This paper concerns the development of an innovative LiCrO2 catalyst (synthesis, characterization, mechanistic analysis, and aging). This catalyst already showed appreciable activity at 300 °C toward the catalytic combustion of soot even under loose contact conditions. Furthermore, its limited sensitivity to hydrothermal aging in the presence of SO2 at 650 °C demonstrated a favorable result for its possible application in catalytic traps for diesel particulate removal from car exhaust gases. In this perspective, an in situ combustion synthesis method was tailored to the preparation of a LiCrO2-catalyzed trap based on a SiC wall-flow monolith. Engine bench tests on this catalytic trap (trap loading and regeneration inducing a temperature increase by the catalytic combustion of suitably postinjected fuel) showed that the presence of the catalyst in the wall-flow trap enabled both a more complete regeneration and a 2-fold reduction of the regeneration time compared to the case of a noncatalytic trap, with the consequent saving of postinjected fuel.
N2O catalytic decomposition over various spinel-type oxides / Russo, Nunzio; Fino, Debora; Saracco, Guido; Specchia, Vito. - In: CATALYSIS TODAY. - ISSN 0920-5861. - 119:(2007), pp. 228-232.
N2O catalytic decomposition over various spinel-type oxides
RUSSO, Nunzio;FINO, DEBORA;SARACCO, GUIDO;SPECCHIA, Vito
2007
Abstract
This paper concerns the development of an innovative LiCrO2 catalyst (synthesis, characterization, mechanistic analysis, and aging). This catalyst already showed appreciable activity at 300 °C toward the catalytic combustion of soot even under loose contact conditions. Furthermore, its limited sensitivity to hydrothermal aging in the presence of SO2 at 650 °C demonstrated a favorable result for its possible application in catalytic traps for diesel particulate removal from car exhaust gases. In this perspective, an in situ combustion synthesis method was tailored to the preparation of a LiCrO2-catalyzed trap based on a SiC wall-flow monolith. Engine bench tests on this catalytic trap (trap loading and regeneration inducing a temperature increase by the catalytic combustion of suitably postinjected fuel) showed that the presence of the catalyst in the wall-flow trap enabled both a more complete regeneration and a 2-fold reduction of the regeneration time compared to the case of a noncatalytic trap, with the consequent saving of postinjected fuel.Pubblicazioni consigliate
I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
https://hdl.handle.net/11583/1485279
Attenzione
Attenzione! I dati visualizzati non sono stati sottoposti a validazione da parte dell'ateneo