Catalytic oxidation of methane over PdO in wire microcalorimetry

Combustion and Flame

Volumn 160, Issue 1, 2013, Pages 149-154

  Zhang, Taichang ^a,d,e   Xin, Yuxuan ^a   Ren, Zhuyin ^b   Qi, Fei ^d   Law, Chung K ^a,c  

^a Princeton University   (United States)

^b UNIVERSITY OF CONNECTICUT   (United States)

^c TSINGHUA UNIVERSITY   (China)

^d UNIVERSITY OF SCIENCE AND TECHNOLOGY OF CHINA   (China)

^e INSTITUTE OF MECHANICS   (China)

Author keywords

Catalytic oxidation; Mechanism; Methane combustion; Pd based catalyst

Indexed keywords

BUOYANT FLOW; CATALYTIC OXIDATION OF METHANE; HEAT RELEASE RATE (HRR); HIGH-TEMPERATURE REGIME; INTERNAL PORES; LOW TEMPERATURES; METHANE COMBUSTION; MICRO-CALORIMETRY; OXIDATIVE ADSORPTION; PD-BASED CATALYST; PORE DIFFUSION; REACTION MECHANISM; RESPONSE SURFACE METHODOLOGY; SATISFACTORY PREDICTIONS; SURFACE LAYERS; TEMPERATURE RANGE; TWO DIMENSIONAL MODEL;

ACTIVATION ENERGY; CALORIMETERS; DESORPTION; GAS ADSORPTION; MECHANISMS; METHANE; OXYGEN; SURFACE REACTIONS; TEMPERATURE; WIRE;

CATALYTIC OXIDATION;

METHANE; PALLADIUM; OXYGEN; PALLADIUM OXIDE; UNCLASSIFIED DRUG;

ADSORPTION; ARTICLE; CATALYST; DESORPTION; DIFFUSION; ENERGY; HIGH TEMPERATURE; LOW TEMPERATURE; MICROCALORIMETRY; OXIDATION; POROSITY; PRIORITY JOURNAL; REACTION ANALYSIS; RESPONSE SURFACE METHOD; SIMULATION; SURFACE PROPERTY; TEMPERATURE DEPENDENCE; HEAT TRANSFER; THERMAL CONDUCTIVITY; THERMODYNAMICS; TRANSITION TEMPERATURE;

EID: 84869088170     PISSN: 00102180     EISSN: 15562921     Source Type: Journal    
DOI: 10.1016/j.combustflame.2012.09.004     Document Type: Article

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