%0 Journal Article %1 Evans1996 %A Evans, J. %A Hayden, B. E. %A Lu, G. %D 1996 %J Surf. Sci. %K Chemisorption, science} {surface %N 1-3 %P 61 - 73 %R DOI: 10.1016/0039-6028(96)00591-2 %T The adsorption of carbon monoxide on TiO2(110) supported palladium %U http://www.sciencedirect.com/science/article/B6TVX-3YGDBN5-G/2/18da26dfe7d68824d6e765b29bff09c5 %V 360 %X Palladium overlayers deposited on TiO2(110) by metal vapour deposition have been investigated using LEED, XPS and FT-RAIRS of adsorbed CO. Low coverages of palladium (<3 ML) deposited at 300 K adsorb CO exclusively in a bridged configuration with a band (B1 at 1990 cm-1) characteristic of CO adsorption on Pd(110) and Pd(100) surfaces. When annealed to 500 K, XPS and LEED indicate the nucleation of Pd particles on which CO adsorbs predominantly as a strongly bound linear species which we associate with edge sites on the Pd particles (L* band at 2085 cm-1). Both bridged and linear CO bands are exhibited as increases in reflectivity at the resonant frequency, indicating the retention of small particle size during the annealing process. Palladium overlayers of intermediate coverages (10-20 ML) deposited at 300 K undergo some nucleation during growth, and adsorbed CO exhibits both absorption and transmission bands in the B1 (1990 cm-1) and B2 (1940 cm-1) regions. The latter is associated with the formation of Pd(111) facets. Highly dispersed Pd particles are produced on annealing at 500 K. This is evidenced by the dominance of transmission bands for adsorbed CO and a significant concentration of edge sites, which accommodate the strongly bound linear species at 300 K. Adsorption of CO at low temperature also allows the identification of the constituent faces of Pd and the conversion of Pd(110)/(100) facets to Pd(111) facets during the annealing process. High coverages of palladium (100 ML) produce only absorption bands in FT-RAIRS of adsorbed CO associated with the Pd facets, but annealing these surfaces also shows a conversion to Pd(111) facets. LEED indicates that at coverages above 10 ML, the palladium particles exhibit (111) facets parallel to the substrate and aligned with the TiO2(110) unit cell, and that this ordering in the particles is enhanced by annealing.

@article{Evans1996, abstract = {Palladium overlayers deposited on TiO2(110) by metal vapour deposition have been investigated using LEED, XPS and FT-RAIRS of adsorbed CO. Low coverages of palladium (<3 ML) deposited at 300 K adsorb CO exclusively in a bridged configuration with a band (B1 at 1990 cm-1) characteristic of CO adsorption on Pd(110) and Pd(100) surfaces. When annealed to 500 K, XPS and LEED indicate the nucleation of Pd particles on which CO adsorbs predominantly as a strongly bound linear species which we associate with edge sites on the Pd particles (L* band at 2085 cm-1). Both bridged and linear CO bands are exhibited as increases in reflectivity at the resonant frequency, indicating the retention of small particle size during the annealing process. Palladium overlayers of intermediate coverages (10-20 ML) deposited at 300 K undergo some nucleation during growth, and adsorbed CO exhibits both absorption and transmission bands in the B1 (1990 cm-1) and B2 (1940 cm-1) regions. The latter is associated with the formation of Pd(111) facets. Highly dispersed Pd particles are produced on annealing at 500 K. This is evidenced by the dominance of transmission bands for adsorbed CO and a significant concentration of edge sites, which accommodate the strongly bound linear species at 300 K. Adsorption of CO at low temperature also allows the identification of the constituent faces of Pd and the conversion of Pd(110)/(100) facets to Pd(111) facets during the annealing process. High coverages of palladium (100 ML) produce only absorption bands in FT-RAIRS of adsorbed CO associated with the Pd facets, but annealing these surfaces also shows a conversion to Pd(111) facets. LEED indicates that at coverages above 10 ML, the palladium particles exhibit (111) facets parallel to the substrate and aligned with the TiO2(110) unit cell, and that this ordering in the particles is enhanced by annealing.}, added-at = {2009-10-30T10:04:05.000+0100}, author = {Evans, J. and Hayden, B. E. and Lu, G.}, biburl = {https://www.bibsonomy.org/bibtex/2956bcdb642901548ee128af52bc1f319/jfischer}, doi = {DOI: 10.1016/0039-6028(96)00591-2}, interhash = {41d4bb6e7de8e860d740d2629b306e4d}, intrahash = {956bcdb642901548ee128af52bc1f319}, issn = {0039-6028}, journal = {Surf. Sci.}, keywords = {Chemisorption, science} {surface}, number = {1-3}, pages = {61 - 73}, timestamp = {2009-10-30T10:04:12.000+0100}, title = {The adsorption of carbon monoxide on TiO2(110) supported palladium}, url = {http://www.sciencedirect.com/science/article/B6TVX-3YGDBN5-G/2/18da26dfe7d68824d6e765b29bff09c5}, volume = 360, year = 1996 }