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Reduce the risk of tree mortality from biological or climatic stressors in fire-prone systems

Approach

The complex interactions and feedbacks between climate, vegetation, and tree insect pests on fire occurrence and behavior have global consequences for atmospheric carbon concentrations. Extensive tree mortality due to drought, insect pests and pathogens, weather extremes, or other climate-related disturbances greatly increases fuel loads and the risk of wildfire. Fire risk may respond over short timeframes if vegetation mortality occurs quickly, such as when windthrow occurs, or have a time-lagged response due to interactions between multiple stressors. Management actions that reduce susceptibility of forest stands to drought-, insect-, or disturbance-induced tree die-offs may reduce susceptibility to these threats.

Tactics

  • Thinning forest stands to reduce risk of drought-induced mortality.
  • Selective harvest to lower the density of a host species for a pathogen or insect pest.
  • Increasing diversity of tree species within forest stands.
  • Diversifying age classes or stand structures to reduce the impacts of pests and pathogens.
  • Reducing susceptibility to drought and windthrow with by thinning stands when young.

Strategy

Strategy Text

Natural disturbance events—including insect pests and diseases, damage from wind and ice, drought, and wildfire—typically reduce near-term forest carbon stocks while initiating long-term and gradual recovery. These disturbances are both a major causes of carbon loss in forests and influence future sequestration rates through impacts on species composition, ecosystem structure, rates of photosynthesis and respiration, and flows through various carbon pools. While forest regrowth offsets carbon losses following human and natural disturbances over time allowing U.S. forests to remain a net carbon sink, enhanced disturbance frequency, severity, or extent from climate change may enhance large-scale forest carbon release. Shifting climatic conditions, including earlier snowmelt, low precipitation, and warmer temperatures contribute to increases in fire size, frequency, and the area burned annually in the U.S.. Impacts of wildfire on forest carbon sequestration can be long lasting and profound, particularly when they occur outside of the historical fire regime. Not only do wildland fires emit carbon stored in trees that have been burned, but mineral soils and forest floor carbon stocks can also be reduced significantly. Additionally, carbon sequestration rates can be lowered in burned areas because of negative impacts on vegetation productivity following severe fire. While many actions associated with this strategy can result in a short-term, low magnitude, or fine-scale forest carbon loss, this strategy aims to avoid or reduce long-term, large magnitude, or broad-scale carbon losses through management actions intended to decrease natural disturbance frequency, extent, intensity, or severity.

Todd A Ontl, Maria K Janowiak, Christopher W Swanston, Jad Daley, Stephen Handler, Meredith Cornett, Steve Hagenbuch, Cathy Handrick, Liza Mccarthy, Nancy Patch, Forest Management for Carbon Sequestration and Climate Adaptation, Journal of Forestry, Volume 118, Issue 1, January 2020, Pages 86–101, https://doi.org/10.1093/jofore/fvz062

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Resource Area

Relevant Region

Midwest
Northeast
Northwest
Southeast