Strained thin copper films as model catalysts in the materials gap

Research output: Contribution to journalArticleResearchpeer review

Authors

  • F. Girgsdies
  • T. Ressler
  • U. Wild
  • T. Wübben
  • T. J. Balk
  • G. Dehm
  • L. Zhou
  • S. Günther
  • E. Arzt
  • R. Imbihl
  • R. Schlögl

Research Organisations

External Research Organisations

  • Fritz Haber Institute of the Max Planck Society (FHI)
  • Max Planck Institute for Intelligent Systems
  • Ludwig-Maximilians-Universität München (LMU)
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Details

Original languageEnglish
Pages (from-to)91-97
Number of pages7
JournalCatalysis letters
Volume102
Issue number1-2
Publication statusPublished - Jul 2005

Abstract

Thin copper films on silicon constitute model systems to investigate the influence of lattice strain on activity in heterogeneous catalysis. Thin copper films on silicon were investigated by ultraviolet photoelectron spectroscopy (UPS) to reveal the effect of strain in the copper films on the electronic structure of the surface. For cleaned and adsorbate-free surfaces, no effect of strain on the electronic structure was detected by UPS. Conversely, an oxygen-containing film exhibited a distinct effect of strain induced by cyclic heating and cooling on the electronic structure. Comparison with studies on a Cu single crystal under methanol oxidation reaction conditions revealed a characteristic hysteresis behavior in both the adsorbate structure and the catalytic properties of the metal surface. Hence, copper model systems that are suitable to unravel the correlation between strain and catalytic activity need to take the disordered microstructure of "real" copper catalysts into account. The present experiments reveal the correlation between surface restructuring and catalysis on the one side and the influence of lattice strain on either restructuring or the electronic structure of the surface on the other side.

Keywords

    Copper, Methanol steam reforming, Methanol synthesis, Model system, Real structure, Strain, Structure-activity relationships

ASJC Scopus subject areas

Cite this

Strained thin copper films as model catalysts in the materials gap. / Girgsdies, F.; Ressler, T.; Wild, U. et al.
In: Catalysis letters, Vol. 102, No. 1-2, 07.2005, p. 91-97.

Research output: Contribution to journalArticleResearchpeer review

Girgsdies, F, Ressler, T, Wild, U, Wübben, T, Balk, TJ, Dehm, G, Zhou, L, Günther, S, Arzt, E, Imbihl, R & Schlögl, R 2005, 'Strained thin copper films as model catalysts in the materials gap', Catalysis letters, vol. 102, no. 1-2, pp. 91-97. https://doi.org/10.1007/s10562-005-5208-4
Girgsdies, F., Ressler, T., Wild, U., Wübben, T., Balk, T. J., Dehm, G., Zhou, L., Günther, S., Arzt, E., Imbihl, R., & Schlögl, R. (2005). Strained thin copper films as model catalysts in the materials gap. Catalysis letters, 102(1-2), 91-97. https://doi.org/10.1007/s10562-005-5208-4
Girgsdies F, Ressler T, Wild U, Wübben T, Balk TJ, Dehm G et al. Strained thin copper films as model catalysts in the materials gap. Catalysis letters. 2005 Jul;102(1-2):91-97. doi: 10.1007/s10562-005-5208-4
Girgsdies, F. ; Ressler, T. ; Wild, U. et al. / Strained thin copper films as model catalysts in the materials gap. In: Catalysis letters. 2005 ; Vol. 102, No. 1-2. pp. 91-97.
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AU - Ressler, T.

AU - Wild, U.

AU - Wübben, T.

AU - Balk, T. J.

AU - Dehm, G.

AU - Zhou, L.

AU - Günther, S.

AU - Arzt, E.

AU - Imbihl, R.

AU - Schlögl, R.

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N2 - Thin copper films on silicon constitute model systems to investigate the influence of lattice strain on activity in heterogeneous catalysis. Thin copper films on silicon were investigated by ultraviolet photoelectron spectroscopy (UPS) to reveal the effect of strain in the copper films on the electronic structure of the surface. For cleaned and adsorbate-free surfaces, no effect of strain on the electronic structure was detected by UPS. Conversely, an oxygen-containing film exhibited a distinct effect of strain induced by cyclic heating and cooling on the electronic structure. Comparison with studies on a Cu single crystal under methanol oxidation reaction conditions revealed a characteristic hysteresis behavior in both the adsorbate structure and the catalytic properties of the metal surface. Hence, copper model systems that are suitable to unravel the correlation between strain and catalytic activity need to take the disordered microstructure of "real" copper catalysts into account. The present experiments reveal the correlation between surface restructuring and catalysis on the one side and the influence of lattice strain on either restructuring or the electronic structure of the surface on the other side.

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