International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC)–Catalytic pollution control for stationary and mobile sources
Foreword
p. 1005-1006
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Influence of gas hourly space velocity on the activity of monolithic catalysts for the simultaneous removal of soot and NOx
p. 1007-1012
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Synthesis of CuO/SBA-15 adsorbents for SOx removal applications, using different impregnation methods
[Synthèse d’adsorbants CuO/SBA-15 par différentes méthodes d’imprégnation, pour le piégeage des SOx]
p. 1013-1029
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Novel intense metallic monolith for automotive applications: Experimental versus numerical studies
p. 1030-1035
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
The influence of poisoning on the deactivation of DeNOx catalysts
[L’influence de l’empoisonnement sur la désactivation des catalyseurs DeNOx]
p. 1036-1048
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
The influence of the modification of carbonaceous materials on their catalytic properties in SCR-NH3. A short review
[L’influence de la modification des matières carbonées sur leurs propriétés catalytiques dans la réaction catalytique sélective par NH3. Un bref aperçu]
p. 1049-1073
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Copper, cobalt and manganese: Modified hydrotalcite materials as catalysts for the selective catalytic reduction of NO with ammonia. The influence of manganese concentration
[Cuivre, cobalt et manganèse : des matériaux modifiés de type hydrotalcite, utilisables comme catalyseurs dans la réduction catalytique sélective de NO par l’ammoniac. L’influence de la concentration en manganèse]
p. 1074-1083
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Identification of by-products issued from the catalytic oxidation of toluene by chemical and biological methods
[Identification de sous-produits de l’oxydation catalytique du toluène par des méthodes chimiques et biologiques]
p. 1084-1093
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Combustion synthesis and properties of nanocrystalline zirconium oxide
p. 1094-1105
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Catalytic activity of layered aluminosilicates for VOC oxidation in the presence of NOx
[L’activité catalytique des phyllosilicates pour l’oxydation de COV en présence de NOx]
p. 1106-1113
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Supported Co–Mn–Al mixed oxides as catalysts for N2O decomposition
p. 1114-1122
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Synthesis of Faujasite type zeolite from low grade Tunisian clay for the removal of heavy metals from aqueous waste by batch process: Kinetic and equilibrium study
[Synthèse d’une zéolithe de type faujasite à partir d’une argile commune tunisienne pour l’élimination des métaux lourds contenus dans des déchets aqueux par un traitement par batch : étude cinétique et de l’équilibre]
p. 1123-1133
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Preliminary selection of clay minerals for the removal of pharmaceuticals, bisphenol A and triclosan in acidic and neutral aqueous solutions
[Sélection préliminaire des minéraux d’argile pour l’élimination des produits pharmaceutiques, du bisphénol A et du triclosan dans les solutions aqueuses acides et neutres]
p. 1134-1142
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Decolorization and mineralization of yellow 5 (E102) by UV/Fe2+/H2O2 process. Optimization of the operational conditions by response surface methodology
p. 1152-1160
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Photo-Fenton oxidation of phenol over a Cu-doped Fe-pillared clay
p. 1161-1169
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Transition metal loaded TiO2 for phenol photo-degradation
p. 1170-1182
International Symposium on Air & Water Pollution Abatement Catalysis (AWPAC) – Catalytic pollution control for stationary and mobile sources
Mercury in atmospheric aerosols: A preliminary case study for the city of Krakow, Poland
p. 1183-1191