| 3 - 16 |
Catalyst deactivation: is it predictable? What to do?
Moulijn JA, van Diepen AE, Kapteijn F |
| 83 - 96 |
Organic chemistry of coke formation
Guisnet M, Magnoux P |
| 117 - 128 |
Modeling of catalyst deactivation
Froment GF |
| 129 - 151 |
Consequences of catalyst deactivation for process design and operation
Sie ST |
| 153 - 160 |
The regeneration of disposal of deactivated heterogeneous catalysts
Trimm DL |
| 161 - 174 |
Deactivation of supported copper metal catalysts for hydrogenation reactions
Twigg MV, Spencer MS |
| 189 - 197 |
Deactivation of high temperature combustion catalysts
Thevenin PO, Ersson AG, Kusar HMJ, Menon PG, Jaras SG |
| 199 - 213 |
Enhancing the stability of porous catalysts with supercritical reaction media
Subramaniam B |
| 215 - 222 |
The effects of sulfur & ceria on the activity of automotive Pd/Rh catalysts
Rabinowitz HN, Tauster SJ, Heck RM |
| 223 - 238 |
Deactivation of palladium on activated carbon in the selective hydrogenolysis of CCl2F2 (CFC-12) into CH2F2 (HFC-32)
Wiersma A, van de Sandt EJAX, Makkee M, Moulijn JA |
| 239 - 245 |
Catalyst deactivation phenomena in styrene production
Meima GR, Menon PG |
| 247 - 255 |
Emission and loss of potassium promoter from styrene catalysts: studies by ultrahigh vacuum/molecular-beam and laser techniques
Holmlid L, Menon PG |
