R, Guo W, Li M, Fu D, Shan H. Density functional investigation of methanol dehydrogenation on Pd(111). Journal of Physical Chemistry C, 2009, 113(10): 4188–4197

DOI

30
Nikolic V M, Zugic D L, Perovic I M, Saponjic A B, Babic B M, Pasti I A, Kaninski M P M. Investigation of tungsten carbide supported Pd or Pt as anode catalysts for PEM fuel cells. International Journal of Hydrogen Energy, 2013, 38(26): 11340–11345

DOI

31
Vasic D D, Pasti I A, Mentus S V. DFT study of platinum and palladium overlayers on tungsten carbide: Structure and electrocatalytic activity toward hydrogen oxidation/evolution reaction. International Journal of Hydrogen Energy, 2013, 38(12): 5009–5018

DOI

32
Elezovic N R, Zabinski P, Ercius P, Wytrwal M, Radmilovic V R, Lacnjevac U C, Krstajic N V. High surface area Pd nanocatalyst on core-shell tungsten based support as a beneficial catalyst for low temperature fuel cells application. Electrochimica Acta, 2017, 247: 674–684

DOI

33
Moon J S, Lee Y W, Han S B, Park K W. Pd nanoparticles on mesoporous tungsten carbide as a non-Pt electrocatalyst for methanol electrooxidation reaction in alkaline solution. International Journal of Hydrogen Energy, 2014, 39(15): 7798–7804

DOI

34
Zhang Q, Mellinger Z J, Jiang Z, Chen X, Wang B, Tian B Y, Liang Z X, Chen J G G. Palladium-modified tungsten carbide for ethanol electrooxidation: From surface science studies to electrochemical evaluation. Journal of the Electrochemical Society, 2018, 165(15): J3031–J3038

DOI

35
Park H Y, Park I S, Choi B, Lee K S, Jeon T Y, Sung Y E, Yoo S J. Pd nanocrystals on WC as a synergistic electrocatalyst for hydrogen oxidation reactions. Physical Chemistry Chemical Physics, 2013, 15(6): 2125–2130

DOI

36
Mellinger Z J, Kelly T G, Chen J G. Pd-modified tungsten carbide for methanol electro-oxidation: From surface science studies to electrochemical evaluation. ACS Catalysis, 2012, 2(5): 751–758

DOI

37
Delley B. From molecules to solids with the DMol(3) approach. Journal of Chemical Physics, 2000, 113(18): 7756–7764

DOI

38
Perdew J P, Burke K, Ernzerhof M. Generalized gradient approximation made simple. Physical Review Letters, 1996, 77(18): 3865–3868

DOI

39
Wang X, Chen L, Li B. A density functional theory study of methanol dehydrogenation on the PtPd3(111) surface. International Journal of Hydrogen Energy, 2015, 40(31): 9656–9669

DOI

40
Zhang M, Wu X, Yu Y. A comparative DFT study on the dehydrogenation of methanol on Rh(100) and Rh(110). Applied Surface Science, 2018, 436: 268–276

DOI

41
Orazi V, Bechthold P, Jasen P V, Faccio R, Pronsato M E, González E A. DFT study of methanol adsorption on PtCo(111). Applied Surface Science, 2017, 420: 383–389

DOI

42
Lide D R. CRC Handbook of chemistry and physics: A ready-reference book of chemical and physical data. CRC Press, 2004, 152–155

43
Zhang X, Lu Z, Yang Z. A comparison study of oxygen reduction on the supported Pt, Pd, Au monolayer on WC(0001). Journal of Power Sources, 2016, 321: 163–173

DOI

44
Park H Y, Park I S, Choi B, Lee K S, Jeon T Y, Sung Y E, Yoo S J. Pd nanocrystals on WC as a synergistic electrocatalyst for hydrogen oxidation reactions. Physical Chemistry Chemical Physics, 2013, 15(6): 2125–2130

DOI

45
Miragliotta J, Polizzotti R S, Rabinowitz P, Cameron S D, Hall R B. Ir-visible sum-frequency generation study of methanol adsorption and reaction on Ni(100). Chemical Physics, 1990, 143(1): 123–130

DOI

46
Zhang C J, Hu P. A first principles study of methanol decomposition on Pd(111): Mechanisms for O–H bond scission and C–O bond scission. Journal of Chemical Physics, 2001, 115(15): 7182–7186

DOI

47
Desai S K, Neurock M, Kourtakis K. A periodic density functional theory study of the dehydrogenation of methanol over Pt(111). Journal of Physical Chemistry B, 2002, 106(10): 2559–2568

DOI

48
Gates J A, Kesmodel L L. Methanol adsorption and decomposition on clean and oxygen precovered palladium (111). Journal of Catalysis, 1983, 83(2): 437–445

DOI

49
Yang H, Whitten J L. Adsorption of formyl on Ni(100). Langmuir, 1995, 11(3): 853–859

DOI

50
Chen J J, Jiang Z C, Zhou Y, Chakraborty B R, Winograd N. Spectroscopic studies of methanol decomposition on Pd(111). Surface Science, 1995, 328(3): 248–262

DOI

51
Levis R J, Jiang Z C, Winograd N. Thermal-decomposition of CH3OH adsorbed on Pd(111)—a new reaction pathway involving CH3 formation. Journal of the American Chemical Society, 1989, 111: 4605–4612

DOI

52
Remediakis I N, Abild-Pedersen F, Norskov J K. DFT study of formaldehyde and methanol synthesis from CO and H2 on Ni(111). Journal of Physical Chemistry B, 2004, 108(38): 14535–14540

DOI

53
Kua J, Goddard W A. Oxidation of methanol on 2nd and 3rd row Group VIII transition metals (Pt, Ir, Os, Pd, Rh and Ru): Application to direct methanol fuel cells. Journal of the American Chemical Society, 1999, 121(47): 10928–10941

DOI

54
Jiang R B, Guo W Y, Li M, Lu X Q, Yuan J Y, Shan H H. Dehydrogenation of methanol on Pd(100): Comparison with the results of Pd(111). Physical Chemistry Chemical Physics, 2010, 12(28): 7794–7803

DOI

55
Felter T E, Sowa E C, Vanhove M A. Location of hydrogen adsorbed on palladium(111) studied by low-energy electron-diffraction. Physical Review. B, 1989, 40(2): 891–899

DOI

Options
Outlines

/