Soil Bacterial and Fungal Response to Wildfires in the Canadian Boreal Forest Across a Burn Severity Gradient

Whitman, Thea; Whitman, Ellen; Woolet, Jamie; Flannigan, Mike D.; Thompson, Dan K.; Parisien, Marc‐André

doi:10.1101/512798

Cited by 7 publications

(7 citation statements)

References 87 publications

(113 reference statements)

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“…Peatlands in late spring/early summer SRI versus LRI fire had relatively similar depth of peat layer (Figure 2), while peat depths in transitional areas were significantly greater following SRI fire (Figure 2). These results were contrary to Whitman et al (2019), who found that peat depths were greater in LRI fires compared with SRI fires that occurred in summer in both boreal forests and peatlands. Differences may be due to enhanced drying and disconnection from regional groundwater following evaporative drying in summer in peatlands that had not been burned in recent decades, compared with shallower depth to water table in peatlands that had burned recently (e.g., Kettridge et al, 2014).…”

Section: Soil Characteristics Of Sri and Lri Fire In Western Boreal P...contrasting

confidence: 99%

“…Boreal peatlands are composed of thick layers of insulating moss vegetation, which extend to depths greater than 0.4 m due to gradual processes of carbon sequestration, biomass accumulation and slow rates of decomposition (Benscoter et al, 2011;Kuhry, 1994). The largely moist characteristics of peatlands make them an important refuge from wildland fire, increasing the years between fire compared with surrounding upland forests (Turetsky et al, 2004;Whitman et al, 2019;Zoltai et al, 1998). The period between fires is described as a 'fire return interval'.…”

Section: Introductionmentioning

confidence: 99%

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Ecological impacts of shortening fire return intervals on boreal peatlands and transition zones using integrated in situ field sampling and lidar approaches

et al. 2022

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Aridity associated with rising air temperatures in northern latitudes is expected to contribute to increased frequency of wildland fires. Here, we examined regenerating vegetation following short return interval (SRI) fire (56 years post‐fire) compared to long return interval (LRI) fire (>80 years post‐fire) in boreal peatlands and their adjacent transitional areas. The objectives of this study were to quantify if differences exist between (1) peatland and transitional soil characteristics in LRI versus SRI areas and (2) regenerating vegetation species, structural characteristics and diversity. We also determined if patterns of vegetation structural characteristics observed using field data also occur across the broader landscape using airborne lidar data. The Utikuma Region Study Area (URSA) is located in central Alberta, Canada. Here, 19 peatlands were sampled, coincident with an airborne lidar survey of the broader region, where 120 peatlands in short and long fire return intervals were identified. We found that SRI transitional areas had significantly deeper organic soil deposits than those found in LRI (p < 0.0001). Proportions of regenerating species differed significantly between peatlands and transitional areas in SRI versus LRI, where greater proportion of coniferous species were observed in LRI. Deciduous transitional–upland species and taller post‐fire vegetation heights were more commonly found SRI peatlands compared with LRI. This suggest that fires with SRIs in this region may result in enhanced deciduous succession, which may transition boreal peatlands into ecosystems that have some characteristics of transitional and upland forests.

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Section: Soil Characteristics Of Sri and Lri Fire In Western Boreal P...contrasting

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Ecological impacts of shortening fire return intervals on boreal peatlands and transition zones using integrated in situ field sampling and lidar approaches

et al. 2022

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“…A fire resilience index could also be developed for systems where crown-killing fire is the common fire regime, but would need to incorporate the variation in regeneration methods and optimal fire return intervals (Enright et al, 2015). In general, fire-embracing species possessing either serotiny or resprouting ability are resilient to stand-replacing, high-severity fire, although with ongoing anthropogenic and climate-driven shortening of fire return intervals in such crown-fire-adapted ecosystems, these species are also at risk of population declines (Enright et al, 2015;Turner, Braziunas, Hansen, & Harvey, 2019;Whitman, Parisien, Thompson, & Flannigan, 2019). Furthermore, fire-avoiding species (Keeley, 2012) may also be resilient to stand-replacing fire if tree establishment proceeds during sufficiently long fire-free intervals and if post-fire spatial mosaics of live tree refugia are complex enough for seed dispersal to initiate forest succession.…”

Section: Discussionmentioning

confidence: 99%

Biogeography of fire regimes in western U.S. conifer forests: A trait‐based approach

Stevens

Kling

Schwilk

et al. 2020

Global Ecol Biogeogr

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Aim Functional traits are a crucial link between species distributions and the ecosystem processes that structure those species’ niches. Concurrent increases in the availability of functional trait data and our ability to model species distributions present an opportunity to develop functional trait biogeography (i.e., the mapping of functional traits across space). Functional trait biogeography can improve process‐based predictions about the resistance of certain species assemblages to changing environmental conditions across landscape scales. We illustrate this concept by developing the first trait‐based, quantitative ranking of fire resistance (adult tree survival) in North American conifer species and mapping that fire resistance across space. Location and time period Western continental USA, present day. Major taxa studied Twenty‐nine common conifer tree species. Methods We compiled six traits for each species: three relating to tree morphology and three relating to litter flammability. We combined these traits into a single fire resistance score and used community‐weighted averaging to estimate the fire resistance scores of different forest communities, using interpolated species distribution and relative abundance data. Results Species associated historically with frequent fire have high fire resistance scores (e.g., Pinus ponderosa), reflected by thick bark, tall crowns and flammable litter. Species associated with subalpine or arid conditions have low fire resistance scores (e.g., Picea engelmannii and Pinus edulis), reflected by thin bark, short stature, poor self‐pruning and low litter flammability. A map of forest community fire resistance across the western USA reveals agreement with independent assessments of historical fire regimes, while also identifying areas where community‐wide species traits might be mismatched with historical fire regimes. Main conclusions Quantifying the functional traits that confer resistance to tree‐killing fire provides a direct link between ecosystem disturbance and community resistance. Understanding this link is crucial to evaluation of the long‐term resilience of different forest types under dynamic fire regimes. Our work represents the first known spatial representation of fire resistance traits at a regional scale and, as such, provides a link between functional traits and biogeography relevant to a critical ecosystem process.

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“…Aspen and birch are also replacing black spruce after severe fires, and the fate of postfire deciduous forest will almost certainly be determined by similar abiotic and biotic drivers to those studied here. In other parts of the North American boreal biome, lodgepole pine and jack pine trees are now becoming dominant over black spruce after fire (Jean, Pinno, & Nielsen, 2020;Johnstone & Chapin, 2003;Searle & Chen, 2017;Whitman, Parisien, Thompson, & Flannigan, 2018;Whitman et al, 2019). We must evaluate whether and how feedbacks will form that determine the long-term fate of these emerging vegetation types.…”

Section: Gaining Mechanistic Insights Across the North American Bormentioning

confidence: 99%

An alternate vegetation type proves resilient and persists for decades following forest conversion in the North American boreal biome

et al. 2020

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Climate change and natural disturbances are catalysing forest transitions to different vegetation types, but whether these new communities are resilient alternate states that will persist for decades to centuries is not known. Here, we test how changing climate, disturbance and biotic interactions shape the long‐term fate of a deciduous broadleaf forest type that replaces black spruce after severe wildfires in interior Alaska, USA. We simulated postfire deciduous forest that replaced black spruce after severe fires in 2004 for tens to hundreds of years under different climate scenarios (contemporary, mid 21st century, late 21st century), fire return intervals (11–250 years), distances to seed source (50–1,000 m) and browsing intensities (background, moderate, chronic). We identified combinations of conditions where deciduous forest remained the dominant vegetation type and combinations where it returned to black spruce forest, transitioned to mixed forest (where deciduous species and black spruce co‐dominate) or converted to nonforest. Deciduous forest persisted in 86% of simulations and was most resilient if fire return intervals were short (≤50 years). When transitions to another vegetation type occurred, mixed forest was most common, particularly when fire return intervals were long (>50 years) and the nearest seed source was 500 m or farther. Moderate and chronic browsing also reduced deciduous sapling growth and survival, helping black spruce compete if fire return intervals were long and seed source was distant. Dry soils occasionally caused conversion to nonforest following short‐interval fire when simulations were forced with a late 21st‐century climate scenario that projects warming and increased vapor pressure deficit. Return to black spruce forest almost never occurred. Synthesis. Conversion from black spruce to deciduous forest is already underway at regional scales in interior Alaska, and similar transitions have been widely observed throughout the North American boreal biome. We show that this boreal deciduous forest type is likely a resilient alternate state that will persist through the 21st century, which is important, because future vegetation outcomes will shape biophysical feedbacks to regional climate and influence subsequent disturbance regimes.

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Soil Bacterial and Fungal Response to Wildfires in the Canadian Boreal Forest Across a Burn Severity Gradient

Cited by 7 publications

References 87 publications

Ecological impacts of shortening fire return intervals on boreal peatlands and transition zones using integrated in situ field sampling and lidar approaches

Ecological impacts of shortening fire return intervals on boreal peatlands and transition zones using integrated in situ field sampling and lidar approaches

Biogeography of fire regimes in western U.S. conifer forests: A trait‐based approach

An alternate vegetation type proves resilient and persists for decades following forest conversion in the North American boreal biome

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