Under climate change, winter will be the best time for burn-offs – but that could be bad news for our health

  Last updated August 3, 2020 at 2:17 pm

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Climate change may shift the window of opportunity for prescribed burns to the winter months, but that could increase the health impacts from smoke.


prescribed burns_burn offs_hazard reduction burns

Credit: AAP Image/Supplied by State Control Centre Media/News Corp Australia, Jason Edwards




Why This Matters: Climate change will make it more complex to mange the risk of bushfires.




At the height of last summer’s fires, some commentators claimed “greenies” were preventing hazard reduction burns – also known as prescribed burns – in cooler months. They argued that such burns would have reduced the bushfire intensity.


Fire experts repeatedly dismissed these claims. As then NSW Rural Fire Service Commissioner Shane Fitzsimmons noted in January this year, the number of available days to carry out prescribed burns had reduced because climate change was altering the weather and causing longer fire seasons.


This public conversation led our research team to ask: if climate change continues at its current rate, how will this change the days suitable for prescribed burning?




Also: If now is not the time to talk about climate change, when is?




Our results, were unexpected. Climate change may actually increase the number of burn days in some places, but the windows of opportunity will shift towards winter months. The bad news is that burning during these months potentially increases the public health impacts of smoke.


A hot debate of prescribed burns


Hazard reduction involves removing vegetation that could otherwise fuel a fire, including burning under controlled conditions. But its effectiveness to subdue or prevent fires is often debated in the scientific community.



Those with experience on fire grounds, including Fitzsimmons, say it’s an important factor in fire management, but “not a pancea”.


Despite the debate, it’s clear hazard reduction burning will continue to be an important part of bushfire risk management in coming decades.


Modelling future weather


Before conducting prescribed burns, firefighting agencies consider factors such as vegetation type, proximity to property, desired rate of spread and possible smoke dispersal over populated areas. But we wanted to distil our investigation down to daily weather factors.


We reduced those factors to five key components. These were maximum temperature, relative humidity, wind speed, fuel moisture and the McArthur forest fire danger index (the index used to forecast fire danger in southeast Australia).


We looked at these elements on prescribed burning days between 2004-2015. We then used climate models to simulate how the conditions would change with global warming over southeast Australia, relative to a baseline historical 20-year period for 1990-2009.


prescribed burns_burn offs_hazard reduction burns

Under global warming, suitable conditions for prescribed burns will be shifted to late winter and early spring in many places. Credit: Shutterstock


To make a valid 20-year comparison, we compared the historical period to a modelled period from 2060-2079, assuming emissions continue to rise at their current pace.


Surprisingly, we found, with one regional exception, the number of days suitable for prescribed burning did not change. And in many places, the number increased.


As the fire season lengthened under a warming climate, the number of days suitable for burning just shifted from autumn to winter.


Shifting seasons


Our research indicated that by 2060 there’ll be fewer prescribed burning days during March, April and May. These are the months when most burning happens now.


But there will be significantly more opportunities for burning days from June to October. This is because the conditions that make for a good day for prescribed burning – such as mild and still days – start to shift to winter. Today, weather in these months is unsuitable for conducting burns.




Also: A strategic approach to controlled burning boosts effectiveness




Interestingly, these results aren’t uniform across southeast Australia. For example, much of the Australian east coast and South Australia would see seasonal shifts in burning windows, with around 50% fewer burning days in March to May.


Much of Victoria and in particular the southern regions saw an increase in burning windows during April to May and, in some parts of the state, through September and October as well.


Only the east Queensland coast would see a total reduction in prescribed burn days from April to October.


The smoke trap


This may be good news for firefighters and those agencies who depend on prescribed burning as a key tool in bushfire prevention. But, as so often is the case with climate change, it’s not that simple.


byproduct of prescribed burning is smoke, and it’s a very significant health issue.


Last year, research showed global warming will strengthen an atmospheric layer that traps pollution close to the land surface, known as the “inversion layer”. This will happen in the years 2060-79, relative to 1990-2009 – especially during winter.


prescribed burns_smoke haze_smoke haze over sydney

Hazard reduction burns can release smoke into nearby communities, even major cities. Credit: REUTERS/David Gray


Unfortunately, the conditions that create inversion layers – including cool, still air – correspond with conditions suitable for prescribed burning.


For asthmatics and those sensitive to air pollution, smokier burn days could make winter months more difficult and add further stress to the health system.


It also creates an additional challenge for firefighting agencies, which must already consider whether smoke will linger close to the surface and potentially drift into populated regions during prescribed burns.


This is just one factor our firefighting agencies will need to face in the future as bushfire risk management becomes more complex and challenging under climate change.


This article was co-authored with Annette Hirsch, Jason Evans, Jason Sharples and Melissa Hart from UNSW, and Hamish Clarke from the University of Wollongong


This article is republished from The Conversation under a Creative Commons license. Read the original article.


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About the Author

Giovanni Di Virgilio
Giovanni Di Virgilio is a research associate at the University of New South Wales. His field of research is the urban climate. His current research focuses on the pollutant emissions from bush fires and hazard reduction burns to help develop a tool for forecasting the air quality risk of proposed hazard reduction burns in the greater Sydney region.

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