Article Title,Year,Volume,Issue,Page Range,Author
Dynamics of wildland fires and their impact on structures,2007,149,3,314-328,Porterie
Modeling forest fire spread and spotting process with small world networks,2007,149,1-2,63-78,Porterie
On the transition from smoldering to flaming,2006,145,3,579-606,Aldushin
Comparison of burning characteristics of live and dead chaparral fuels,2006,144,1-2,349-359,Mahalingam
Behaviour of Fully Developed Fire in An Enclosure,1962,6,3,133-135,Thomas
Potential explosion hazard of carbonaceous nanoparticles: screening of allotropes,2016,167,,218-227,Dastidar
Framework for submodel improvement in wildfire modeling,2018,190,,12-24,Hadden
An investigation of pyrolysis and ignition of moist leaf-like fuel subject to convective heating,2018,190,,25-35,Mahalingam
Fire spread across a sloping fuel bed: flame dynamics and heat transfers,2018,190,,158-170,Dupuy
Relating microstructure temperature and chemistry to explosive ignition and shock sensitivity,2018,190,,171-176,Ma
Experimental and numerical investigations on propagating modes of detonations: detonation wave/boundary layer interaction,2018,190,,201-215,Cai
Large eddy simulation of upward flame spread on PMMA walls with a fully coupled fluid-solid approach,2018,190,,365-387,Wang
Experimental study of corner fires--Part I: Inert panel tests,2018,189,,472-490,Merci
Experimental study of corner fires--Part II: Flame spread over MDF panels,2018,189,,491-505,Merci
An experimental study of horizontal flame spread over PMMA surface in still air,2018,188,,388-398,Tereshchenko
Propagation speeds for interacting triple flames,2018,187,,230-238,Grib
Ignition of a hydrogen-air mixture by low voltage electrical contact arcs,2017,186,,236-246,Shekhar
Buoyancy effects on concurrent flame spread over thick PMMA,2019,199,,279-291,Fernandez-Pello