Methanol decomposition over palladium particles supported on silica: Role of particle size and co-feeding carbon dioxide on the catalytic properties

ACS Catalysis

Volumn 2, Issue 6, 2012, Pages 1013-1019

  Hokenek, Selma ^a   Kuhn, John N ^a  

^a UNIVERSITY OF SOUTH FLORIDA   (United States)

Author keywords

methanol catalysis; nanoparticle growth; nucleation; product poisoning; structure sensitivity

Indexed keywords

CATALYTIC DEACTIVATION; CATALYTIC PROPERTIES; CO-FEEDING; CONTROLLED SIZE; HIGH OXIDATION STATE; INTRINSIC ACTIVITIES; LOW OXIDATION STATE; METHANOL DECOMPOSITION; MOLAR RATIO; MONODISPERSE; NANOPARTICLE GROWTHS; NUCLEATION RATE; ONE POT; OXIDATION STATE; PALLADIUM PARTICLES; PALLADIUM PRECURSORS; PD PARTICLE; POLYOL PROCESS; RATE-LIMITING STEPS; REACTION MECHANISM; SIZE CONTROL; STRUCTURE SENSITIVITY; STRUCTURE-SENSITIVE; SUPPORTED ON SILICA; TURNOVER FREQUENCY;

CARBON DIOXIDE; CARBON MONOXIDE; NUCLEATION; OXIDATION; SILICA; X RAY ABSORPTION SPECTROSCOPY;

METHANOL;

EID: 84861801817     PISSN: 21555435     EISSN: None     Source Type: Journal    
DOI: 10.1021/cs200689k     Document Type: Article

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