Releasing global forests from human management: How much more carbon could be stored?

Roebroek, Caspar T. J.; Duveiller, Grégory; Seneviratne, Sonia I.; Davin, Edouard L.; Cescatti, Alessandro

doi:10.1126/science.add5878

Cited by 43 publications

(25 citation statements)

References 39 publications

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“…We establish the long-term persistence of the global forest carbon sink by estimating the above-ground biomass carrying capacity (BCC) under present and future climatic conditions (Roebroek 2024). BCC is the biomass of a forest 'under prevailing environmental conditions and natural disturbance regimes, but excluding anthropogenic disturbance' (Keith et al 2009, Roebroek et al 2023. Under the assumption that human influences (e.g.…”

Section: Methodsmentioning

confidence: 99%

“…The estimates of BCC are made with a modular machine learning model framework. It is based on a simplified model definition, expanding on previous work (Roebroek et al 2023). It describes changes in BCC as a product of growth potential (B p , potential biomass), natural disturbance regime ((1 − D), fraction of potential biomass that is expected to be sustainable under given climate conditions) and CO 2 fertilization (F CO2 , a factor adapting potential biomass and the disturbance regime to enhanced CO 2 scenarios, systematically larger than 1):…”

Section: Methodsmentioning

confidence: 99%

“…Hyperparameters were chosen with a grid-based 5-fold cross validation approach, minimizing the pinball loss (with alpha set to 0.995) for the predictions of PRB. This procedure is described in more detail in Roebroek et al (2023) and visualized in figure 1.…”

Section: Methodsmentioning

confidence: 99%

“…The original model description in Roebroek et al (2023) was purely based on current environmental conditions, for which various predictors are available. In order to transpose the model framework to future climate scenarios, the set of environmental predictors had to be adapted.…”

Section: Methodsmentioning

confidence: 99%

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Climate policies for carbon neutrality should not rely on the uncertain increase of carbon stocks in existing forests

Roebroek,

Caporaso,

Alkama

et al. 2024

Environ. Res. Lett.

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The international community, through treaties such as the Paris Agreement, aims to limit climate change to well below 2°C, which implies reaching carbon neutrality around the second half the century. In the current calculations underpinning the various roadmaps toward carbon neutrality, a major component is a steady or even expanding terrestrial carbon sink, supported by an increase of global forest biomass. However, recent research has challenged this view. Here we developed a framework that assesses the potential global equilibrium of forest biomass under different climate change scenarios. Results show that under global warming carbon storage potential in forest aboveground biomass gradually shifts to higher latitudes and the intensity of the disturbance regimes increases significantly almost everywhere. CO2 fertilization stands out as the most uncertain process, with different methods of estimation leading to diverging results by almost 155 PgC of above ground biomass at equilibrium. Overall, assuming that the sum of human pressures (e.g., wood extraction) does not change over time, that total forest cover does not change significantly and that the trend in CO2 fertilisation as it is currently estimated from satellite proxy observations remains, results show that we have reached (or are very close to reaching) the peak of global forest carbon storage. In the short term, where increased disturbance regimes are assumed to act quicker than increased forest growth potential, global forests might instead act as a carbon source, that will require even more effort in decarbonization than previously estimated. Therefore, the potential of forests as a nature-based solution to mitigate climate change brings higher uncertainties and risks than previously thought.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

See 2 more Smart Citations

Climate policies for carbon neutrality should not rely on the uncertain increase of carbon stocks in existing forests

Roebroek,

Caporaso,

Alkama

et al. 2024

Environ. Res. Lett.

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“…Forests play an important role in shaping climate conditions from local to global scales by mediating greenhouse gas, water and energy fluxes between the land and the atmosphere (Davin and Noblet-Ducoudré 2010, Teuling et al 2017, O'Connor et al 2021, Roebroek et al 2023. In addition, tree canopies create distinct climatic conditions in the forest understory, which are typically referred to as the forest microclimate (Geiger et al 2009).…”

Section: Introductionmentioning

confidence: 99%

Projecting future forest microclimate using a land surface model

Hes,

Vanderkelen,

Fisher

et al. 2024

Environ. Res. Lett.

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The forest understory experiences temperature variations that are dampened compared to adjacent open areas, allowing the development of a forest microclimate and associated ecological conditions. It is however unclear to what extent forests will maintain this buffering effect under increasing global warming. Providing reliable projections of future forest microclimates is therefore crucial to anticipate climate change impacts on forest biodiversity, and to identify corresponding conservation strategies. Recent empirical studies suggest that the buffering of air temperature extremes in forest understory compared to open land could increase with global warming, albeit at a slower rate than macroclimate temperatures. Here, we investigate the trend of this temperature buffering effect in a high-emission global warming scenario, using the process-based Land Surface Model CLM5.1. We find biome-dependant buffering trends with strongest values in tropical forests where buffering increases for every degree of global warming by 0.1 °C for maximum soil temperature, and by 0.2 °C for maximum canopy air temperature. In boreal regions, forest microclimate exhibits a strong seasonality and the effect of global warming is more uncertain. Thus, our results highlight the specific importance of tropical forest canopies in particular, in maintaining hospitable conditions for understory species while increasing their climate debt under global warming. Our research also illustrates the potential and limitations of LSMs to simulate forest microclimate, and calls for further collaborations between Earth system modelers and ecologists to jointly question climate and biosphere dynamics.

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Multiscale modeling for enhanced battery health analysis: Pathways to longevity

Yang,

Zhang,

Wang

et al. 2024

Carbon Neutralization

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The issues of health assessment and lifespan prediction have always been prominent challenges in the large‐scale application of lithium‐ion batteries (LIBs). This paper reviews the multiscale modeling techniques and their applications in battery health analysis, including atomic scale computational chemistry, particle scale reaction simulations, electrode scale structural models, macroscale electrochemical models, and data‐driven models at the system level. Multiscale modeling offers a profound insight into material behavior and the aging process of batteries, thereby providing a valuable reference for both estimation and management strategies of battery state of health. To extend the battery lifespan, the utilization of artificial intelligence for material discovery and manufacturing process optimization, the implementation of end‐cloud collaborative battery management systems, and the design of a multiscale simulation integration platform are considered. A management framework aimed at extending battery life is further proposed. This framework offers a promising roadmap for addressing health analysis challenges in LIBs, ultimately leading to more reliable, efficient, and durable solutions for next‐generation batteries.

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Releasing global forests from human management: How much more carbon could be stored?

Cited by 43 publications

References 39 publications

Climate policies for carbon neutrality should not rely on the uncertain increase of carbon stocks in existing forests

Climate policies for carbon neutrality should not rely on the uncertain increase of carbon stocks in existing forests

Projecting future forest microclimate using a land surface model

Multiscale modeling for enhanced battery health analysis: Pathways to longevity

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