Wildfire and Weather Radar: A Review

McCarthy, Nicholas; Guyot, Adrien; Dowdy, Andrew J.; McGowan, Hamish A.

doi:10.1029/2018jd029285

Cited by 43 publications

(59 citation statements)

References 139 publications

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“…Radar observations of pyroconvection combined with lightning mapping array indicates that lightning occurred whenever the smoke plume grew to 10 km [9] of mean sea level. These scientists capitalized on the polarimetric data (CSU CHILL, Colorado State University and Chicago Illinois radar) to identify the smoke part of plumes by noting low reflectivities (10)(11)(12)(13)(14)(15)(16)(17)(18)(19)(20)(21)(22)(23)(24)(25), increased Z DR (1-5 dB), and small correlation coefficient between returns at orthogonal polarizations, ρ hv of about 0.6.…”

Section: Introductionmentioning

confidence: 99%

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Of Fire and Smoke Plumes, Polarimetric Radar Characteristics

et al. 2020

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Weather surveillance radars routinely detect smoke of various origin. Of particular significance to the meteorological community are wildfires in forests and/or prairies. For example, one responsibility of the National Weather Service in the USA is to forecast fire outlooks as well as to monitor wildfire evolution. Polarimetric variables have enabled relatively easy recognitions of smoke plumes in data fields of weather radars. Presented here are the fields of these variables from smoke plumes caused by grass fire, brush fire, and forest fire. Histograms of polarimetric data from plumes contrast these cases. Most of the data are from the polarimetric Weather Surveillance Radar 1988 Doppler (WSR-88D aka NEXRAD, 10 cm wavelength); hence, the wavelength does not influence these comparisons. Nevertheless, in one case, simultaneous observations of a plume by the operational Terminal Doppler Weather Radar (TDWR, 5 cm wavelength) and a WSR-88D is used to infer backscattering characteristic and, hence, sizes of dominant contributors to the returns. To interpret these measurements, Computational Electromagnetics (CEM) tools are applied. For one wildfire from Oklahoma, radar and satellite (GOES-16, Geostationary Operational Environmental Satellite) images are analyzed. The case demonstrates a potential to forecast fire intensification caused by a very rapid cold front. Finally, we suggest a possible way to extract the smoke plume return from the class of nonmeteorological scatterers.

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Section: Introductionmentioning

confidence: 99%

“…A comprehensive review of wildfire observations with radars is in [12]. The authors introduce the term pyrometeor for the ash particles causing the returns and advocate "radar research to establish the cross section and dielectric factor K m for scatterers of pyrogenic origin".…”

Section: Introductionmentioning

confidence: 99%

Of Fire and Smoke Plumes, Polarimetric Radar Characteristics

et al. 2020

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“…The intense convective plume mode is characterized Murdoch et al NWA Journal of Operational Meteorology 8 October 2019 by a buoyancy-driven and vertically oriented updraft associated with inflow and outflow winds that spread the fire erratically (Banta et al 1992). The basic premise behind a convective plume, as observed on the Weather Surveillance Radar-1988 Doppler (WSR-88D, Crum andAlberty, 1993) is that heat flux increases combustion, and as resultant buoyant forces accelerate upward, pyrometeors (McCarthy et al 2019) are lofted higher in the plume (Jones and Christopher 2010). This provides an indirect estimate of the general intensity of a fire by the magnitude of returned reflectivity.…”

Section: Introductionmentioning

confidence: 99%

“…This provides an indirect estimate of the general intensity of a fire by the magnitude of returned reflectivity. McCarthy (2019) emphasizes that to understand a radar's depiction of a plume it is important to know the properties and distribution of pyrogenic scatterers. The particle size distribution of the pyroconvective plumes has a wide spectrum ranging from ash (2 μm to 1 mm in diameter) to large vegetation (on the order of centimeters in diameter to even larger) (McCarthy et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Identifying Plume Mode via WSR-88D Observations of Wildland Fire Convective Plumes and Proposed Tactical Decision Support Applications

Murdoch

Gitro

Lindley

et al. 2019

J. Operational Meteor.

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To date, the use of Doppler radar (WSR-88D) in wildland fire operations has been limited, with tactical applications focused on analyzing ambient atmospheric features. This paper presents geographically diverse analysis of radar-observed wildland fire convective plumes to determine indicators of plume mode for tactical decision support. Through the visualization of buoyancy via thermal bubbles and vertical plumes, plume mode is revealed via WSR-88D interrogation of three Southern Great Plains grass/shrub fires and two timber fires in Texas and California. Analogous to thunderstorm convective modes, past research has identified two distinct plume modes of wildland fire: multicell and intense convective plume. Multicell plume mode is characterized by a series of shallow discrete cells that move away from the fire’s main buoyancy source, with successive cells rising, expanding, and replacing cells from the updraft source. This process, known as the thermal bubble concept, occurs most notably in strong vertical wind profile environments with a strong advection component. These cells or thermal bubbles are observed via WSR-88D data for three Southern Great Plains cases. Intense convective plumes are observed to be vertical with the low-level reflectivity maximum and maximum echo top juxtaposed and occurrence is confined to weak wind environments; these plume structures are identified in the two timber fire cases. An important WSR-88D signature, the back-sheared convective plume (hereafter BSCP), is identified in terms of transverse vortices and vortex rings, which may imply enhanced combustion rates due to increased turbulent mixing. Determination of plume convective mode via radar offers meteorologists the ability to detect changes in plume mode and to provide important tactical decision support information about fire behavior.

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“…The most significant events have produced plumes that have reached the upper troposphere/lower stratosphere (UTLS) region. Insights into pyroCb development have relied on weather radar (Melnikov et al, 2008;McCarthy et al, 2019;Peace et al, 2017;McRae, 2010;Johnson et al, 2014;Fromm et al, 2012) that provides high temporal resolution imagery of the pyroconvection, although importantly they do not accurately detect the exact extent of entrained gaseous and fine particulate emissions because they are 'tuned' to identify larger particles such as rain and ice crystals, and can therefore fortuitously detect ash and embers.…”

mentioning

confidence: 99%

Evolution of an extreme Pyrocumulonimbus-driven wildfire event in Tasmania, Australia

Ndalila

Williamson

Fox‐Hughes

et al. 2019

Preprint

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Abstract. Extreme fires have substantial adverse effects on society and natural ecosystems. Such events can be associated with intense coupling of fire behaviour with the atmosphere, resulting in extreme fire characteristics such as pyrocumulonimbus cloud (pyroCb) development. Concern that anthropogenic climate change is increasing the occurrence of pyroCbs globally is driving more focused research into these meteorological phenomena. Using 6-minute scans from a nearby weather radar, we describe the development of a pyroCb during the afternoon of 4 January 2013 above the Forcett-Dunalley fire in south-eastern Tasmania. We relate storm development to: (1) near-surface weather using the McArthur Forest Fire Danger Index (FFDI), and the C-Haines Index, a measure of the vertical atmospheric stability and dryness both derived from gridded weather reanalysis for Tasmania (BARRA-TA), and (2) a chronosequence of fire severity derived from remote sensing. We show that the pyroCb rapidly developed over a 24-minute period in the afternoon of 4 January, with the cloud top reaching a height of 15 km. The pyroCb was associated with a highly unstable atmosphere (C-Haines 10-11) and Severe-marginally Extreme (FFDI 60-75) near-surface fire weather, and formed over an area of forest that was severely burned (total crown defoliation). We use spatial patterns of elevated fire weather in Tasmania, and fire weather during major runs of large wildfires in Tasmania for the period 2007–2016 to geographically and historically contextualise this pyroCb event. Although the Forcett-Dunalley fire is the only known record of a pyroCb in Tasmania, our results show that eastern and south-eastern Tasmania are prone to the conjunction of high FFDI and C-Haines values that have been associated with pyroCb development. Our findings have implications for fire weather forecasting and wildfire management, and highlight the vulnerability of southeast Tasmania to extreme fire events.

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Wildfire and Weather Radar: A Review

Cited by 43 publications

References 139 publications

Of Fire and Smoke Plumes, Polarimetric Radar Characteristics

Of Fire and Smoke Plumes, Polarimetric Radar Characteristics

Identifying Plume Mode via WSR-88D Observations of Wildland Fire Convective Plumes and Proposed Tactical Decision Support Applications

Evolution of an extreme Pyrocumulonimbus-driven wildfire event in Tasmania, Australia

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