In situ microphysics observations of intense pyroconvection from a large wildfire

In situ microphysics observations of intense pyroconvection from a large wildfire

This study characterizes the size and shape distributions of 10 µm to 6 mm diameter particles observed during six penetrations of wildfire-induced pyroconvection near Boise, Idaho, USA, by a research aircraft over the period 29–30 August 2016. In situ measurements by the aircraft include winds, atmo...

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Bibliographic Details
Published in:Atmospheric chemistry and physics Vol. 23; no. 1; pp. 1 - 21
Main Authors: Kingsmill, David E, French, Jeffrey R, Lareau, Neil P
Format: Journal Article
Language:English
Published: Katlenburg-Lindau Copernicus GmbH 03-01-2023
Copernicus Publications
Subjects:
Aerosols
Aircraft
Ash
Ashes
Biomass
Clouds
Diameters
Forest & brush fires
Hydrometeors
Ice particles
In situ measurement
Laboratories
Liquid water content
Microphysics
Moisture content
Particle composition
Particle concentration
Penetration
Prescribed fire
Relative humidity
Remote sensing
Research aircraft
Shape
Size distribution
Smoke
Smoke plumes
Updraft
Water
Water content
Wildfires
Winds
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Summary:This study characterizes the size and shape distributions of 10 µm to 6 mm diameter particles observed during six penetrations of wildfire-induced pyroconvection near Boise, Idaho, USA, by a research aircraft over the period 29–30 August 2016. In situ measurements by the aircraft include winds, atmospheric state, and bulk water content and particle concentration, size, and shape. These observations are complemented by data from airborne and ground-based radars. One of the penetrations is through a subsaturated smoke–ash plume with negligible cloud liquid water content that is characterized by an updraft of almost 36 m s−1. The size distribution of number concentration is very similar to that documented previously for a smoke plume from a prescribed fire, and particle shapes exhibit qualitative and quantitative attributes comparable to ash particles created in a burn chamber. Particles sampled during this penetration are most likely pyrometeors composed of ash. Pyrocumulus clouds are probed in the other penetrations where values of relative humidity and cloud liquid water content are larger, but updrafts are weaker. Compared to the smoke-plume penetration, size distributions are mostly characterized by larger concentration, and particle shapes exhibit a higher degree of circular symmetry. Particle composition in these pyrocumulus penetrations is most likely a combination of hydrometeors (ice particles) and pyrometeors (ash).
ISSN:1680-7324
1680-7316
1680-7324
DOI:10.5194/acp-23-1-2023