| 1 |
Direct utilization status and power generation potential of low-medium temperature hydrothermal geothermal resources in Tianjin, China: A review
An QS, Wang YZ, Zhao J, Luo C, Wang Y
Geothermics, 64, 426, 2016 |
| 2 |
NiCu-Zr0.1Ce0.9O2-delta anode materials for intermediate temperature solid oxide fuel cells using hydrocarbon fuels
Song SD, Han MF, Zhang JQ, Fan H
Journal of Power Sources, 233, 62, 2013 |
| 3 |
Preparation of Cu-Ni/YSZ solid oxide fuel cell anodes using microwave irradiation
Islam S, Hill JM
Journal of Power Sources, 196(11), 5091, 2011 |
| 4 |
Importance of pyrolysis and catalytic decomposition for the direct utilization of methanol in solid oxide fuel cells
Cimenti M, Hill JM
Journal of Power Sources, 195(1), 54, 2010 |
| 5 |
Direct utilization of methanol and ethanol in solid oxide fuel cells using Cu-Co(Ru)/Zr0.35Ce0.65O2-delta anodes
Cimenti M, Hill JM
Journal of Power Sources, 195(13), 3996, 2010 |
| 6 |
Direct utilization of methanol on impregnated Ni/YSZ and Ni-Zr0.35Ce0.65O2/YSZ anodes for solid oxide fuel cells
Cimenti M, Alzate-Restrepo V, Hill JM
Journal of Power Sources, 195(13), 4002, 2010 |
| 7 |
Operation of solid oxide fuel cells on glycerol fuel: A thermodynamic analysis using the Gibbs free energy minimization approach
da Silva AL, Muller IL
Journal of Power Sources, 195(17), 5637, 2010 |
| 8 |
Thermodynamic analysis of solid oxide fuel cells operated with methanol and ethanol under direct utilization, steam reforming, dry reforming or partial oxidation conditions
Cimenti M, Hill JM
Journal of Power Sources, 186(2), 377, 2009 |
| 9 |
Mitigation of carbon deposits formation in intermediate temperature solid oxide fuel cells fed with dry methane by anode doping with barium
La Rosa D, Sin A, Lo Faro M, Monforte G, Antonucci V, Arico AS
Journal of Power Sources, 193(1), 160, 2009 |
| 10 |
Recent developments on anodes for direct fuel utilization in SOFC
Gorte RJ, Vohs JM, McIntosh S
Solid State Ionics, 175(1-4), 1, 2004 |
