Production scientifique 2016-2021

Dans cette catégorie :

1. K. Meerpoel-Pietri, V. Tihay-Felicelli, P.A. Santoni, Determination of the critical conditions leading to the ignition of decking slabs by flaming firebrands, Fire Safety Journal, 120 (2021) 103017 https://doi.org/10.1016/j.firesaf.2020.103017
2. L. Ferrat, F. Morandini, G. Lapa, Influence of Prescribed Burning on a Pinus nigra subsp. Laricio Forest: Heat Transfer and Tree Vitality, Forests, 12(7) (2021) 915, https://doi.org/10.3390/f12070915
3. J.F. Ciprián-Sánchez, G. Ochoa-Ruiz, L. Rossi, F. Morandini, Assessing the impact of the loss function, architecture and image type for deep learning-based wildfire segmentation, Applied Sciences (Switzerland), 11 (15) (2021), 7046 https://doi.org/10.3390/app11157046
4. F. Ciprián-Sánchez, G. Ochoa-Ruiz, M. Gonzalez-Mendoza, L. Rossi, F. FIRe-GAN: a novel deep learning-based infrared-visible fusion method for wildfire imagery Neural Computing and Applicationsthis link is disabled Neural Computing and Applicationsthis (2021)
5. N. Frangieh, G. Accary, J.L. Rossi, D. Morvan, S. Meradji, T. Marcelli, F.J. Chatelon, Fuelbreak effectiveness against wind-driven and plume-dominated fires: A 3D numerical study, Fire Safety Journal, 124, 103383, (2021) https://doi.org/10.1016/j.firesaf.2021.103383
6. V. Leroy-Cancellieri, D. Cancellieri, E. Leoni, Characterization of pahs trapped in the soot from the combustion of various mediterranean species, Atmospherethis, 12(8), 965, (2021)
7. F. Allaire, V. Mallet, J.B. Filippi, Emulation of wildland fire spread simulation using deep learning Neural Networksthis link is disabled, 141, 184–198, (2021) https://doi.org/10.3390/atmos12080965
8. F. Allaire, V. Mallet, J.B. Filippi, Novel method for a posteriori uncertainty quantification in wildland fire spread simulation, Applied Mathematical Modellingthis, 90, 527–546 (2021) https://doi.org/10.1016/j.apm.2020.08.040
9. J.B. Filippi, J. Durand, P. Tulet, S. Bielli, Multiscale modeling of convection and pollutant transport associated with volcanic eruption and lava flow: Application to the april 2007 eruption of the piton de la fournaise (Reunion Island), Atmosphere, 12(4), 507, (2021) https://doi.org/10.3390/atmos12040507
10. C.Awad, N. Frangieh, T. Marcelli, G. Accary, D. Morvan, S. Meradji, F.J.  Chatelon, J.L. Rossi, Numerical study of the moisture content threshold under prescribed burning conditions, fire Safety, 122, 103324, (2021) https://doi.org/10.1016/j.firesaf.2021.103324

1. F. Allaire, J.B. Filippi, V. Mallet Generation and evaluation of an ensemble of wildland fire simulations. International Journal of Wildland Fire, 29(2), 160-173 (2020).
2. T. Barboni, L. Leonelli, P.A. Santoni, V. Tihay-Felicelli Aerosols and carbonaceous and nitrogenous compounds emitted during the combustion of dead shrubs according to twigs’ diameter and combustion phases, Fire Safety Journal, 113, 102988 (2020).
3. K. Meerpoel-Pietri, V. Tihay-Felicelli, P.A. Santoni Determination of the critical conditions leading to the ignition of decking slabs by flaming firebrands, Fire Safety Journal, 103017 (2020).
4. J.H. Balbi, F.J Chatelon, D. Morvan, J.L. Rossi, T. Marcelli, F. Morandini A convective–radiative propagation model for wildland fires. Int. J. Wildl. Fire, 29, 723–738, doi:10.1071/WF19103 (2020).
5. C. Awad, D. Morvan, J.L. Rossi, T. Marcelli, F.J. Chatelon, F. Morandini, J.H. Balbi. Fuel moisture content threshold leading to fire extinction under marginal conditions, Fire Safety Journal, Volume 18, 103226 (2020).
6. F. Allaire, V. Mallet, J.B. Filippi Novel method for a posteriori uncertainty quantification in wildland fire spread simulation Applied Mathematical Modelling (In Press), (2020).
7. V. Ciullo, L. Rossi, A. Pieri. Experimetal Fire measurement with UAV multimodal Stereovision, Remote Sens. 12, 3546; doi:10.3390/rs12213546 (2020).

1. Clements, CB, Kochanski, AK, Seto, D, Davis, B, Camacho, C, Lareau, NP, Contezac, J, Restaino, J, Heilman, WE, Krueger, SK, Butler, B, Ottmar, RD, Vihnanek, R, Flynn, J, Filippi, JB, Barboni, T, Hall, DE, Mandel, J, Jenkins, MA, O’Brien, J, Hornsby, B et Teske, C. The FireFlux II experiment: a model-guided field experiment to improve understanding of fire–atmosphere interactions and fire spread. International Journal of Wildland Fire, 28 :308, (2019).
2. Kokubu, Y, Rotha?usler, E, Filippi, JB, Durieux, EDH et Komatsu, T. Revealing the deposition of macrophytes transported offshore: Evidence of their long-distance dispersal and seasonal aggregation to the deep sea. Scientific Reports mar,9 (2019).
3. G. Gerandi, V. Tihay-Felicelli, P.A. Santoni, V. Leroy, D. Cancellieri, Multi-scale modeling of the degradation of thermally thin wood plates, Fire Safety Journal, 108, 102823, 1-13 (2019).
4. F. Morandini, P.A. Santoni, J.B. Tramoni, W.E. Mell, Experimental investigation of flammability and numerical study of combustion of shrub of rockrose under severe drought conditions, Fire Safety Journal, 108, 102836, 1-16 (2019).
5. T. Barboni, L. Leonelli, P.A. Santoni, V. Tihay-Felicelli, Study of the burning of Pteridium aquilinum L. and risk for the personnel involved: Thermal properties and chemical risk, online, 110 102904 (2019).
6. Migliorini M, Hagen JS, Mihaljevi? J, Mysiak J, Rossi J-L, Siegmund A, Meliksetian K, Guha Sapir D (2019) Data interoperability for disaster risk reduction in Europe. Disaster Prevention and Management: An International Journal 28, 796–808. doi:10.1108/DPM-09-2019-0291 (2019).
7. M. Salis, B. Arca, F. Alcasena-Urdiroz, V. Bacciu, A. Massaiu, F. Bosseur, P. Caramelle, D. Molina-Terren, P.A. Santoni, C. Vega-Garcia, S. Dettori, D. Spano, P. Duce, Recent dynamics of wildland fires in Quercus suber L. woodlands in Sardinia, Corsica and Catalonia, European Journal of Forest Research 138(3) 415-431 (2019).

1. D. Cancellieri, V. Leroy-Cancellieri, X. Silvani, F. Morandini, New experimental diagnostics in combustion of forest fuels : microscale appreciation for a macroscale approach, Natural Hazards and Earth System Sciences, 18, 1957-1968, 2018
2. X. Silvani, F. Morandini, J.L. Dupuy, A. Susset, R. Vernet, O. Lambert. Measuring velocity field and heat transfer during natural fire spread over large inclinable bench, Experimental Thermal and Fluid Science, 92, 184-201, 2018
3. F. Morandini, X. Silvani, J.L. Dupuy, A. Susset. Fire spread across a sloping fuel bed: flame dynamics and heat transfers, Combustion and Flame, 190, 158-170, 2018
4. T. Toulouse, L. Rossi, M. A. Akhloufi, A. Pieri, X. Maldague. A multimodal 3D framework for fires characteristics estimation, Measurement Science and Technology, 29, 025404, 2018
5. Z. Li, L.S. Mihaylova, O. Isupova, L. Rossi. Autonomous Flame detection in Videos with Dirichlet process Gaussian Mixture Colour Model, IEEE Transactions on Industrial Informatics, Special Section on Multisensor Fusion and Integration for Intelligent Systems, 14(3), 1146-1154, 2018
6. C. Lac, J-P Chaboureau, V. Masson, et al (Filippi J.B.). Overview of the Meso-NH model version 5.4 and its applications. Geoscientific Model Development; 11:1929–1969, 2018
7. J-B Filippi, F. Bosseur, C. Mari, et C. Lac, Simulation of a Large Wildfire in a Coupled Fire-Atmosphere Model. Atmosphere; 9:218, 2018

1. Zhang, C, Rochoux, M, Tang, W, Gollner, M, Filippi, J-B et Trouvé, A. Evaluation of a data-driven wildland fire spread forecast model with spatially-distributed parameter estimation in simulations of the FireFlux I field-scale experiment. Fire Safety Journal 2017; 91:758–767.
2. Y. Perez-Ramirez, W.E. Mell, P.A. Santoni, J.B. Tramoni, F. Bosseur. Examination of WFDS in modeling spreading fires in a furniture calorimeter, Fire Technology, 53(5), 1795-1832, 2017
3. L. Leonelli, T. Barboni, P.A. Santoni, Y. Quilichini, A. Copalle, A characterization of aerosols emissions from the combustion of dead shrub twigs and leaves using a cone calorimeter, Fire Safety Journal, 91, 800-810, 2017
4. T. Toulouse, L. Rossi, A. Campana, T. Celik, M. Akhloufi. An evolving image dataset for processing and analysis, Fire Safety Journal, 92, 188-194, 2017
5. N. Chiaramonti, E. Romagnoli, P.A. Santoni, T. Barboni. Comparison of the combustion of pine species with two sizes of calorimeter: 10 g vs. 100 g, Fire technology, 53, 741-770, 2017
6. T. Toulouse, L. Rossi, A. Campana, T. Celik, M. Akhloufi. Computer vision for wildfire research: an evolving image dataset for processing and analysis, Fire Safety Journal, 92, 188-194, 2017
7. J. Chatelon, JH Balbi, D. Morvan, JL Rossi and T. Marcelli. A convective model for laboratory fires with well-ordered vertically-oriented fuel beds, Fire Safety Journal, 90, 54-61, 2017
8. V. Tihay-Felicelli, P.A. Santoni, G. Gerandi, T. Barboni. Smoke emissions due to burning of green waste in the mediterranean area: influence of fuel moisture content and fuel mass, Atmospheric Environment, 159, 92-106, 2017
9. T. Barboni, L. Leonelli, P.A. Santoni, V. Tihay-Felicelli. Influence of particle size on the heat release rate and smoke opacity during the burning of dead Cistus leaves and twigs, Journal of Fire sciences, 35(4), 259-283, 2017
10. G. Lapa, F. Morandini, L. Ferrat. Sap flow and photosynthetic response to climate and drought of Pinus nigra in a Mediterranean natural forest. Trees, 31:1711–1721, 2017

1. D.R. Weise, E. Koo, X. Zhou, S. Mahalingam, F. Morandini, JH Balbi. Fire spread in chaparral - a comparison of laboratory data and model predictions in burning live fuels, International Journal of Wildland Fire, 25, 980-994, 2016
2. V. Tihay-Felicelli, P.A Santoni, T. Barboni, L. Leonelli. Autoignition of Dead Shrub Twigs: Influence of Diameter on Ignition, Fire Technology, 2016, 52(3), 897-929