| 1 |
Structural and surface changes of cobalt modified manganese oxide during activation and ethanol steam reforming reaction
Gac W, Greluk M, Slowik G, Turczyniak-Surdacka S
Applied Surface Science, 440, 1047, 2018 |
| 2 |
Electro-catalytic conversion of ethanol in solid electrolyte cells for distributed hydrogen generation
Ju H, Giddey S, Badwal SPS, Mulder RJ
Electrochimica Acta, 212, 744, 2016 |
| 3 |
Renewable hydrogen production concepts from bioethanol reforming with carbon capture
Cormos CC
International Journal of Hydrogen Energy, 39(11), 5597, 2014 |
| 4 |
A comparative study on energetic and exergetic assessment of hydrogen production from bioethanol via steam reforming, partial oxidation and auto-thermal reforming processes
Khila Z, Hajjaji N, Pons MN, Renaudin V, Houas A
Fuel Processing Technology, 112, 19, 2013 |
| 5 |
Analysis of the control structures for an integrated ethanol processor for proton exchange membrane fuel cell systems
Biset S, Deglioumini LN, Basualdo M, Garcia VM, Serra M
Journal of Power Sources, 192(1), 107, 2009 |
| 6 |
The role of surface reactions on the active and selective catalyst design for bioethanol steam reforming
Benito M, Padilla R, Serrano-Lotina A, Rodriguez L, Brey JJ, Daza L
Journal of Power Sources, 192(1), 158, 2009 |
| 7 |
Zirconia supported catalysts for bioethanol steam reforming: Effect of active phase and zirconia structure
Benito M, Padilla R, Rodriguez L, Sanz JL, Daza L
Journal of Power Sources, 169(1), 167, 2007 |
| 8 |
The use of industrial dehydrogenation catalysts for hydrogen production from bioethanol
Dolgykh L, Stolyarchuk I, Deynega I, Strizhak P
International Journal of Hydrogen Energy, 31(11), 1607, 2006 |
