Solar-blind ultraviolet photodetection of an α-Ga<sub>2</sub>O<sub>3</sub> nanorod array based on photoelectrochemical self-powered detectors with a simple, newly-designed structure

The present study is dedicated to an experimental microkinetic approach of the catalyst oxidation of the diesel soot using a filter coated with ceria. To mimic the situation encountered in this process, mechanical ceria/soot mixtures have been prepared according to the tight and loose contact concepts described in the literature with ceria/soot ratio R > 1. Diesel soots prepared on an engine test bench and commercial soot have been used. The evolution of the ceria/soot contacts (via the amount of oxygen transferred from ceria to soot) with the progressive oxidation of the soot is followed using temperature-programmed experiments (denoted as TPEs) that provide the rate of CO2 and CO productions [denoted as R CO2 (T) and R CO(T)] during the increase in the temperature in helium in the range of 300−1100 K. During the first TPE, different surface processes implying pure soot and ceria contribute to R CO2 (T) and R CO(T), making the evaluation of the oxygen transfer difficult. It is shown that these difficulties are suppressed by performing, on the same ceria/soot sample, successive cycles constituted by a TPE followed by adsorption of O2 at 300 K that leads to the progressive oxidation of the soot. After three cycles, it is shown that, whatever the ceria/soot mixtures, the amount of oxygen that can be transferred from ceria to soot remains constant. This indicates that the ceria/soot surface contacts do not change during the soot oxidation, which is a conclusion consistent with recent literature data on environmental transmission electron microscopy (TEM). However, the amount of oxygen provided by ceria and available for the soot oxidation is dependent upon the type of ceria/soot mixtures, and this controls the performances of the catalyst evaluated by the decrease of the light-off temperature of the soot in a flow rate of 30% O2/He. These conclusions are used in part 2 (10.1021/ef100582w) to provide a detailed kinetic modeling of the TPE experiments for the different ceria/soot mixtures, focusing on the key role of the ceria/soot contacts on the rate of soot oxidation. This provides a consistent formalism to understand the impact of the types of catalyst/soot mixtures on the performances.

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High-throughput approach to the catalytic combustion of diesel soot II: Screening of oxide-based catalysts

Bassou

Guilhaume

Iojoiu

et al. 2011

Catalysis Today

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High-throughput approach to the catalytic combustion of diesel soot

et al. 2008

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Heats of Adsorption of Linear and Bridged CO Species Adsorbed on a 3% Ag/Al₂O₃Catalyst Using in situ FTIR Spectroscopy under Adsorption Equilibrium

et al. 2007

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The heats of adsorption of linear and bridged CO species adsorbed on Ag0 sites of a reduced 3% Ag/Al2O3 catalyst and of the linear CO species on Ag+ sites of the oxidized catalyst are determined as the function of their respective coverages by using the adsorption equilibrium infrared spectroscopy method previously developed. The evolutions of the intensities of the IR bands of each adsorbed species: 2045 cm-1 and 2000 cm-1 at 300 K, for the linear and bridged CO species, respectively, on Ag0 sites of the reduced solid and 2168 cm-1 for a linear CO species on Ag+ sites of the oxidized solid are determined as a function of the adsorption temperature T a, at a constant CO adsorption pressure P CO. This provides the evolutions of the coverages of each adsorbed CO species with T a in isobar conditions that give the individual heats of adsorption of the three adsorbed CO species at several coverages according to an adsorption model. The heats of adsorption of the linear and bridged adsorbed CO species on Ag0 sites vary linearly with their coverages : from E 0 = 76 kJ/mol to E 1 = 58 kJ/mol for the linear CO species and from E 0 = 88 kJ/mol to E 1 = 84 kJ/mol for the bridged CO species at coverages 0 and 1, respectively. Volumetric measurements indicate that the total amount of the adsorbed CO species represents a small fraction of the superficial sites of the reduced Ag particles suggesting that they are adsorbed on defect sites. The heat of adsorption of the linear CO species on the Ag+ sites linearly varies with its coverage from E 0 = 66 kJ/mol to E 1 = 41 kJ/mol at coverages 0 and 1, respectively.

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Karine Lombaert

Experimental Microkinetic Approach of the Catalytic Oxidation of Diesel Soot by Ceria Using Temperature-Programmed Experiments. Part 1: Impact and Evolution of the Ceria/Soot Contacts during Soot Oxidation

High-throughput approach to the catalytic combustion of diesel soot II: Screening of oxide-based catalysts

High-throughput approach to the catalytic combustion of diesel soot

Heats of Adsorption of Linear and Bridged CO Species Adsorbed on a 3% Ag/Al₂O₃Catalyst Using in situ FTIR Spectroscopy under Adsorption Equilibrium

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Karine Lombaert

Experimental Microkinetic Approach of the Catalytic Oxidation of Diesel Soot by Ceria Using Temperature-Programmed Experiments. Part 1: Impact and Evolution of the Ceria/Soot Contacts during Soot Oxidation

High-throughput approach to the catalytic combustion of diesel soot II: Screening of oxide-based catalysts

High-throughput approach to the catalytic combustion of diesel soot

Heats of Adsorption of Linear and Bridged CO Species Adsorbed on a 3% Ag/Al2O3Catalyst Using in situ FTIR Spectroscopy under Adsorption Equilibrium

Contact Info

Product

Resources

About

Heats of Adsorption of Linear and Bridged CO Species Adsorbed on a 3% Ag/Al₂O₃Catalyst Using in situ FTIR Spectroscopy under Adsorption Equilibrium