| 1 |
Influence of Support Surface Area and Niobium Addition on the Reactivity of Vanadium Catalysts for Propane Oxidative Dehydrogenation
Ruettinger W, Benderly A, Han S, Shen XF, Ding YS, Suib SL
Catalysis Letters, 141(1), 15, 2011 |
| 2 |
Precious metal catalysts supported on ceramic and metal monolithic structures for the hydrogen economy
Farrauto RJ, Liu Y, Ruettinger W, Ilinich O, Shore L, Giroux T
Catalysis Reviews-Science and Engineering, 49(2), 141, 2007 |
| 3 |
Kinetics of the water-gas shift reaction on Pt catalysts supported on alumina and ceria
Phatak AA, Koryabkina N, Rai S, Ratts JL, Ruettinger W, Farrauto RJ, Blau GE, Delgass WN, Ribeiro FH
Catalysis Today, 123(1-4), 224, 2007 |
| 4 |
Cu-Al2O3-CuAl2O4 water-gas shift catalyst for hydrogen production in fuel cell applications: Mechanism of deactivation under start-stop operating conditions
Ilinich O, Ruettinger W, Liu XS, Farrauto R
Journal of Catalysis, 247(1), 112, 2007 |
| 5 |
Mechanism of aging for a Pt/CeO2-ZrO2 water gas shift catalyst
Ruettinger W, Liu XS, Farrauto RJ
Applied Catalysis B: Environmental, 65(1-2), 135, 2006 |
| 6 |
Deactivation of Pt/CeO2 water-gas shift catalysts due to shutdown/startup modes for fuel cell applications
Liu XS, Ruettinger W, Xu XM, Farrauto R
Applied Catalysis B: Environmental, 56(1-2), 69, 2005 |
| 7 |
Monolithic structures as alternatives to particulate catalysts for the reforming of hydrocarbons for hydrogen generation
Giroux T, Hwang S, Liu Y, Ruettinger W, Shore L
Applied Catalysis B: Environmental, 56(1-2), 95, 2005 |
| 8 |
A new generation of water gas shift catalysts for fuel cell applications
Ruettinger W, Ilinich O, Farrauto RJ
Journal of Power Sources, 118(1-2), 61, 2003 |
| 9 |
O-2 evolution from the manganese-oxo cubane core Mn4O46+: A molecular mimic of the photosynthetic water oxidation enzyme?
Ruettinger W, Yagi M, Wolf K, Bernasek S, Dismukes GC
Journal of the American Chemical Society, 122(42), 10353, 2000 |
