Abstract
Abstract. Extreme wildfires are global phenomena that consistently result in loss of life and property and further impact the cultural, economic and political stability of communities. In their most severe form they cause widespread devastation of environmental assets and are capable of impacting the upper troposphere/lower stratosphere through the formation of a thunderstorm within the plume. Such fires are now often observed by a range of remote-sensing technologies, which together allow a greater understanding of a fire's complex dynamics. This paper considers one such fire that burnt in the Blue Mountains region of Australia in late November 2006, which is known to have generated significant pyrocumulonimbus clouds in a series of blow-up events. Observations of this fire are analysed in detail to investigate the localised processes contributing to extreme fire development. In particular, it has been possible to demonstrate for the first time that the most violent instances of pyroconvection were driven by, and not just associated with, atypical local fire dynamics, especially the fire channelling phenomenon, which arises due to an interaction between an active fire, local terrain attributes and critical fire weather and causes the fire to rapidly transition from a frontal to an areal burning pattern. The impacts of local variations in fire weather and of the atmospheric profile are also discussed, and the ability to predict extreme fire development with state-of-the-art tools is explored.
Highlights
Over the last decade south-eastern Australia has experienced a number of extreme wildfire events
The development of these vigorous plumes, which manifest as pyrocumulus or pyrocumulonimbus (American Meteorological Society, 2013), signals a transition in fire development from what is primarily a surface phenomenon to a coupled fire–atmosphere phenomenon (Potter, 2002; McRae and Sharples, 2011), in which the fire is able to interact with upper levels of the atmosphere
These are referred to using codes explained in the figure caption
Summary
Over the last decade south-eastern Australia has experienced a number of extreme wildfire events. Large fire plumes offer a direct transport path between the planetary boundary layer and the stratosphere, which is not fully captured by large-scale atmospheric transport models (Jost et al, 2004) In their analysis of the 2003 Canberra bushfires, Sharples et al (2012) demonstrated several cases where interactions between strong winds and rugged topography resulted in rapid wildfire development. Based on remotely sensed data from a range of satellites and weather radar and surface and profile data from official weather observation sites, Fromm et al (2012) concluded that the factors of significance for the development of the pyroconvection were significant departures from the norm in boundary layer temperature (as indicated by the elevated value of the continuous Haines (C-Haines) Index) and wind speed They noted that neither factor alone was deterministic, reflecting a general need to further scrutinise the local drivers of the extreme fire behaviour. Australian eastern summer time, is UTC + 11 h
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