Role of buoyant flame dynamics in wildfire spread

Mark A. Finney, Jack D. Cohen, Jason M. Forthofer, Sara S. McAllister, Michael J. Gollner, Daniel J. Gorham, Kozo Saito, Nelson K. Akafuah, Brittany A. Adam, Justin D. English, Robert E. Dickinson

Research output: Contribution to journalArticlepeer-review

235 Scopus citations

Abstract

Large wildfires of increasing frequency and severity threaten local populations and natural resources and contribute carbon emissions into the earth-climate system. Although wildfires have been researched and modeled for decades, no verifiable physical theory of spread is available to form the basis for the precise predictions needed to manage fires more effectively and reduce their environmental, economic, ecological, and climate impacts. Here, we report new experiments conducted at multiple scales that appear to reveal how wildfire spread derives from the tight coupling between flame dynamics induced by buoyancy and fine-particle response to convection. Convective cooling of the fine-sized fuel particles in wildland vegetation is observed to efficiently offset heating by thermal radiation until convective heating by contact with flames and hot gasses occurs. The structure and intermittency of flames that ignite fuel particles were found to correlate with instabilities induced by the strong buoyancy of the flame zone itself. Discovery that ignition in wildfires is critically dependent on nonsteady flame convection governed by buoyant and inertial interaction advances both theory and the physical basis for practical modeling.

Original languageEnglish
Pages (from-to)9833-9838
Number of pages6
JournalProceedings of the National Academy of Sciences of the United States of America
Volume112
Issue number32
DOIs
StatePublished - Aug 11 2015

Keywords

  • Buoyant instability
  • Convective heating
  • Flame spread
  • Wildfires

ASJC Scopus subject areas

  • General

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