The effect of fuel utilization on heat and mass transfer within solid oxide fuel cells examined by three-dimensional numerical simulations

Physics & Astronomy

• solid oxide fuel cells 100%
• mass transfer 77%
• heat transfer 66%
• fuel flow 45%
• simulation 32%
• anodes 24%
• operating costs 21%
• heat balance 19%
• potential gradients 18%
• gradients 18%
• convective flow 17%
• conservation equations 16%
• durability 15%
• cells 15%
• thermal stresses 15%
• pressure gradients 14%
• partial pressure 13%
• reaction kinetics 12%
• performance 12%
• depletion 12%
• temperature gradients 12%
• convection 12%
• electrolytes 11%
• flow velocity 11%
• degradation 10%
• current density 10%
• thermodynamics 9%
• conduction 9%
• heat 9%
• electrodes 8%
• hydrogen 8%
• oxygen 8%
• fluids 8%
• gases 7%

Chemical Compounds

• Heat Transfer 92%
• Mass Transfer 71%
• Fuel 70%
• Simulation 54%
• Electrochemical Reaction 32%
• Heat Balance 17%
• Convective Flow 16%
• Models (Physical) 14%
• Mechanical Stress 13%
• Electrochemical Cell Potential 13%
• Partial Pressure 10%
• Flow Kinetics 8%
• Heat 7%
• Current Density 7%
• Anode 7%
• Flow 6%
• Thermodynamics 6%
• Length 6%
• Porosity 6%
• Pressure 6%
• Environment 6%
• Gas 5%
• Hydrogen 5%
• Behavior as Electrode 5%
• Dioxygen 5%

Engineering & Materials Science

• Solid oxide fuel cells (SOFC) 92%
• Mass transfer 76%
• Heat transfer 57%
• Computer simulation 46%
• Anodes 20%
• Partial pressure 12%
• Reaction kinetics 11%
• Pressure gradient 11%
• Thermal gradients 10%
• Thermal stress 10%
• Convection 10%
• Operating costs 10%
• Cells 10%
• Electrolytes 10%
• Current density 10%
• Conservation 10%
• Hot Temperature 10%
• Thermodynamics 9%
• Durability 8%
• Oxygen 8%
• Hydrogen 8%
• Electrodes 8%
• Flow rate 8%
• Degradation 7%
• Fluids 6%
• Gases 6%