Unusual forest growth decline in boreal North America covaries with the retreat of Arctic sea ice

Girardin, Martin P.; Guo, Xingqi; Jong, Rogier de; Kinnard, Christophe; Bernier, Pierre Y.; Raulier, Frédéric

doi:10.1111/gcb.12400

Cited by 82 publications

(90 citation statements)

References 93 publications

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“…The high sensitivity to temperature observed during the late 20th century in eastern forests (Fig. 6A), parallel with rapid warming and growth decline, may reflect a temperature-dependent increase in respiration and depletion in carbon reserves, as was recently suggested by process-based modeling of productivity in black spruce stands (16). Such temperature responses are not static, and plants have the capacity to adjust to a warming environment via physiological acclimation (33).…”

Section: Regional Variation In Growth Trends From Tree Rings Show Modmentioning

confidence: 67%

“…Adding to this uncertainty is the discrepancy over recent changes in the productivity of boreal and other northern latitude forests. Some empirical evidence suggests increases in the forest productivity (12)(13)(14), whereas other studies suggest decreasing productivity over the last decades (7,8,(15)(16)(17). Furthermore, inversion and process-based ecosystem models indicate large carbon sinks (7,8), whereas field-based bottom-up approaches suggest smaller carbon sinks or small carbon sources (3, 18), or large sinks (19).…”

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confidence: 99%

“…However, a recent comparison of commonly used NDVI datasets showed marked differences in their representation of mean seasonal vegetation productivity and decadal-long trends (21), which stresses the necessity for large-scale, ground-based observations. Ground-based observations of vegetation productivity may originate from permanent sample plots (13,17) or from tree-ring analyses (12,14,16,23), which differ in the temporal resolution (decadal vs. annual) and spatial scale (stand vs. tree). Both are prone to bias because of unbalanced spatial sampling.…”

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confidence: 99%

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No growth stimulation of Canada’s boreal forest under half-century of combined warming and CO ₂ fertilization

Girardin

Bouriaud

Hogg

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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251

246

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Considerable evidence exists that current global temperatures are higher than at any time during the past millennium. However, the long-term impacts of rising temperatures and associated shifts in the hydrological cycle on the productivity of ecosystems remain poorly understood for mid to high northern latitudes. Here, we quantify species-specific spatiotemporal variability in terrestrial aboveground biomass stem growth across Canada's boreal forests from 1950 to the present. We use 873 newly developed tree-ring chronologies from Canada's National Forest Inventory, representing an unprecedented degree of sampling standardization for a largescale dendrochronological study. We find significant regional-and species-related trends in growth, but the positive and negative trends compensate each other to yield no strong overall trend in forest growth when averaged across the Canadian boreal forest. The spatial patterns of growth trends identified in our analysis were to some extent coherent with trends estimated by remote sensing, but there are wide areas where remote-sensing information did not match the forest growth trends. Quantifications of tree growth variability as a function of climate factors and atmospheric CO 2 concentration reveal strong negative temperature and positive moisture controls on spatial patterns of tree growth rates, emphasizing the ecological sensitivity to regime shifts in the hydrological cycle. An enhanced dependence of forest growth on soil moisture during the late-20th century coincides with a rapid rise in summer temperatures and occurs despite potential compensating effects from increased atmospheric CO 2 concentration. drought impacts | climate change | dendrochronology | normalized difference vegetation index | ecology C ircumpolar boreal forests are estimated to store ∼53.9 Pg of carbon or ∼14% of terrestrial vegetation biomass (1). These regions are currently experiencing accelerated changes, including warmer and longer growing seasons, tree line expansion, species migration, increased frequency and severity of drought, and increases in the frequency and severity of disturbances (2-10). These changes create uncertainty about the boreal forests' future role in the global carbon cycle (11). Adding to this uncertainty is the discrepancy over recent changes in the productivity of boreal and other northern latitude forests. Some empirical evidence suggests increases in the forest productivity (12)(13)(14), whereas other studies suggest decreasing productivity over the last decades (7,8,(15)(16)(17). Furthermore, inversion and process-based ecosystem models indicate large carbon sinks (7,8), whereas field-based bottom-up approaches suggest smaller carbon sinks or small carbon sources (3, 18), or large sinks (19). Quantifying

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Section: Regional Variation In Growth Trends From Tree Rings Show Modmentioning

confidence: 67%

mentioning

confidence: 99%

mentioning

confidence: 99%

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No growth stimulation of Canada’s boreal forest under half-century of combined warming and CO ₂ fertilization

Girardin

Bouriaud

Hogg

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

251

246

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“…As large fires are generally more severe than small ones (19), models predict than aspen abundance will increase in a future with more fires, thus potentially strengthening the negative feedback on burn rates (15,41,42). Boreal forest productivity may also increase or decrease directly with climate change (43)(44)(45), further suggesting the negative feedback on burn rates may not be stationary through time. Geographic differences may also exist across the boreal biome.…”

Section: Resultsmentioning

confidence: 99%

Resistance of the boreal forest to high burn rates

Héon

Arseneault

Parisien

2014

Proc. Natl. Acad. Sci. U.S.A.

138

153

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Boreal ecosystems and their large carbon stocks are strongly shaped by extensive wildfires. Coupling climate projections with records of area burned during the last 3 decades across the North American boreal zone suggests that area burned will increase by 30-500% by the end of the 21st century, with a cascading effect on ecosystem dynamics and on the boreal carbon balance. Fire size and the frequency of large-fire years are both expected to increase. However, how fire size and time since previous fire will influence future burn rates is poorly understood, mostly because of incomplete records of past fire overlaps. Here, we reconstruct the length of overlapping fires along a 190-km-long transect during the last 200 y in one of the most fire-prone boreal regions of North America to document how fire size and time since previous fire will influence future fire recurrence. We provide direct field evidence that extreme burn rates can be sustained by a few occasional droughts triggering immense fires. However, we also show that the most fire-prone areas of the North American boreal forest are resistant to high burn rates because of overabundant young forest stands, thereby creating a fuel-mediated negative feedback on fire activity. These findings will help refine projections of fire effect on boreal ecosystems and their large carbon stocks.climate change | fire-free intervals | fuel feedback | probability of burning | tree ring dating

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“…Examples of these effects are shown for enhanced growth of Norway spruce (Picea abies) in forest productivity studies in Sweden and Finland [4]. However, negative effects have been observed on poor sites, decreasing growth [13] or increasing mortality of trees [14] especially under heat or drought stress [15], as a combined effect of temperature (increase) and precipitation (decrease).…”

Section: Impacts On Forest Growth and Productivitymentioning

confidence: 99%

Climate Change and Decision-Making Under Uncertainty

Yousefpour

Hanewinkel

2016

Curr Forestry Rep

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This paper highlights the main risks and uncertainties associated with climate change in forest management. The overarching challenge is the deep uncertainty about the future direction of changes in climate denoted by representative concentration pathways (RCPs). Moreover, climate change poses new sources of risk from frequent, more intensive, and even novel disturbances in forest ecosystems. Adaptation strategies have been developed to guarantee resistance of forests to climate change and impacts, but they are mostly valid for a restricted set of climate outcomes in the future. Therefore, alternative decision-making approaches should be found to overcome the deep uncertainty about future climate development and adapt forests to future environmental conditions. We propose two decision-making approaches; portfolio diversification and robust decisionmaking (RDM) to solve both problems. Portfolio management is an established concept in forest utilization and requires diversification of forest structures by e.g., admixing new species, or applying different sets of silvicultural interventions. Robust decision-making is a unique approach to deal with the deep uncertainty in general, but has rarely been applied to forest management. Recent adaptations of RDM to risk management under climate change provide a good basis for application in forestry. We outline the details of RDM to this end with an example, and highly recommend its application. Finally, a consensus among politicians on a climate target, e.g., Paris agreement, may diminish the deep uncertainty about the degree of climatic change at the end of the century. However, actions pathways, i.e., scenarios to meet the climate target would stay deeply uncertain for long.

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Unusual forest growth decline in boreal North America covaries with the retreat of Arctic sea ice

Cited by 82 publications

References 93 publications

No growth stimulation of Canada’s boreal forest under half-century of combined warming and CO ₂ fertilization

No growth stimulation of Canada’s boreal forest under half-century of combined warming and CO ₂ fertilization

Resistance of the boreal forest to high burn rates

Climate Change and Decision-Making Under Uncertainty

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Unusual forest growth decline in boreal North America covaries with the retreat of Arctic sea ice

Cited by 82 publications

References 93 publications

No growth stimulation of Canada’s boreal forest under half-century of combined warming and CO 2 fertilization

No growth stimulation of Canada’s boreal forest under half-century of combined warming and CO 2 fertilization

Resistance of the boreal forest to high burn rates

Climate Change and Decision-Making Under Uncertainty

Contact Info

Product

Resources

About

No growth stimulation of Canada’s boreal forest under half-century of combined warming and CO ₂ fertilization

No growth stimulation of Canada’s boreal forest under half-century of combined warming and CO ₂ fertilization