David Sporleder scite author profile

The UV photodesorption of molecular oxygen from a reduced TiO 2 (110) single-crystal surface was investigated as a function of photon excitation energy, substrate temperature, and preannealing conditions. A pump-delayedprobe method using pulsed lasers for UV excitation (pump) and VUV ionization (probe) were used in conjunction with time-of-flight mass spectrometry to measure velocity distributions of the desorbing O 2 molecules. The measured velocity distributions exhibit three distinct features, two of which are attributed to prompt desorption resulting in "fast" velocity distributions and one "slow" channel whose average kinetic energy tracks the surface temperature. The latter is assigned to trapping-desorption of photoexcited O 2 * which are trapped in the physisorption well prior to thermal desorption. The velocity distributions show no dependence on photon energy over the range studied (3.45-4.16 eV), consistent with a substrate-mediated, hole-capture desorption mechanism. The observed prompt desorption channels have mean translational energies of ∼0.14 and ∼0.50 eV and are attributed to the photodesorption of two distinct initial states of chemisorbed oxygen. The identities of the chemisorbed initial states associated with oxygen vacancy or interstitial defect sites are discussed in light of previous experimental and theoretical studies of oxygen on reduced TiO 2 (110) surfaces.

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IR and UV Spectroscopy of Vapor-Phase Jet-Cooled Ionic Liquid [emim]⁺[Tf₂N]⁻: Ion Pair Structure and Photodissociation Dynamics

Cooper

Zolot

Boatz

et al. 2013

J. Phys. Chem. A

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Small gas-phase clusters (ion pairs) of the ionic liquid [emim](+)[Tf2N](-) have been generated in a supersonic expansion. Clusters are investigated via UV photofragmentation and time-of-flight mass spectrometry. Spectra between 42,000 and 45,000 cm(-1) reveal dynamical branching between direct dissociation of the ion pair to the cation and anion and to radical species. The IR spectrum between 2800 and 3200 cm(-1) was measured by action spectroscopy. Multiple conformations of the ion pair are found to be present in the molecular beam, leading to broad spectral features, further complicated by hydrogen bonding and Fermi resonances. The measured and theoretical spectra compare well, and the jet-cooled ion pair structures present in the molecular beam are strongly hydrogen bonded "stacked" conformers.

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Final State Distributions of Methyl Photoproducts from the Photooxidation of Acetone on TiO₂(110)

2012

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The UV photooxidation of acetone on a reduced TiO2(110) surface was investigated using a combination of photodesorption and thermal desorption measurements and pump–probe laser detection of gas-phase products. In agreement with earlier studies, acetone adsorbed on TiO2 does not undergo a UV photoreaction unless codosed with molecular oxygen. The only gas-phase photoproducts are methyl radicals originating from fragmentation of the active acetone surface species and photodesorbed molecular oxygen. Postirradiation TPD measurements show that acetate is the primary surface product remaining after photooxidation. The dependence of the methyl radical formation rate on oxygen and thermal pretreatment of the TiO2 surface is consistent with the formation of an acetone–oxygen (diolate) complex involving adsorbed acetone and oxygen adatoms. Pump-delayed-probe laser techniques were used to measure the velocity and translational energy distributions of methyl radicals resulting from fragmentation of the acetone diolate. The observed translational energy distributions are well described by empirical fits involving two components with average energies of 0.19 eV (“fast”) and 0.03 eV (“slow”). The latter are found to be insensitive to surface temperature or preannealing conditions, suggesting that the “fast” and “slow” components represent different final states of methyl radicals originating from fragmentation of a single photoactive species. The methyl kinetic energy distributions were also found to be independent of UV pump energy which is consistent with a substrate-induced process involving thermalized charge carriers, electrons or holes, which transfer to the acetone diolate to induce fragmentation. The results are discussed in terms of probable substrate-induced photoreaction mechanisms and analogous molecular photofragmentation processes.

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Final state distributions of methyl radical desorption from ketone photooxidation on TiO2(110)

Wilson

Sporleder

White

2012

Phys. Chem. Chem. Phys.

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In this work, we report on product energy distributions for methyl radicals produced by UV photooxidation of a set of structurally related carbonyl molecules, R(CO)CH(3) (R = H, CH(3), C(2)H(5), C(6)H(5)), adsorbed on a TiO(2)(110) surface. Specifically, laser pump-probe techniques were used to measure the translational energy distributions of methyl radicals resulting from α-carbon bond cleavage induced by photoexcited charge carriers at the TiO(2) surface. Photoreaction requires the presence of co-adsorbed oxygen and/or background oxygen during UV laser (pump) exposure, which is consistent with the formation of a photoactive oxygen complex, i.e., η(2)-bonded diolate species (R(COO)CH(3)). The methyl translational energy distributions were found to be bimodal for all molecules studied, with "slow" and "fast" dissociation channels. The "fast" methyl channel is attributed to prompt fragmentation of the diolate species following charge transfer at the TiO(2) surface. The average translational energies of the "fast" methyl channels are found to vary with R-substituent and correlate with the mass of the remaining surface fragments, RCO(x) (x =1 or 2). By comparison, the average energies of the "slow" methyl channels do not show any obvious correlation with R-substituent. The apparent correlation of the "fast" methyl translation energies with surface fragment mass is consistent with a simple two-body fragmentation event isolated on the diolate molecule with little coupling to the surface. These results also suggest that the total available energy for methyl fragmentation does not vary significantly with changes in R-substituent and is representative of exit barriers leading to "fast" methyl fragments.

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David Sporleder

Final State Distributions of O₂ Photodesorbed from TiO₂(110)

IR and UV Spectroscopy of Vapor-Phase Jet-Cooled Ionic Liquid [emim]⁺[Tf₂N]⁻: Ion Pair Structure and Photodissociation Dynamics

Final State Distributions of Methyl Photoproducts from the Photooxidation of Acetone on TiO₂(110)

Final state distributions of methyl radical desorption from ketone photooxidation on TiO2(110)

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David Sporleder

Final State Distributions of O2 Photodesorbed from TiO2(110)

IR and UV Spectroscopy of Vapor-Phase Jet-Cooled Ionic Liquid [emim]+[Tf2N]−: Ion Pair Structure and Photodissociation Dynamics

Final State Distributions of Methyl Photoproducts from the Photooxidation of Acetone on TiO2(110)

Final state distributions of methyl radical desorption from ketone photooxidation on TiO2(110)

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Product

Resources

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Final State Distributions of O₂ Photodesorbed from TiO₂(110)

IR and UV Spectroscopy of Vapor-Phase Jet-Cooled Ionic Liquid [emim]⁺[Tf₂N]⁻: Ion Pair Structure and Photodissociation Dynamics

Final State Distributions of Methyl Photoproducts from the Photooxidation of Acetone on TiO₂(110)