Eldad Herceg scite author profile

Reflection absorption infrared spectroscopy (RAIRS) and temperature-programmed desorption (TPD) were used to identify the molecular species formed upon the reaction of hydrogen with surface carbon that is deposited by exposing acetylene to a Pt(111) surface held at 750 K. At this temperature, the acetylene is completely dehydrogenated and all hydrogen is desorbed from the surface. Upon subsequent hydrogen exposure at 85 K followed by sequential annealing to higher temperatures, ethylidyne (CCH3), ethynyl (CCH), and methylidyne (CH) are formed. The observation of these species indicates that carbon atoms and C2 molecules exist as stable species on the surface over a wide range of temperatures. Through a combination of RAIRS intensities, hydrogen TPD peak areas, and Auger electron spectroscopy, quantitative estimates of the coverages of the various species were obtained. It was found that 79% of the acetylene-derived carbon was in the form of C2 molecules, with the remainder in the form of carbon atoms. Essentially all of the acetylene-derived carbon could be hydrogenated. In contrast, 85% of an equivalent coverage of carbon deposited by ethylene exposure at 750 K was found to be inert toward hydrogenation.

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Reversible Hydrogenation of Surface N Atoms To Form NH on Pt(111)

Herceg

Mudiyanselage

Trenary

2005

J. Phys. Chem. B

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The formation and dissociation chemistry of the NH species on Pt(111) was characterized with reflection absorption infrared spectroscopy and temperature programmed desorption. Irradiation of a chemisorbed bilayer of ammonia with a 100 eV electron beam at 85 K leads to a mixture of NH, N, and H on the surface. Annealing to temperatures in the range of 200-300 K leads to reaction of N and H to form additional NH. The NH species has an intense and narrow NH stretch peak at 3320 cm(-1), while no peak due to the PtNH bend is observed above 800 cm(-1). The NH species is stable up to a temperature of approximately 400 K. The surface N atoms produced from NH dissociation are readily hydrogenated back to NH by exposure of the surface to H2. However, NH cannot be further hydrogenated to generate adsorbed NH2 or to NH3 under the conditions used here. Exposure of the NH/Pt(111) surface to D2 at 380 K produces the ND species. Comparison with the results of density functional theory calculations based on small Pt clusters indicates that NH occupies three-fold hollow sites with the molecular axis perpendicular to the surface.

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Eldad Herceg

Formation and hydrogenation of ethylidene on the Pt(111) surface

Characterization of methylidyne on Pt(111) with infrared spectroscopy

Formation and hydrogenation of p(2×2)-N on Pt(111)

Identification and Hydrogenation of C₂ on Pt(111)

Reversible Hydrogenation of Surface N Atoms To Form NH on Pt(111)

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Eldad Herceg

Formation and hydrogenation of ethylidene on the Pt(111) surface

Characterization of methylidyne on Pt(111) with infrared spectroscopy

Formation and hydrogenation of p(2×2)-N on Pt(111)

Identification and Hydrogenation of C2 on Pt(111)

Reversible Hydrogenation of Surface N Atoms To Form NH on Pt(111)

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Product

Resources

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Identification and Hydrogenation of C₂ on Pt(111)