M. Hupa, O. Karlström, E. Vainio, "Biomass combustion technology development – It is all about chemical details”, Proceedings of the Combustion Institute vol. 36 pp. 113-134, 2017.
 J. F. González, C. M. González-García, A. Ramiro, J. González, E. Sabio, J. Gañán, M. A. Rodríguez, “Combustion optimisation of biomass residue pellets for domestic heating with a mural boiler”, Biomass & Bioenergy vol. 27 pp. 145-154, 2004.
 T. Miranda, A. Esteban, S. Rojas, I. Montero, A. Ruiz, “Combustion Analysis of Different Olive Residues”, International Journal of Molecular Sciences vol. 9 pp. 512-525, 2008.
 F. J. Gómez-de la Cruz, P. J. Casanova-Peláez, J. M. Palomar-Carnicero, F. Cruz-Peragón, “Drying kinetics of olive stone: A valuable source of biomass obtained in the olive oil extraction”, Energy vol. 75 pp. 146-152, 2014.
 F. F. Costa, G. Wang, M. Costa, “Combustion kinetics and particle fragmentation of raw and torrified pine shells and olive stones in a drop tube furnace”, Proceedings of the Combustion Institute vol. 35 pp. 3591-3599, 2015.
 H. Thunman, B. Leckner, F. Niklasson, F. Johnsson, “Combustion of wood particles – A particle model for Eulerian calculations”, Combustion and Flame vol. 129 pp. 30-46, 2002.
 Y. Haseli, J.A. van Oijen, L.P.H. de Goey, “A detailed one-dimensional model of combustion of a woody biomass particle”, Bioresource Technology vol. 102 pp. 9772-9782, 2011.
 X. Jiang, D. Chen, Z. Ma, J. Yan, “Models for the combustion of single solid fuel particles in fluidized beds: A review”, Renewable and Sustainable Energy Reviews vol. 68 pp. 410-431, 2017.
 J. Porteiro, J. L. Míguez, E. Granada, J.C. Moran, “Mathematical modelling of the combustion of a single wood particle”, Fuel Processing Technology vol. 87 pp. 169-175, 2006.
 J. Porteiro, E. Granada, J. Collazo, D. Patiño, J.C. Morán, “A model for the combustion of large particles of densified wood”, Energy & Fuels vol. 21 pp. 3151-3159, 2007.
 A. Soria-Verdugo, E. Goos, J. Arrieta-Sanagustín, N. Garcia-Hernando, “Modeling of the pyrolysis of biomass under parabolic and exponential temperature increases using the Distributed Activation Energy Model”, Energy Conversion and Management vol. 118 pp. 223-230, 2016.
 A. Soria-Verdugo, E. Goos, N. Garcia-Hernando, U. Riedel, “Analyzing the pyrolysis kinetics of several microalgae species by various differential and integral isoconversional kinetic methods and the Distributed Activation Energy Model”, Energy Conversion and Management vol. 32 pp. 11-29, 2018.
 A. Soria-Verdugo, M. Rubio-Rubio, E. Goos, U. Riedel, “Combining the Lumped Capacitance Method and the simplified Distributed Activation Energy Model to describe the pyrolysis of thermally small biomass particles”, Energy Conversion and Management vol. 175 pp. 164-172, 2018.
 A. Soria-Verdugo, A. Morato-Godino, L. M. García-Gutiérrez, N. García-Hernando, “Pyrolysis of sewage sludge in a fixed and a bubbling fluidized bed – Estimation and experimental validation of the pyrolysis time”, Energy Conversion and Management vol. 144 pp. 235-242, 2017.
 A. Morato-Godino, S. Sánchez-Delgado, N. García-Hernando, A. Soria-Verdugo, “Pyrolysis of Cynara cardunculus L. samples – Effect of operating conditions and bed stage on the evolution of the conversion”, Chemical Engineering Journal vol. 351, pp. 371-381, 2018.
 D. Geldart, “Types of gas fluidization”, Powder Technology vol. 7 pp. 285-292, 1973.
 D. Kunii, O. Levenspiel, “Fluidization Engineering”, 2nd edition, Butterworth-Heinemann, Boston, 1991.
 P.C. Carman, “Fluid flow through granular beds”, Transactions of the Institute of Chemical Engineers vol. 15 pp. 150-166, 1937.
 J. Sánchez-Prieto, A. Soria-Verdugo, J. V. Briongos, D. Santana, “The effect of temperature on the distributor design in bubbling fluidized beds”, Powder Technology vol. 261 pp. 176–184, 2014.