The predictability of near‐term forest biomass change in boreal North America

Burrell, Arden L.; Cooperdock, Sol; Potter, Stefano; Berner, Logan T.; Hember, Robert; Macander, Matthew J.; Walker, Xanthe J.; Massey, Richard; Foster, Adrianna C.; Mack, Michelle C.; Goetz, Scott J.; Rogers, Brendan

doi:10.1002/ecs2.4737

Ecosphere

2024

DOI: 10.1002/ecs2.4737

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The predictability of near‐term forest biomass change in boreal North America

Arden L. Burrell,

Sol Cooperdock,

Stefano Potter

et al.

Abstract: Climate change is driving substantial changes in North American boreal forests, including changes in productivity, mortality, recruitment, and biomass. Despite the importance for carbon budgets and informing management decisions, there is a lack of near‐term (5–30 year) forecasts of expected changes in aboveground biomass (AGB). In this study, we forecast AGB changes across the North American boreal forest using machine learning, repeat measurements from 25,000 forest inventory sites, and gridded geospatial da… Show more

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Integrating remotely sensed imagery in a forest gap model to study North American boreal forests in a changing world

Sundquist,

Lutz,

Foster

et al. 2024

Environ. Res.: Ecology

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Boreal forests of Alaska and Western Canada are experiencing rapid climate change characterized by higher temperatures, more extreme droughts, and changing disturbance regimes, resulting in forest mortality and composition changes. Mechanistic models are increasingly important for predicting future forest trends as the region experiences novel environmental change. Previously, many process-based models have generated starting conditions by ‘spinning up’ to equilibrium. However, setting appropriate initial conditions remains a persistent challenge in using mechanistic forest models, where stochastic events and latent parameters governing tree establishment have long-lasting impacts on simulation outcomes. Recent advances in remote sensing analysis provide information that can help address this issue. We updated an individual-based gap model, the University of Virginia Forest Model Enhanced (UVAFME), to include initial conditions derived from aerial and satellite imagery at two locations. Following these updates, material legacies (e.g., trees, seed banks, soil organic layer) allowed new forest types to persist in UVAFME simulations, landscape-level forest heterogeneity increased, and forest-wide biomass estimates increased. At both study sites, initialization from remotely sensed data had a strong impact on forest cover and volume. Climate change impacts were simulated decades earlier than when the model was ‘spun up'. In Alaska’s Tanana Valley State Forest, warmer climate scenarios drove deciduous expansion, increased drought stress, and resulted in a 28% decrease in overall biomass by 2100 between historical and high emissions climate scenarios. At a lowland site in Northern British Columbia, lodgepole pine (Pinus contorta) remained dominant and became more productive with exogenous climate forcing as temperature, nutrient, and flooding limitations decreased. These case studies demonstrate a new framework for forest modeling and emphasize the advantages of integrating remotely sensed data with mechanistic models, thereby laying groundwork for future research that explores near-term impacts of non-stationary ecological change.

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Integrating remotely sensed imagery in a forest gap model to study North American boreal forests in a changing world

Sundquist,

Lutz,

Foster

et al. 2024

Environ. Res.: Ecology

View full text Add to dashboard Cite

show abstract

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The predictability of near‐term forest biomass change in boreal North America

Cited by 1 publication

References 84 publications

Integrating remotely sensed imagery in a forest gap model to study North American boreal forests in a changing world

Integrating remotely sensed imagery in a forest gap model to study North American boreal forests in a changing world

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