Articles citing this paper
On the need for a theory of wildland fire spread
Mark A. Finney A B , Jack D. Cohen A , Sara S. McAllister A and W. Matt Jolly A
+ Author Affiliations
- Author Affiliations
A USDA Forest Service, Missoula Fire Sciences Laboratory, 5775 Highway 10 West, Missoula, MT 59808, USA. Email: jcohen@fs.fed.us; smcallister@fs.fed.us; mjolly@fs.fed.us
B Corresponding author. Email: mfinney@fs.fed.us
International Journal of Wildland Fire 22(1) 25-36 https://doi.org/10.1071/WF11117
Submitted: 12 August 2011 Accepted: 21 May 2012 Published:
162 articles found in Crossref database.
Thermal decomposition of vegetative fuels and the impact of measured variations on simulations of wildfire spread
Leventon Isaac T.,
Yang Jiuling, Bruns Morgan C.
Fire Safety Journal. 2023 137 p.103762
Fire spread in chaparral – a comparison of laboratory data and model predictions in burning live fuels
Weise David R.,
Koo Eunmo,
Zhou Xiangyang,
Mahalingam Shankar,
Morandini Frédéric, Balbi Jacques-Henri
International Journal of Wildland Fire. 2016 25(9). p.980
Short-term fire front spread prediction using inverse modelling and airborne infrared images
Rios O.,
Pastor E.,
Valero M. M., Planas E.
International Journal of Wildland Fire. 2016 25(10). p.1033
Stages and time-scales of ignition and burning of live fuels for different convective heat fluxes
Fazeli Hamid,
Jolly William M., Blunck David L.
Fuel. 2022 324 p.124490
Climate–vegetation–fire interactions and feedbacks: trivial detail or major barrier to projecting the future of the Earth system?
Harris Rebecca M. B.,
Remenyi Tomas A.,
Williamson Grant J.,
Bindoff Nathaniel L., Bowman David M. J. S.
WIREs Climate Change. 2016 7(6). p.910
Volatile Oil in Pinus yunnanensis Potentially Contributes to Extreme Fire Behavior
Chen Feng,
Si Liqing,
Zhao Fengjun, Wang Mingyu
Fire. 2023 6(3). p.113
Effect of fuel spatial resolution on predictive wildfire models
Taneja Ritu,
Hilton James,
Wallace Luke,
Reinke Karin, Jones Simon
International Journal of Wildland Fire. 2021 30(10). p.776
On the formation of thermal drift
Abtahi Arman, Floryan J. M.
Physics of Fluids. 2018 30(4).
Fire regimes, fire experiments and alternative stable states in mesic savannas
Veenendaal Elmar M.,
Torello‐Raventos Mireia,
Miranda Heloisa S.,
Sato Naomi M.,
Janssen Thomas A. J.,
van Langevelde Frank, Lloyd Jon
New Phytologist. 2021 231(1). p.14
Review of Pathways for Building Fire Spread in the Wildland Urban Interface Part I: Exposure Conditions
Caton Sara E.,
Hakes Raquel S. P.,
Gorham Daniel J.,
Zhou Aixi, Gollner Michael J.
Fire Technology. 2017 53(2). p.429
Wildland Fire Science Literacy: Education, Creation, and Application
McGranahan Devan, Wonkka Carissa
Fire. 2018 1(3). p.52
Cellular automata-based simulators for the design of prescribed fire plans: the case study of Liguria, Italy
Perello Nicoló,
Trucchia Andrea,
Baghino Francesco,
Asif Bushra Sanira,
Palmieri Lola,
Rebora Nicola, Fiorucci Paolo
Fire Ecology. 2024 20(1).
Scaling analysis of downstream heating and flow dynamics of fires over an inclined surface
Ren Xingyu,
Sluder Evan T.,
Heck Michael V.,
Grumstrup Torben P.,
Finney Mark A.,
Mäkiharju Simo A., Gollner Michael J.
Combustion and Flame. 2022 242 p.112203
Uncertainty associated with model predictions of surface and crown fire rates of spread
Cruz Miguel G., Alexander Martin E.
Environmental Modelling & Software. 2013 47 p.16
Effects of Season on Ignition of Live Wildland Fuels Using the Forced Ignition and Flame Spread Test Apparatus
McAllister S., Weise D. R.
Combustion Science and Technology. 2017 189(2). p.231
Encyclopedia of Wildfires and Wildland-Urban Interface (WUI) Fires (2020)
Encyclopedia of Wildfires and Wildland-Urban Interface (WUI) Fires (2018)
Mapping the daily progression of large wildland fires using MODIS active fire data
Veraverbeke Sander,
Sedano Fernando,
Hook Simon J.,
Randerson James T.,
Jin Yufang, Rogers Brendan M.
International Journal of Wildland Fire. 2014 23(5). p.655
Fuel Particle Heat Transfer Part 1: Convective Cooling of Irradiated Fuel Particles
Cohen Jack D., Finney Mark A.
Combustion Science and Technology. 2023 195(13). p.3095
De-coupling seasonal changes in water content and dry matter to predict live conifer foliar moisture content
Jolly W. Matt,
Hadlow Ann M., Huguet Kathleen
International Journal of Wildland Fire. 2014 23(4). p.480
Experimental investigation of fire propagation in single live shrubs
Li Jing,
Mahalingam Shankar, Weise David R.
International Journal of Wildland Fire. 2017 26(1). p.58
Transition from Surface to Crown Fires: Effects of Moisture Content
Mišić Nikola,
Protić Milan,
Cerdà Artemi,
Raos Miomir, Blagojević Milan
Fire Technology. 2024 60(1). p.669
A response to ‘Clarifying the meaning of mantras in wildland fire behaviour modelling: reply to Cruz et al. (2017)'
Cruz Miguel G.,
Alexander Martin E., Sullivan Andrew L.
International Journal of Wildland Fire. 2018 27(11). p.776
Experimental confirmation of the MWIR and LWIR grey body assumption for vegetation fire flame emissivity
Johnston J. M.,
Wooster M. J., Lynham T. J.
International Journal of Wildland Fire. 2014 23(4). p.463
Piloted Ignition of Cylindrical Wildland Fuels Under Irradiation
Lin Shaorun,
Huang Xinyan,
Urban James,
McAllister Sara, Fernandez-Pello Carlos
Frontiers in Mechanical Engineering. 2019 5
Evaluation of a data-driven wildland fire spread forecast model with spatially-distributed parameter estimation in simulations of the FireFlux I field-scale experiment
Zhang Cong,
Rochoux Mélanie,
Tang Wei,
Gollner Michael,
Filippi Jean-Baptiste, Trouvé Arnaud
Fire Safety Journal. 2017 91 p.758
Using Spatial Reinforcement Learning to Build Forest Wildfire Dynamics Models From Satellite Images
Ganapathi Subramanian Sriram, Crowley Mark
Frontiers in ICT. 2018 5
A national approach for integrating wildfire simulation modeling into Wildland Urban Interface risk assessments within the United States
Haas Jessica R.,
Calkin David E., Thompson Matthew P.
Landscape and Urban Planning. 2013 119 p.44
Effect of woody debris on the rate of spread of surface fires in forest fuels in a combustion wind tunnel
Sullivan A.L.,
Surawski N.C.,
Crawford D.,
Hurley R.J.,
Volkova L.,
Weston C.J., Meyer C.P.
Forest Ecology and Management. 2018 424 p.236
A nonlinear mixed‐effects modeling approach for ecological data: Using temporal dynamics of vegetation moisture as an example
Oddi Facundo J.,
Miguez Fernando E.,
Ghermandi Luciana,
Bianchi Lucas O., Garibaldi Lucas A.
Ecology and Evolution. 2019 9(18). p.10225
Plant traits linked to field-scale flammability metrics in prescribed burns in Eucalyptus forest
Tumino Bianca J.,
Duff Thomas J.,
Goodger Jason Q. D.,
Cawson Jane G., Lázaro Amparo
PLOS ONE. 2019 14(8). p.e0221403
Dryness thresholds for fire occurrence vary by forest type along an aridity gradient: evidence from Southern Australia
Duff Thomas J.,
Cawson Jane G., Harris Sarah
Landscape Ecology. 2018 33(8). p.1369
On the Growth of Wildland Fires from a Small Ignition Source
Thomsen M.,
Fernandez-Pello A. C., Williams F. A.
Combustion Science and Technology. 2023 195(14). p.3542
Embracing Complexity to Advance the Science of Wildland Fire Behavior
Yedinak Kara,
Strand Eva,
Hiers J., Varner J.
Fire. 2018 1(2). p.20
Persistent, viable seedbank buffers serotinous bishop pine over a broad fire return interval
Bisbing Sarah M.,
Urza Alexandra K.,
York Robert A.,
Hankin Lacey E., Putz Tessa R.
Fire Ecology. 2023 19(1).
The Ecological Importance of Mixed-Severity Fires (2015)
Getting Ahead of the Wildfire Problem: Quantifying and Mapping Management Challenges and Opportunities
O’Connor Christopher,
Thompson Matthew, Rodríguez y Silva Francisco
Geosciences. 2016 6(3). p.35
Scaling nonreactive cross flow over a heated plate to simulate forest fires
Gustenyov Nikolay,
Akafuah Nelson K,
Salaimeh Ahmad,
Finney Mark,
McAllister Sara, Saito Kozo
Combustion and Flame. 2018 197 p.340
Exploring fire response to high wind speeds: fire rate of spread, energy release and flame residence time from fires burned in pine needle beds under winds up to 27 ms−1
Butler Bret,
Quarles Steve,
Standohar-Alfano Christine,
Morrison Murray,
Jimenez Daniel,
Sopko Paul,
Wold Cyle,
Bradshaw Larry,
Atwood Loren,
Landon Justin,
O'Brien Joseph,
Hornsby Benjamin,
Wagenbrenner Natalie, Page Wesley
International Journal of Wildland Fire. 2020 29(1). p.81
Effects of curing on grassfires: II. Effect of grass senescence on the rate of fire spread
Cruz Miguel G.,
Gould Jim S.,
Kidnie Susan,
Bessell Rachel,
Nichols David, Slijepcevic Alen
International Journal of Wildland Fire. 2015 24(6). p.838
Natural Hazard Uncertainty Assessment (2016)
Burning Rate and Flow Resistance Through Porous Fuel Beds: Axisymmetric Versus Line Fires
McAllister Sara
Combustion Science and Technology. 2023 195(13). p.3148
Reply to Sullivan and Cruz: Defense of a simplified physical model
Fox Jerome M., Whitesides George M.
Proceedings of the National Academy of Sciences. 2015 112(31).
Deriving Fire Behavior Metrics from UAS Imagery
Moran Christopher J.,
Seielstad Carl A.,
Cunningham Matthew R.,
Hoff Valentijn,
Parsons Russell A.,
Queen LLoyd,
Sauerbrey Katie, Wallace Tim
Fire. 2019 2(2). p.36
An inconvenient truth about temperature–time data from thermocouples
McGranahan Devan Allen
Plant Ecology. 2020 221(11). p.1091
Why is the effect of live fuel moisture content on fire rate of spread underestimated in field experiments in shrublands?
Pimont F.,
Ruffault J.,
Martin-StPaul N. K., Dupuy J.-L.
International Journal of Wildland Fire. 2019 28(2). p.127
Encyclopedia of Wildfires and Wildland-Urban Interface (WUI) Fires (2020)
Pyros: a raster–vector spatial simulation model for predicting wildland surface fire spread and growth
Voltolina Debora,
Cappellini Giacomo,
Apuani Tiziana, Sterlacchini Simone
International Journal of Wildland Fire. 2024 33(3).
Development and participatory evaluation of fireline intensity and flame property models for managed burns on Calluna-dominated heathlands
Davies G. Matt,
Legg Colin J.,
Smith A. Adam, MacDonald Angus
Fire Ecology. 2019 15(1).
Autoignition of Dead Shrub Twigs: Influence of Diameter on Ignition
Tihay-Felicelli Virginie,
Santoni Paul-Antoine,
Barboni Toussaint, Leonelli Lara
Fire Technology. 2016 52(3). p.897
Towards a new paradigm in fire severity research using dose–response experiments
Smith Alistair M. S.,
Sparks Aaron M.,
Kolden Crystal A.,
Abatzoglou John T.,
Talhelm Alan F.,
Johnson Daniel M.,
Boschetti Luigi,
Lutz James A.,
Apostol Kent G.,
Yedinak Kara M.,
Tinkham Wade T., Kremens Robert J.
International Journal of Wildland Fire. 2016 25(2). p.158
The effect of fuel moisture content on the spread rate of forest fires in the absence of wind or slope
Rossa Carlos G.
International Journal of Wildland Fire. 2017 26(1). p.24
Evaluating Crown Fire Rate of Spread Predictions from Physics-Based Models
Hoffman C. M.,
Canfield J.,
Linn R. R.,
Mell W.,
Sieg C. H.,
Pimont F., Ziegler J.
Fire Technology. 2016 52(1). p.221
Comparison of flame spread characteristics between dense and loose fuel arrays
Bu Rongwei,
Fan Chuangang, Zhou Yang
Journal of Thermal Analysis and Calorimetry. 2022 147(23). p.13913
An Investigation of the Influence of Heating Modes on Ignition and Pyrolysis of Woody Wildland Fuel
Yashwanth B. L.,
Shotorban B.,
Mahalingam S., Weise D. R.
Combustion Science and Technology. 2015 187(5). p.780
An empirically based approach to defining wildland firefighter safety and survival zone separation distances
Page Wesley G., Butler Bret W.
International Journal of Wildland Fire. 2017 26(8). p.655
Infra-red line camera data-driven edge detector in UAV forest fire monitoring
De Vivo Francesco,
Battipede Manuela, Johnson Eric
Aerospace Science and Technology. 2021 111 p.106574
Enabling Machine Learning Applications in Data Science (2021)
Smoldering and Flaming of Disc Wood Particles Under External Radiation: Autoignition and Size Effect
Wang Supan,
Ding Pengfei,
Lin Shaorun,
Gong Junhui, Huang Xinyan
Frontiers in Mechanical Engineering. 2021 7
Towards predictive data-driven simulations of wildfire spread – Part I: Reduced-cost Ensemble Kalman Filter based on a Polynomial Chaos surrogate model for parameter estimation
Rochoux M. C.,
Ricci S.,
Lucor D.,
Cuenot B., Trouvé A.
Natural Hazards and Earth System Sciences. 2014 14(11). p.2951
GIS-based integration of spatial and remote sensing data for wildfire monitoring
Earth Resources and Environmental Remote Sensing/GIS Applications IX (2018)
Natural convection and thermal drift
Abtahi Arman, Floryan J. M.
Journal of Fluid Mechanics. 2017 826 p.553
Encyclopedia of Wildfires and Wildland-Urban Interface (WUI) Fires (2020)
Physicochemical characteristics controlling the flammability of live
Campos-Ruiz Rodrigo,
Parisien Marc-André, Flannigan Mike D.
International Journal of Wildland Fire. 2022 31(9). p.857
A convective model for laboratory fires with well-ordered vertically-oriented fuel beds
Chatelon François Joseph,
Balbi Jacques Henri,
Morvan Dominique,
Rossi Jean Louis, Marcelli Thierry
Fire Safety Journal. 2017 90 p.54
Fire-Modified Meteorology in a Coupled Fire–Atmosphere Model
Peace Mika,
Mattner Trent,
Mills Graham,
Kepert Jeffrey, McCaw Lachlan
Journal of Applied Meteorology and Climatology. 2015 54(3). p.704
Wildfires front dynamics: 3D structures and intensity at small and large scales
Frangieh Nicolas,
Accary Gilbert,
Morvan Dominique,
Méradji Sofiane, Bessonov Oleg
Combustion and Flame. 2020 211 p.54
Natural Hazard Uncertainty Assessment (2016)
Short communication: On the effect of live fuel moisture content on fire-spread rate
Rossa Carlos G., Fernandes Paulo M.
Forest Systems. 2018 26(3). p.eSC08
Assessment of crown fire initiation and spread models in Mediterranean conifer forests by using data from field and laboratory experiments
Rodríguez y Silva Francisco,
Guijarro Mercedes,
Madrigal Javier,
Jiménez Enrique,
Molina Juan R.,
Hernando Carmen,
Vélez Ricardo, Vega Jose A.
Forest Systems. 2017 26(2). p.e02S
Automated location of active fire perimeters in aerial infrared imaging using unsupervised edge detectors
Valero M. M.,
Rios O.,
Pastor E., Planas E.
International Journal of Wildland Fire. 2018 27(4). p.241
Learning-based prediction of wildfire spread with real-time rate of spread measurement
Zhai Chunjie,
Zhang Siyu,
Cao Zhaolou, Wang Xinmeng
Combustion and Flame. 2020 215 p.333
Report on Existing Fireproof Construction Guidelines for Dwellings against Wildfires
Cantor Pedro,
Bicelli António Renato,
de Assis Ellon Bernardes,
Arruda Mário Rui, Branco Fernando
CivilEng. 2023 4(2). p.657
Inside the Inferno: Fundamental Processes of Wildland Fire Behaviour
Sullivan Andrew L.
Current Forestry Reports. 2017 3(2). p.132
Linking fire behaviour and its ecological effects to plant traits, using FRaME in R
Zylstra Philip
Methods in Ecology and Evolution. 2021 12(8). p.1365
Natural Hazard Uncertainty Assessment (2016)
Experimental study on the burning behaviour of Pinus halepensis needles using small‐scale fire calorimetry of live, aged and dead samples
Jervis Freddy X., Rein Guillermo
Fire and Materials. 2016 40(3). p.385
Wildland fires behaviour: wind effect versus Byram’s convective number and consequences upon the regime of propagation
Morvan D., Frangieh N.
International Journal of Wildland Fire. 2018 27(9). p.636
Warning signals for eruptive events in spreading fires
Fox Jerome M., Whitesides George M.
Proceedings of the National Academy of Sciences. 2015 112(8). p.2378
Physics-Based Modeling of Live Wildland Fuel Ignition Experiments in the Forced Ignition and Flame Spread Test Apparatus
Anand C.,
Shotorban B.,
Mahalingam S.,
McAllister S., Weise D. R.
Combustion Science and Technology. 2017 189(9). p.1551
Role of buoyant flame dynamics in wildfire spread
Finney Mark A.,
Cohen Jack D.,
Forthofer Jason M.,
McAllister Sara S.,
Gollner Michael J.,
Gorham Daniel J.,
Saito Kozo,
Akafuah Nelson K.,
Adam Brittany A., English Justin D.
Proceedings of the National Academy of Sciences. 2015 112(32). p.9833
Pyro-Ecophysiology: Shifting the Paradigm of Live Wildland Fuel Research
Jolly W., Johnson Daniel
Fire. 2018 1(1). p.8
The effect of flow and geometry on concurrent flame spread
Gollner Michael J.,
Miller Colin H.,
Tang Wei, Singh Ajay V.
Fire Safety Journal. 2017 91 p.68
Machine Learning Methods and Synthetic Data Generation to Predict Large Wildfires
Pérez-Porras Fernando-Juan,
Triviño-Tarradas Paula,
Cima-Rodríguez Carmen,
Meroño-de-Larriva Jose-Emilio,
García-Ferrer Alfonso, Mesas-Carrascosa Francisco-Javier
Sensors. 2021 21(11). p.3694
Plant-Fire Interactions (2020)
Litter moisture adsorption is tied to tissue structure, chemistry, and energy concentration
Talhelm Alan F., Smith Alistair M. S.
Ecosphere. 2018 9(4).
Ignition delay times of live and dead pinus radiata needles
Reszka P.,
Cruz J.J.,
Valdivia J.,
González F.,
Rivera J.,
Carvajal C., Fuentes A.
Fire Safety Journal. 2020 112 p.102948
Quantifying pyroconvective injection heights using observations of fire energy: sensitivity of spaceborne observations of carbon monoxide
Gonzi S.,
Palmer P. I.,
Paugam R.,
Wooster M., Deeter M. N.
Atmospheric Chemistry and Physics. 2015 15(8). p.4339
100 Years of Progress in Applied Meteorology. Part III: Additional Applications
Haupt Sue Ellen,
Kosović Branko,
McIntosh Scott W.,
Chen Fei,
Miller Kathleen,
Shepherd Marshall,
Williams Marcus, Drobot Sheldon
Meteorological Monographs. 2019 59 p.24.1
Assessing improvements in models used to operationally predict wildland fire rate of spread
Cruz Miguel G.,
Alexander Martin E.,
Sullivan Andrew L.,
Gould James S., Kilinc Musa
Environmental Modelling & Software. 2018 105 p.54
Modeling Wildfire Incident Complexity Dynamics
Thompson Matthew P., Scalas Enrico
PLoS ONE. 2013 8(5). p.e63297
An integrated approach for tactical monitoring and data-driven spread forecasting of wildfires
Valero Mario M.,
Rios Oriol,
Mata Christian,
Pastor Elsa, Planas Eulàlia
Fire Safety Journal. 2017 91 p.835
Burning Rate of Wood Cribs with Controlled Airflow
McAllister S., Grumstrup T.
Fire Technology. 2023 59(6). p.3473
Design and implementation of a portable, large-scale wind tunnel for wildfire research
Di Cristina Giovanni,
Gallagher Michael R.,
Skowronski Nicholas S.,
Simeoni Albert,
Rangwala Ali, Im Seong-kyun
Fire Safety Journal. 2022 131 p.103607
Deformation of wood slice in fire: Interactions between heterogeneous chemistry and thermomechanical stress
Wang Supan,
Ding Pengfei,
Lin Shaorun,
Huang Xinyan, Usmani Asif
Proceedings of the Combustion Institute. 2021 38(3). p.5081
Quantifying the flammability of living plants at the branch scale: which metrics to use?
Cawson J. G.,
Burton J. E.,
Pickering B. J.,
Demetriou V., Filkov A. I.
International Journal of Wildland Fire. 2023 32(10). p.1404
Inside the Inferno: Fundamental Processes of Wildland Fire Behaviour
Sullivan Andrew L.
Current Forestry Reports. 2017 3(2). p.150
New In-Flame Flammability Testing Method Applied to Monitor Seasonal Changes in Live Fuel
Melnik Oleg M.,
Paskaluk Stephen A.,
Ackerman Mark Y.,
Melnik Katharine O.,
Thompson Dan K.,
McAllister Sara S., Flannigan Mike D.
Fire. 2021 5(1). p.1
On the merits of sparse surrogates for global sensitivity analysis of multi-scale nonlinear problems: Application to turbulence and fire-spotting model in wildland fire simulators
Trucchia A.,
Egorova V.,
Pagnini G., Rochoux M.C.
Communications in Nonlinear Science and Numerical Simulation. 2019 73 p.120
Flame spread predictions over linear discrete fuel arrays using an empirical B-number model and stagnation point flow
Cristina Giovanni Di,
Skowronski Nicholas S.,
Simeoni Albert,
Rangwala Ali S., Im Seong-kyun
Combustion and Flame. 2021 234 p.111644
Encyclopedia of Wildfires and Wildland-Urban Interface (WUI) Fires (2019)
Critical mass flux for flaming ignition of wet wood
McAllister S.
Fire Safety Journal. 2013 61 p.200
Phases and Time-Scales of Ignition and Burning of Live Fuels
Fazeli Hamid,
Jolly William M., Blunck David L.
SSRN Electronic Journal . 2022
Assessing forest fire behavior simulation using FlamMap software and remote sensing techniques in Western Black Sea Region, Turkey
YAVUZ Mehmet,
SAĞLAM Bülent,
KÜÇÜK Ömer, TÜFEKÇİOĞLU Aydın
Kastamonu Üniversitesi Orman Fakültesi Dergisi. 2018 18(2). p.171
Coastal Vulnerability under Extreme Weather
Murray Alan T.,
Carvalho Leila,
Church Richard L.,
Jones Charles,
Roberts Dar,
Xu Jing,
Zigner Katelyn, Nash Deanna
Applied Spatial Analysis and Policy. 2021 14(3). p.497
Collective Effects of Fire Intensity and Sloped Terrain on Wind-Driven Surface Fire and Its Impact on a Cubic Structure
Ghodrat Maryam,
Edalati-Nejad Ali, Simeoni Albert
Fire. 2022 5(6). p.208
The effects of humus moisture content on underground fires in a Larix gmelinii plantation
Han Xiyue,
Xu Hening,
Wang Tiantian,
Yin Sainan,
Gao Bo,
Wang Yajun, Shan Yanlong
Journal of Forestry Research. 2022 33(3). p.865
Rate of spread and flaming zone velocities of surface fires from visible and thermal image processing
Schumacher B.,
Melnik K. O.,
Katurji M.,
Zhang J.,
Clifford V., Pearce H. G.
International Journal of Wildland Fire. 2022 31(8). p.759
Development and application of a geospatial wildfire exposure and risk calculation tool
Thompson Matthew P.,
Haas Jessica R.,
Gilbertson-Day Julie W.,
Scott Joe H.,
Langowski Paul,
Bowne Elise, Calkin David E.
Environmental Modelling & Software. 2015 63 p.61
A Device for Instantaneously Estimating Duff Moisture Content Is also Effective for Grassland Fuels
McGranahan Devan
Fire. 2019 2(1). p.12
The wildland fire system and challenges for engineering
Finney Mark A.
Fire Safety Journal. 2021 120 p.103085
Encyclopedia of Wildfires and Wildland-Urban Interface (WUI) Fires (2020)
Examining alternative fuel management strategies and the relative contribution of National Forest System land to wildfire risk to adjacent homes – A pilot assessment on the Sierra National Forest, California, USA
Scott Joe H.,
Thompson Matthew P., Gilbertson-Day Julie W.
Forest Ecology and Management. 2016 362 p.29
A Review of Pathways for Building Fire Spread in the Wildland Urban Interface Part II: Response of Components and Systems and Mitigation Strategies in the United States
Hakes Raquel S. P.,
Caton Sara E.,
Gorham Daniel J., Gollner Michael J.
Fire Technology. 2017 53(2). p.475
Empirical Modeling of Fire Spread Rate in No-Wind and No-Slope Conditions
Rossa Carlos G, Fernandes Paulo M
Forest Science. 2018 64(4). p.358
Mantras of wildland fire behaviour modelling: facts or fallacies?
Cruz Miguel G.,
Alexander Martin E., Sullivan Andrew L.
International Journal of Wildland Fire. 2017 26(11). p.973
Physical model of wildland fire spread: Parametric uncertainty analysis
Yuan Xieshang,
Liu Naian,
Xie Xiaodong, Viegas Domingos X.
Combustion and Flame. 2020 217 p.285
Combining multi-spectral and thermal remote sensing to predict forest fire characteristics
Maffei Carmine,
Lindenbergh Roderik, Menenti Massimo
ISPRS Journal of Photogrammetry and Remote Sensing. 2021 181 p.400
Faster prediction of wildfire behaviour by physical models through application of proper orthogonal decomposition
Guelpa Elisa,
Sciacovelli Adriano,
Verda Vittorio, Ascoli Davide
International Journal of Wildland Fire. 2016 25(11). p.1181
Wildland Fuel Fundamentals and Applications (2015)
Experimental study of fire spread through discontinuous fuels without flame contact
Schneider Leo,
Betting Benjamin,
Patterson Matthew,
Skowronski Nicholas, Simeoni Albert
Fire Safety Journal. 2021 120 p.103066
Vegetation fire activity and the Potential Fire Index (PFIv2) performance in the last two decades (2001–2016)
da Silva Alex S.,
Justino Flavio,
Setzer Alberto W., Avila‐Diaz Alvaro
International Journal of Climatology. 2021 41(S1).
Ignition and burning mechanisms of live spruce needles
Darwish Ahmad Adnan,
Abubaker Ahmad M.,
Salaimeh Ahmad,
Akafuah Nelson K.,
Finney Mark,
Forthofer Jason M., Saito Kozo
Fuel. 2021 304 p.121371
Application of Wildfire Risk Assessment Results to Wildfire Response Planning in the Southern Sierra Nevada, California, USA
Thompson Matthew,
Bowden Phil,
Brough April,
Scott Joe,
Gilbertson-Day Julie,
Taylor Alan,
Anderson Jennifer, Haas Jessica
Forests. 2016 7(12). p.64
Mapping Forest Landscape Patterns (2017)
Can peat soil support a flaming wildfire?
Lin Shaorun,
Sun Peiyi, Huang Xinyan
International Journal of Wildland Fire. 2019 28(8). p.601
Flame Characteristics Adjacent to a Stationary Line Fire
Finney Mark A.,
Grumstrup Torben P., Grenfell Isaac
Combustion Science and Technology. 2022 194(11). p.2212
Detailed physical modeling of wildland fire dynamics at field scale - An experimentally informed evaluation
Mueller Eric V.,
Skowronski Nicholas S.,
Clark Kenneth L.,
Gallagher Michael R.,
Mell William E.,
Simeoni Albert, Hadden Rory M.
Fire Safety Journal. 2021 120 p.103051
Plant-Fire Interactions (2020)
The impact of radiative heat transfer in combustion processes and its modeling – with a focus on turbulent flames
Liu Fengshan,
Consalvi Jean-Louis,
Coelho Pedro J.,
Andre Frédéric,
Gu Mingyan,
Solovjov Vladimir, Webb Brent W.
Fuel. 2020 281 p.118555
A Deep Learning Approach to Downscale Geostationary Satellite Imagery for Decision Support in High Impact Wildfires
McCarthy Nicholas F.,
Tohidi Ali,
Aziz Yawar,
Dennie Matt,
Valero Mario Miguel, Hu Nicole
Forests. 2021 12(3). p.294
Numerical investigation on turbulence-radiation interaction in the UMD turbulent line fires
Lin Jianhong,
Zhou Hua,
Hawkes Evatt R.,
Ma Man-Ching, Yeoh Guan H.
Fire Safety Journal. 2023 141 p.103970
Encyclopedia of Wildfires and Wildland-Urban Interface (WUI) Fires (2018)
Extreme Weather Forecasting (2023)
Convective heat transfer in non-uniformly heated corrugated slots
Abtahi Arman, Floryan J. M.
Physics of Fluids. 2017 29(10).
Encyclopedia of Wildfires and Wildland-Urban Interface (WUI) Fires (2019)
Experimental and numerical investigation of a single-tree fire
Accary Gilbert,
Darido Joseph,
Morvan Dominique,
Schneider Leo,
Betting Benjamin,
Frangieh Nicolas,
Meradji Sofiane, Simeoni Albert
Journal of Fire Sciences. 2024 42(2). p.142
Forest fire spread simulation algorithm based on cellular automata
Rui Xiaoping,
Hui Shan,
Yu Xuetao,
Zhang Guangyuan, Wu Bin
Natural Hazards. 2018 91(1). p.309
Progress in Scale Modeling, Volume II (2015)
Fuel Properties of Effective Greenstrips in Simulated Cheatgrass Fires
McGranahan Devan Allen, Wonkka Carissa L.
Environmental Management. 2022 70(2). p.319
Fire spread across a sloping fuel bed: Flame dynamics and heat transfers
Morandini Frédéric,
Silvani Xavier,
Dupuy Jean-Luc, Susset Arnaud
Combustion and Flame. 2018 190 p.158
Autonomous kinetic modeling of biomass pyrolysis using chemical reaction neural networks
Ji Weiqi,
Richter Franz,
Gollner Michael J., Deng Sili
Combustion and Flame. 2022 240 p.111992
Revisiting Wildland Fire Fuel Quantification Methods: The Challenge of Understanding a Dynamic, Biotic Entity
Duff Thomas,
Keane Robert,
Penman Trent, Tolhurst Kevin
Forests. 2017 8(9). p.351
A combustion model of vegetation burning in “Tiger” fire propagation tool
(2017)
Safe separation distance score: a new metric for evaluating wildland firefighter safety zones using lidar
Campbell Michael J.,
Dennison Philip E., Butler Bret W.
International Journal of Geographical Information Science. 2017 31(7). p.1448
Natural convection in a horizontal fluid layer periodically heated from above and below
Hossain M. Z., Floryan J. M.
Physical Review E. 2015 92(2).
Natural Hazard Uncertainty Assessment (2016)
Fuel-related fire-behaviour relationships for mixed live and dead fuels burned in the laboratory
Rossa Carlos G., Fernandes Paulo M.
Canadian Journal of Forest Research. 2017 47(7). p.883
Combustion dynamics of large-scale wildfires
Liu Naian,
Lei Jiao,
Gao Wei,
Chen Haixiang, Xie Xiaodong
Proceedings of the Combustion Institute. 2021 38(1). p.157
Application of artificial intelligence methods to model the effect of grass curing level on spread rate of fires
Khanmohammadi Sadegh,
Cruz Miguel G.,
Mohammadi Golafshani Emadaldin,
Bai Yu, Arashpour Mehrdad
Environmental Modelling & Software. 2024 173 p.105930
Utilization of remote sensing techniques for the quantification of fire behavior in two pine stands
Mueller Eric V.,
Skowronski Nicholas,
Clark Kenneth,
Gallagher Michael,
Kremens Robert,
Thomas Jan C.,
El Houssami Mohamad,
Filkov Alexander,
Hadden Rory M.,
Mell William, Simeoni Albert
Fire Safety Journal. 2017 91 p.845
Prediction and data mining of burned areas of forest fires: Optimized data matching and mining algorithm provides valuable insight
Wood David A.
Artificial Intelligence in Agriculture. 2021 5 p.24
Effect of slope on spread of a linear flame front over a pine needle fuel bed: experiments and modelling
Liu Naian,
Wu Jinmo,
Chen Haixiang,
Xie Xiaodong,
Zhang Linhe,
Yao Bin,
Zhu Jiping, Shan Yanlong
International Journal of Wildland Fire. 2014 23(8). p.1087
Modified Rayleigh–Bénard convection driven by long-wavelength heating from above and below
Floryan J. M.,
Hossain M. Z., Bassom Andrew P.
Theoretical and Computational Fluid Dynamics. 2019 33(1). p.37
Modeling wildfire using evolutionary cellular automata
Proceedings of the 2020 Genetic and Evolutionary Computation Conference (2020)
Fuel Particle Heat Transfer Part 2: Radiation and Convection during Spreading Laboratory Fires
Cohen Jack, Finney Mark
Combustion Science and Technology. 2023 195(13). p.3122
Simulations of the unsteady response of biomass burning particles exposed to oscillatory heat flux conditions
Ahmed Mohamed Mohsen, Trouvé Arnaud
Fire Safety Journal. 2021 120 p.103059
Live Fuel Moisture Content: The ‘Pea Under the Mattress’ of Fire Spread Rate Modeling?
Rossa Carlos, Fernandes Paulo
Fire. 2018 1(3). p.43
Summary of workshop large outdoor fires and the built environment
Manzello Samuel L.,
Blanchi Raphaele,
Gollner Michael J.,
Gorham Daniel,
McAllister Sara,
Pastor Elsa,
Planas Eulàlia,
Reszka Pedro, Suzuki Sayaka
Fire Safety Journal. 2018 100 p.76
The Hot-Dry-Windy Index: A New Fire Weather Index
Srock Alan,
Charney Joseph,
Potter Brian, Goodrick Scott
Atmosphere. 2018 9(7). p.279
Validating the effect of fuel moisture content by a multivalued operator in a simplified physical fire spread model
Asensio M.I.,
Cascón J.M.,
Laiz P., Prieto-Herráez D.
Environmental Modelling & Software. 2023 164 p.105710
Simulations of flaming combustion and flaming-to-smoldering transition in wildland fire spread at flame scale
Ahmed Mohamed Mohsen,
Trouvé Arnaud,
Forthofer Jason, Finney Mark
Combustion and Flame. 2024 262 p.113370
