| 1 |
On the characteristic heating and pyrolysis time of thermally small biomass in a fluidized bed reactor
Soria-Verdugo A, Rubio-Rubio M, Goos E, Riedel U
Renewable Energy, 160, 312, 2020 |
| 2 |
Combining the lumped capacitance method and the simplified distributed activation energy model to describe the pyrolysis of thermally small biomass particles
Soria-Verdugo A, Rubio-Rubio M, Goos E, Riedel U
Energy Conversion and Management, 175, 164, 2018 |
| 3 |
Pyrolysis of biofuels of the future: Sewage sludge and microalgae -Thermogravimetric analysis and modelling of the pyrolysis under different temperature conditions
Soria-Verdugo A, Goos E, Morato-Godino A, Garcia-Hernando N, Riedel U
Energy Conversion and Management, 138, 261, 2017 |
| 4 |
Modeling of the pyrolysis of biomass under parabolic and exponential temperature increases using the Distributed Activation Energy Model
Soria-Verdugo A, Goos E, Arrieta-Sanagustin J, Garcia-Hernando N
Energy Conversion and Management, 118, 223, 2016 |
| 5 |
Effect of the number of TGA curves employed on the biomass pyrolysis kinetics results obtained using the Distributed Activation Energy Model
Soria-Verdugo A, Goos E, Garcia-Hernando N
Fuel Processing Technology, 134, 360, 2015 |
| 6 |
A sectional approach for biomass: Modelling the pyrolysis of cellulose
Lin T, Goos E, Riedel U
Fuel Processing Technology, 115, 246, 2013 |
| 7 |
Inhibition of hydrogen oxidation by HBr and Br-2
Dixon-Lewis G, Marshall P, Ruscic B, Burcat A, Goos E, Cuoci A, Frassoldati A, Faravelli T, Glarborg P
Combustion and Flame, 159(2), 528, 2012 |
| 8 |
Reaction kinetics of CO+HO2 -> products: Ab initio transition state theory study with master equation modeling
You XQ, Wang H, Goos E, Sung CJ, Klippenstein SJ
Journal of Physical Chemistry A, 111(19), 4031, 2007 |
