Abstract
Wildfires have increased in size and frequency in recent decades in many biomes, but have they also become more severe? This question remains under-examined despite fire severity being a critical aspect of fire regimes that indicates fire impacts on ecosystem attributes and associated post-fire recovery. We conducted a retrospective analysis of wildfires larger than 1000 ha in south-eastern Australia to examine the extent and spatial pattern of high-severity burned areas between 1987 and 2017. High-severity maps were generated from Landsat remote sensing imagery. Total and proportional high-severity burned area increased through time. The number of high-severity patches per year remained unchanged but variability in patch size increased, and patches became more aggregated and more irregular in shape. Our results confirm that wildfires in southern Australia have become more severe. This shift in fire regime may have critical consequences for ecosystem dynamics, as fire-adapted temperate forests are more likely to be burned at high severities relative to historical ranges, a trend that seems set to continue under projections of a hotter, drier climate in south-eastern Australia.
Highlights
Wildfire shapes landscape patterns and ecosystem processes as it determines both vegetation distribution and structure [1, 2]
This study was conducted across the state of Victoria, south-eastern Australia, an area that encompasses 237,659 km2, ranges from 0 to 1986 m a.s.l in elevation and comprises several geographical bioregions with differing geology, soils, climate, and predominant vegetation (Table 1 and Fig 1) [53]
Estimated changes in the area and the proportion of area burnt by high-severity fire over time by bioregions were positive and significant in all cases (Fig 3 and S2-S3 Figs of S1 File)
Summary
Wildfire shapes landscape patterns and ecosystem processes as it determines both vegetation distribution and structure [1, 2]. Many studies over the past decades have reported a change in wildfire activity including increases in the frequency, size, and duration of wildfires, as well as the length of the fire season [4,5,6,7,8]. Such increases have been linked to climate change, which influences key fire drivers like fuel accumulation and availability [9,10,11]. Models based on climate change projections suggest that this trend in increasing fire activity will continue into the future [3, 12,13,14,15] posing threats to forest resilience, including shifts to lower density forests or non-forest states [16,17,18].
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
