| 223 - 224 |
Catalyst Deactivation by Coke Formation - Foreword
Hughes R, Santamaria J, Monzon A |
| 225 - 232 |
Industrial Relevance of Coking
Rostrupnielsen JR |
| 233 - 238 |
Coke Formation and Minimization During Steam Reforming Reactions
Trimm DL |
| 239 - 248 |
Catalyst Deactivation by Coking in the Mtg Process in Fixed and Fluidized-Bed Reactors
Aguayo AT, Gayubo AG, Ortega JM, Olazar M, Bilbao J |
| 249 - 253 |
Analysis of Coupled Deactivation Effects - Interaction of Sodium and Coke in Cracking over Zeolites
Liu Z, Dadyburjor DB |
| 255 - 265 |
Deactivation by Coking and Poisoning of Spinel-Type Ni Catalysts
Rodriguez JC, Romeo E, Fierro JL, Santamaria J, Monzon A |
| 267 - 275 |
Effect of Nitrogen-Compounds on Deactivation of Hydrotreating Catalysts by Coke
Dong D, Jeong S, Massoth FE |
| 277 - 283 |
Coke Characterization by Temperature-Programmed Techniques
Querini CA, Fung SC |
| 285 - 293 |
Structural Characterization of Catalytic Coke by Solid-State C-13-NMR Spectroscopy
Snape CE, Mcghee BJ, Martin SC, Andresen JM |
| 295 - 307 |
The Effect of Copper on the Structural Characteristics of Carbon Filaments Produced from Iron-Catalyzed Decomposition of Ethylene
Krishnankutty N, Park C, Rodriguez NM, Baker RT |
| 309 - 329 |
The Role of Coke Formation in Catalytic Partial Oxidation for Synthesis Gas-Production
Degroote AM, Froment GF |
| 331 - 349 |
Catalyst Deactivation by Coke Deposition - Approaches Based on Interactions of Coke Laydown with Pore Structure
Mann R |
