Topographic information improves simulated patterns of post‐fire conifer regeneration in the southwest United States

Jung, Chang Gyo; Keyser, Alisa R.; Remy, Cécile C.; Krofcheck, D. J.; Hurteau, Matthew D.

doi:10.1111/gcb.16764

Cited by 3 publications

(2 citation statements)

References 83 publications

(129 reference statements)

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“…Simultaneously, increasing aridification is making forests more flammable as dead fuels become increasingly available to burn (Goodwin et al, 2020(Goodwin et al, , 2021Juang et al, 2022). High-severity fire combined with warmer and drier conditions is already decreasing conifer regeneration in the western United States (Stevens-Rumann et al, 2018) and projections under future climate show limited conifer regeneration following high-severity wildfire in southwestern US forests (Jung et al, 2023;Keyser et al, 2020). A greater increase in high-severity fires occurring at high elevation in mixed-conifer forests compared with lower elevations is also expected, leading to high mortality of the dominant species, Engelmann spruce and subalpine fire, which are not adapted to fire (Cassell et al, 2019;Flatley & Fulé, 2016;Remy et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Restoring frequent fire to dry conifer forests delays the decline of subalpine forests in the southwest United States under projected climate

Remy,

Krofcheck,

Keyser

et al. 2024

Journal of Applied Ecology

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In southwestern US forests, the combined impact of climate change and increased fuel loads due to more than a century of human‐caused fire exclusion is leading to larger and more severe wildfires. Restoring frequent fire to dry conifer forests can mitigate high‐severity fire risk, but the effects of these treatments on the vegetation composition and structure under projected climate change remain uncertain. We used a forest landscape model to assess the impact of thinning and prescribed burns in dry conifer forests across an elevation gradient, encompassing low‐elevation pinyon‐juniper woodlands, mid‐elevation ponderosa pine and high‐elevation mixed‐conifer forests. Our results demonstrated that the treatments decreased the probability of high‐severity fires by 42% in the study area. At low elevation, the treatments did not prevent loss in forest cover and biomass with decreases in Pinus edulis and Juniperus monosperma abundances. At mid‐elevation, changes in fire effects maintained a greater diversity of tree species by favouring the maintenance of cohorts of old trees, in particular Pinus ponderosa which accumulated 5.41 Mg ha−1 more above‐ground biomass than without treatments by late‐century. Treatments in dry conifer forests modified fire effects beyond the treated area, resulting in increased cover and biomass of old Picea englemannii and Abies lasiocarpa cohorts. Synthesis and applications: Our findings indicate that thinning and prescribed burning can enhance tree species diversity in dry conifer forests by protecting old cohorts from stand‐replacing fires. Moreover, our results suggest that treatments mainly implemented in dry pine forests with high risk of high‐severity fires can be beneficial for subalpine species conservation by reducing the chance that high‐severity fire at mid‐elevation is transmitted into high‐elevation forest.

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Section: Introductionmentioning

confidence: 99%

Restoring frequent fire to dry conifer forests delays the decline of subalpine forests in the southwest United States under projected climate

Remy,

Krofcheck,

Keyser

et al. 2024

Journal of Applied Ecology

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“…Even with successful seedling establishment, post-disturbance tree survival can be precarious for multiple years (White, 1985), and survival may be further impeded by subsequent climate extremes (Kemp et al, 2019;Urli et al, 2023). Survival of juvenile trees can be highly sensitive to temperature-related factors of microclimate, such as vapor pressure deficit (Crockett and Hurteau, 2022) and heat load index (Marsh et al, 2022;Jung et al, 2023). Previous studies have addressed seedling recruitment under changing climate (Davis et al, 2019;Kemp et al, 2019;Bailey et al, 2021;Nelson et al, 2021;Stewart et al, 2021), yet few have examined drivers of mortality in subsequently established juvenile trees (e.g., Rother and Veblen, 2016).…”

Section: Introductionmentioning

confidence: 99%

Mortality thresholds of juvenile trees to drought and heatwaves: implications for forest regeneration across a landscape gradient

Lalor,

Law,

Breshears

et al. 2023

Front. For. Glob. Change

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Tree loss is increasing rapidly due to drought- and heat-related mortality and intensifying fire activity. Consequently, the fate of many forests depends on the ability of juvenile trees to withstand heightened climate and disturbance anomalies. Extreme climatic events, such as droughts and heatwaves, are increasing in frequency and severity, and trees in mountainous regions must contend with these landscape-level climate episodes. Recent research focuses on how mortality of individual tree species may be driven by drought and heatwaves, but how juvenile mortality under these conditions would vary among species spanning an elevational gradient—given concurrent variation in climate, ecohydrology, and physiology–remains unclear. We address this knowledge gap by implementing a growth chamber study, imposing extreme drought with and without a compounding heatwave, for juveniles of five species that span a forested life zones in the Southwestern United States. Overall, the length of a progressive drought required to trigger mortality differed by up to 20 weeks among species. Inclusion of a heatwave hastened mean time to mortality for all species by about 1 week. Lower-elevation species that grow in warmer ambient conditions died earlier (Pinus ponderosa in 10 weeks, Pinus edulis in 14 weeks) than did higher-elevation species from cooler ambient conditions (Picea engelmannii and Pseudotsuga menziesii in 19 weeks, and Pinus flexilis in 30 weeks). When exposed to a heatwave in conjunction with drought, mortality advanced significantly only for species from cooler ambient conditions (Pinus flexilis: 2.7 weeks earlier; Pseudotsuga menziesii: 2.0 weeks earlier). Cooler ambient temperatures may have buffered against moisture loss during drought, resulting in longer survival of higher-elevation species despite expected drought tolerance of lower-elevation species due to tree physiology. Our study suggests that droughts will play a leading role in juvenile tree mortality and will most directly impact species at warmer climate thresholds, with heatwaves in tandem with drought potentially exacerbating mortality especially of high elevation species. These responses are relevant for assessing the potential success of both natural and managed reforestation, as differential juvenile survival following episodic extreme events will determine future landscape-scale vegetation trajectories under changing climate.

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Abiotic Factors Modify Ponderosa Pine Regeneration Outcomes After High-Severity Fire

Willson,

Hurteau

2024

Ecosystems

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Topographic information improves simulated patterns of post‐fire conifer regeneration in the southwest United States

Cited by 3 publications

References 83 publications

Restoring frequent fire to dry conifer forests delays the decline of subalpine forests in the southwest United States under projected climate

Restoring frequent fire to dry conifer forests delays the decline of subalpine forests in the southwest United States under projected climate

Mortality thresholds of juvenile trees to drought and heatwaves: implications for forest regeneration across a landscape gradient

Abiotic Factors Modify Ponderosa Pine Regeneration Outcomes After High-Severity Fire

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