Assessing fire impacts on the carbon stability of fire‐tolerant forests

Bennett, Lauren T.; Bruce, Matthew; MacHunter, Josephine; Kohout, Michele; Krishnaraj, Saravanan Jangammanaidu; Aponte, Cristina

doi:10.1002/eap.1626

Cited by 27 publications

(31 citation statements)

References 75 publications

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“…For example, successional pathways may lead to similar or greater complexity at early‐ (Donato, Campbell, & Franklin, ) or mid‐seral stages (Brassard et al, ). Also, disturbances like non‐stand replacing fire may lead to mixed‐aged structures comprised of post‐fire regeneration and older resprouting cohorts (Bennett et al, ).…”

Section: Introductionmentioning

confidence: 99%

Structural diversity underpins carbon storage in Australian temperate forests

Aponte

Kasel

Nitschke

et al. 2020

Global Ecol Biogeogr

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Aim Forest carbon storage is the result of a multitude of interactions among biotic and abiotic factors. Our aim was to use an integrative approach to elucidate mechanistic relationships of carbon storage with biotic and abiotic factors in the natural forests of temperate Australia, a region that has been overlooked in global analyses of carbon‐biodiversity relations. Location South‐eastern Australia. Time period 2010–2015. Major taxa studied Forest trees in 732 plots. Methods We used the most comprehensive forest inventory database available for south‐eastern Australia and structural equation models to assess carbon‐storage relationships with biotic factors (species or functional diversity, community‐weighted mean (CWM) trait values, structural diversity) and abiotic factors (climate, soil, fire history). To assess the consistency of relationships at different environmental scales, our analyses involved three levels of data aggregation: six forest types, two forest groups (representing different growth environments), and all forests combined. Results Structural diversity was consistently the strongest independent predictor of carbon storage at all levels of data aggregation, whereas relationships with species‐ and functional‐diversity indices were comparatively weak. CWMs of maximum height and wood density were also significant independent predictors of carbon storage in most cases. In comparison, climate, soil, and fire history had only minor and mainly indirect effects via biotic factors on carbon storage. Main conclusions Our results indicate that carbon storage in our temperate forests was underpinned by tree structural diversity (representing efficient utilisation of space) and by CWM trait values (representing selection effects) more so than by tree species richness or functional diversity. Abiotic effects were comparatively weak and mostly indirect via biotic factors irrespective of the environmental range. Our study highlights the importance of managing forests for functionally important species and to maintain and enhance their structural complexity in order to support carbon storage.

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Section: Introductionmentioning

confidence: 99%

Structural diversity underpins carbon storage in Australian temperate forests

Aponte

Kasel

Nitschke

et al. 2020

Global Ecol Biogeogr

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“…Fire severity and the spatial patterns of severity classes (e.g. patch size, configuration) have important implications for ecosystem response (Bennett et al, ; Chia et al, ; Doerr et al, ; Smucker, Hutto, & Steele, ). Unburnt patches within large wildfires, here termed ‘fire refugia’, facilitate the persistence of fire‐sensitive plants and animals in forest ecosystems globally (Meddens, Kolden, Lutz, Smith, et al, ; Robinson et al, ).…”

Section: Introductionmentioning

confidence: 99%

Wildfire refugia in forests: Severe fire weather and drought mute the influence of topography and fuel age

Collins

Bennett

Leonard

et al. 2019

Global Change Biology

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Wildfire refugia (unburnt patches within large wildfires) are important for the persistence of fire‐sensitive species across forested landscapes globally. A key challenge is to identify the factors that determine the distribution of fire refugia across space and time. In particular, determining the relative influence of climatic and landscape factors is important in order to understand likely changes in the distribution of wildfire refugia under future climates. Here, we examine the relative effect of weather (i.e. fire weather, drought severity) and landscape features (i.e. topography, fuel age, vegetation type) on the occurrence of fire refugia across 26 large wildfires in south‐eastern Australia. Fire weather and drought severity were the primary drivers of the occurrence of fire refugia, moderating the effect of landscape attributes. Unburnt patches rarely occurred under ‘severe’ fire weather, irrespective of drought severity, topography, fuels or vegetation community. The influence of drought severity and landscape factors played out most strongly under ‘moderate’ fire weather. In mesic forests, fire refugia were linked to variables that affect fuel moisture, whereby the occurrence of unburnt patches decreased with increasing drought conditions and were associated with more mesic topographic locations (i.e. gullies, pole‐facing aspects) and vegetation communities (i.e. closed‐forest). In dry forest, the occurrence of refugia was responsive to fuel age, being associated with recently burnt areas (<5 years since fire). Overall, these results show that increased severity of fire weather and increased drought conditions, both predicted under future climate scenarios, are likely to lead to a reduction of wildfire refugia across forests of southern Australia. Protection of topographic areas able to provide long‐term fire refugia will be an important step towards maintaining the ecological integrity of forests under future climate change.

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“…Evidence from southern Australia suggests that crown fires may destabilize carbon stocks in resprouting eucalypt forests (Bennett et al. ). While prescribed burning can reduce canopy fire occurrence in eucalypt forests, the window of effectiveness is typically short (i.e., up to 5 yr after a prescribed burn; Price and Bradstock , Collins et al.…”

Section: Discussionmentioning

confidence: 99%

Aboveground forest carbon shows different responses to fire frequency in harvested and unharvested forests

Collins

Bradstock

Ximenes

et al. 2018

Ecological Applications

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Sequestration of carbon in forest ecosystems has been identified as an effective strategy to help mitigate the effects of global climate change. Prescribed burning and timber harvesting are two common, co‐occurring, forest management practices that may alter forest carbon pools. Prescribed burning for forest management, such as wildfire risk reduction, may shorten inter‐fire intervals and potentially reduce carbon stocks. Timber harvesting may further increase the susceptibility of forest carbon to losses in response to frequent burning regimes by redistributing carbon stocks from the live pools into the dead pools, causing mechanical damage to retained trees and shifting the demography of tree communities. We used a 27‐yr experiment in a temperate eucalypt forest to examine the effect of prescribed burning frequency and timber harvesting on aboveground carbon (AGC). Total AGC was reduced by ~23% on harvested plots when fire frequency increased from zero to seven fires, but was not affected by fire frequency on unharvested plots. The reduction in total AGC associated with increasing fire frequency on harvested plots was driven by declines in large coarse woody debris (≥10 cm diameter) and large trees (≥20 cm diameter). Small tree (<20 cm DBH) AGC increased with fire frequency on harvested plots, but decreased on unharvested plots. Carbon in dead standing trees decreased with increasing fire frequency on unharvested plots, but was unaffected on harvested plots. Small coarse woody debris (<10 cm diameter) was largely unaffected by fire frequency and harvesting. Total AGC on harvested plots was between 67% and 82% of that on unharvested plots, depending on burning treatment. Our results suggest that AGC in historically harvested forests may be susceptible to declines in response to increases in prescribed burning frequency. Consideration of historic harvesting will be important in understanding the effect of prescribed burning programs on forest carbon budgets.

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Assessing fire impacts on the carbon stability of fire‐tolerant forests

Cited by 27 publications

References 75 publications

Structural diversity underpins carbon storage in Australian temperate forests

Structural diversity underpins carbon storage in Australian temperate forests

Wildfire refugia in forests: Severe fire weather and drought mute the influence of topography and fuel age

Aboveground forest carbon shows different responses to fire frequency in harvested and unharvested forests

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