Research for the Environment

Press release 16 December 2011

Rapid rise in wildfires in large parts of Canada?

Ecologists show for the first time threshold values for natural wildfires

Chicago/Leipzig. Large forest regions in Canada are apparently about to experience rapid change. Based on models, scientists can now show that there are threshold values for wildfires just like there are for epidemics. Large areas of Canada are apparently approaching this threshold value and may in future exceed it due to climate change. As a result both the area burnt down annually and the average size of the fires would increase, write the researchers of the Helmholtz Centre for Environmental Research (UFZ) and the University of Michigan in the December issue of the journal The American Naturalist. The strategies for combating wildfires in large parts of Canada should therefore be reconsidered.

Forest fire in the Rocky Mountains

Forest fire in the Rocky Mountains, Canada. Large forest regions in Canada are apparently about to experience rapid change for natural wildfires.
Photo: © skylight, Fotolia.com

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Dead trees destroyed by forest fire

Dead trees destroyed by forest fire in British Columbia, Canada.
Photo: © Scott Latham, Fotolia.com

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According to media reports, after weeks of drought around 1,000 hectares of forest and scrubland were burnt down in the West Canadian province British Columbia in the summer of 2009 alone. 11,000 people had to be evacuated. Are such events on the rise as a result of climate change? This question is being hotly debated by ecologists all over the world. In July a group of US researchers led by Anthony Westerling of the University of California forecasted similar changes in the journal PNAS. They believe that climate change might result in a dramatic increase in the threat of wildfires in Yellowstone National Park and that the forests might disappear here in the 21st century.

Fires are an important factor in many terrestrial ecosystems. They are a result of the interaction of the weather, vegetation and land use, which makes them very sensitive to global change. "Changes in the wildfire regime have a significant impact on a local and global scale and therefore on the climate as well. It is therefore important to understand how the mechanisms which shape these wildfires work in order to be able to make predictions on what will change in future," explains PD Dr. Volker Grimm of the UFZ.

For their model, the scientists evaluated data from the Canadian Forest Service, which had recorded fires greater than 200 hectares between 1959 and 1999, and sorted these by ecozone. This showed that three of these ecozones in Canada are close to a turning point: the Hudson Plains south of the Hudson Bay, the Boreale Plains in the Mid-West the Boreale Shield, which stretches from the Mid-West to the East coast and is therefore the largest ecozone in Canada. The closest to a turning point is apparently the Boreale Shield. In order to check their model and the theory of a threshold value for wildfires, the scientists looked at the fires in this region more closely. Around 1980 the average size of the fires in this part of the provinces of Alberta, Saskatchewan and Manitoba tripled rapidly. "In our opinion this is a sign that there are also threshold values for forests above which the wildfire regime drastically changes," reports Volker Grimm. "It is likely that the Boreale Plains have in recent decades, particularly around 1980, experienced a change to a system characterised by wildfires. This has fundamental repercussions for the environment and the combating of wildfires. Small changes in the fire propagation parameters have a great impact on the size of the fires." Gradual changes, such as those which can be expected due to climate change, can therefore result in an abrupt and sharp increase in the size of the fires.

The scientists were also interested in the parallels with disease propagation. Prevention strategies, which reduce combustible material, are in a way similar to the vaccinations which are used against the spread of diseases such as the measles. Here too there is a threshold value above which a disease spreads and below which it falls. Other modellers from the UFZ were therefore able to turn this theoretical threshold value into a practical value. With foxes it was shown that only 60 per cent had to be vaccinated against rabies in order to successfully combat the disease. The scientists therefore hope to find out more in future studies which cover both disciplines.
Tilo Arnhold

Publication

Richard D. Zinck, Mercedes Pascual and Volker Grimm (2011)
Understanding Shifts in Wildfire Regimes as Emergent Threshold Phenomena. The American Naturalist. Vol. 178, No. 6, December 2011
www.jstor.org/pss/10.1086/662675
Die Untersuchungen wurden von der Europäischen Union im Rahmen des EU-Projektes PATRES gefördert.

Further information

PD Dr. Volker Grimm
Helmholtz Centre for Environmental Research (UFZ)
Tel +49 341 235 1711
PD Dr. Volker Grimm

Richard D. Zinck
zinck@umich.edu

Dr. Mercedes Pascual
University of Michigan
Tel +1 734 615 9808
Dr. Mercedes Pascual

Tilo Arnhold (UFZ Press office)
Tel +49 341 235 1269
presse@ufz.de

Further links

UN Year of Forests 2011
www.un.org/esa/forests/index.html

Study: Climate Change to Increase Yellowstone Wildfires Dramatically
www.ucmerced.edu/news/study-climate-change-increase-yellowstone-wildfires-dramatically
www.pnas.org/content/early/2011/07/20/1110199108

Fires regenerate African grassland (press release, 19 September 2008)
www.ufz.de/index.php?de=17197

Disturbances in Ecosystems
www.ufz.de/index.php?de=17620

Ecological Epidemiology
www.ufz.de/index.php?de=17095

Canada’s Ecozones
canadianbiodiversity.mcgill.ca/english/ecozones/ecozones.htm

In the Helmholtz Centre for Environmental Research (UFZ) scientists are researching the causes and consequences of far-reaching changes to the environment. They are concerned with water resources, biological diversity, the consequences of climate change and adaptability, environmental and biotechnologies, bioenergy, the behaviour of chemicals in the environment, their effect on health, modelling and social science issues. Their guiding theme: Our research contributes to the sustainable use of natural resources and helps to secure this basis for life for the long term under the effects of global change. The UFZ employs 1000 people in Leipzig, Halle and Magdeburg. It is financed by the federal government, Saxony and Saxony-Anhalt.

The Helmholtz Association contributes towards solving major and pressing social, scientific and economic issues with scientific excellence in six research areas: Energy, Earth and Environment, Health, Key Technologies, Structure of Matter and Aeronautics, Space and Transport. The Helmholtz Association is Germany’s largest scientific organisation with over 31,000 employees in 17 research centres and an annual budget of approximately 3 billion euros. Its work stands in the tradition of the naturalist Hermann von Helmholtz (1821-1894).

Contact

Public relations

Office
Tel +49 341 235 1269
info@ufz.de

Press / Print

Susanne Hufe (Head)
Tel +49 341 235 1630

Tilo Arnhold (Mo-We)
Tel +49 341 235 1635

presse@ufz.de