Adsorbate coverages and surface reactivity in methanol oxidation over Cu(110): An in situ photoelectron spectroscopy study

Abstract: The adsorbate species present during partial oxidation of methanol on a Cu(110) surface have been investigated in the 10 -5 mbar range with in situ x-ray photoelectron spectroscopy (XPS) and rate measurements. Two reaction intermediates were identified, methoxy with a C 1s binding energy (BE) of 285.4 eV and formate with a C 1s BE of 287.7 eV. The c(2x2) overlayer formed under reaction conditions is assigned to formate. Two states of adsorbed oxygen were found characterized by O 1s BE's of 529.6 and 528.9 eV, … Show more

“…In the energy range where the high-pressure XPS reveals the presence of subsurface oxygen, several other species were detected in the low pressure and low temperature experiments. There is agreement that a peak found at 529.6 eV corresponds to adsorbed oxygen [77,88,89] . Whereas one study qualifies this oxygen as non-reactive [77] another assigns it to high reactivity.…”

“…This assignment should be contrasted with the low pressure studies carried out in-situ [77] , which also summarize the extensive work of static experiments [86,87] in the Cu/O/MeOH system. There is good agreement that at all pressures studied, copper oxide islands at metal surfaces are non-reactive and exhibit a binding energy of the oxygen species of 530.5 eV.…”

“…It is thus of interest to know how the surface of a metallic catalyst responds with different surface phases according to the oxidizing or reducing nature of the gas environment, given by the partial pressures of O 2 and CH 3 OH. It can also be expected that an oscillatory change between oxide and metal, as observed at high pressures [78] and in forced modes at low pressures [77] , may give rise to a spatially inhomogeneous distribution of oxidation states, which could not coexist in thermodynamic equilibrium. In such a situation the usual practice of performing the reaction in a reactor chamber and later transferring, after cooling and evacuation, into the UHV chamber for analysis will not show the correct surface state but rather the equilibrated state [42] produced during evacuation.…”

“…Whereas one study qualifies this oxygen as non-reactive [77] another assigns it to high reactivity. Reactive oxygen should be found at 528.9 eV according to the in-situ low pressure study [77] .…”

“…Copper with its facile redox chemistry between oxide and metal, accessible at low and intermediate pressures [77] , is a suitable system for mechanistic studies of selectivity control. The fact that extensive kinetic oscillations in methanol oxidation were reported is an indication [78] that active Cu may exist both as an oxide and as a metal.…”

Ambient pressure photoelectron spectroscopy: A new tool for surface science and nanotechnology

“…In the energy range where the high-pressure XPS reveals the presence of subsurface oxygen, several other species were detected in the low pressure and low temperature experiments. There is agreement that a peak found at 529.6 eV corresponds to adsorbed oxygen [77,88,89] . Whereas one study qualifies this oxygen as non-reactive [77] another assigns it to high reactivity.…”

“…This assignment should be contrasted with the low pressure studies carried out in-situ [77] , which also summarize the extensive work of static experiments [86,87] in the Cu/O/MeOH system. There is good agreement that at all pressures studied, copper oxide islands at metal surfaces are non-reactive and exhibit a binding energy of the oxygen species of 530.5 eV.…”

“…It is thus of interest to know how the surface of a metallic catalyst responds with different surface phases according to the oxidizing or reducing nature of the gas environment, given by the partial pressures of O 2 and CH 3 OH. It can also be expected that an oscillatory change between oxide and metal, as observed at high pressures [78] and in forced modes at low pressures [77] , may give rise to a spatially inhomogeneous distribution of oxidation states, which could not coexist in thermodynamic equilibrium. In such a situation the usual practice of performing the reaction in a reactor chamber and later transferring, after cooling and evacuation, into the UHV chamber for analysis will not show the correct surface state but rather the equilibrated state [42] produced during evacuation.…”

“…Whereas one study qualifies this oxygen as non-reactive [77] another assigns it to high reactivity. Reactive oxygen should be found at 528.9 eV according to the in-situ low pressure study [77] .…”

“…Copper with its facile redox chemistry between oxide and metal, accessible at low and intermediate pressures [77] , is a suitable system for mechanistic studies of selectivity control. The fact that extensive kinetic oscillations in methanol oxidation were reported is an indication [78] that active Cu may exist both as an oxide and as a metal.…”

Ambient pressure photoelectron spectroscopy: A new tool for surface science and nanotechnology

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