CO2 fertilization plays a minor role in long-term carbon accumulation patterns in temperate pine forests in the southwestern Pyrenees

Lo, Yueh-Hsin; Blanco, Juan A.; Andrés, Ester González de; Imbert, J. Bosco; Castillo, Federico

doi:10.1016/j.ecolmodel.2019.108737

Cited by 14 publications

(8 citation statements)

References 108 publications

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“…Whereas increasing atmospheric CO 2 concentrations might directly promote forest productivity and growth (e.g. Keenan et al, 2011), this effect will be strongly modulated by increasing temperatures and drought conditions (Bussotti et al, 2014; Doblas‐Miranda et al, 2017; Lo et al, 2019; Penuelas et al, 2011). This might partly explain why median projected trends for the ‘materials and assistance’ category were more negative for scenarios below the Paris Agreement (Figure 2b), under which CO 2 forcing is smaller.…”

Section: Discussionmentioning

confidence: 99%

Ecosystem services provision by Mediterranean forests will be compromised above 2℃ warming

Morán-Ordóñez

Ramsauer

Coll

et al. 2021

Global Change Biology

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Forests provide a wide range of provisioning, regulating and cultural services of great value to societies across the Mediterranean basin. In this study, we reviewed the scientific literature of the last 30 years to quantify the magnitude of projected changes in ecosystem services provision by Mediterranean forests under IPCC climate change scenarios. We classified the scenarios according to the temperature threshold of 2℃ set by the Paris Agreement (below or above). The review of 78 studies shows that climate change will lead to a general reduction in the provision of regulating services (e.g. carbon storage, regulation of freshwater quantity and quality) and a general increase in the number of fires, burnt areas and generally, an increase in climate‐related forest hazards (median + 62% by 2100). Studies using scenarios above the 2℃ threshold projected significantly more negative changes in regulating services than studies using scenarios below this threshold. Main projected trend changes on material services (e.g. wood products), were less clear and depended on (i) whether or not the studies considered the interaction between the rise in temperatures and other drivers (e.g. forest management, CO2 fertilization) and (ii) differences in productivity responses across the tree species evaluated. Overall, the reviewed studies projected significant reductions in range extent and habitat suitability for the most drought‐sensitive forest species (e.g. −88% Fagus sylvatica), while the amount of habitat available for more drought‐tolerant species will remain stable or increase; however, the magnitude of projected change for these more xeric species was limited when high‐end extreme climatic scenarios were considered (above Paris Agreement). Our review highlights the benefits that climate change mitigation (to keep global mean temperature increase <2℃) can bring in terms of service provision and conservation of Mediterranean forests.

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Section: Discussionmentioning

confidence: 99%

Ecosystem services provision by Mediterranean forests will be compromised above 2℃ warming

Morán-Ordóñez

Ramsauer

Coll

et al. 2021

Global Change Biology

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“…(2017) simulated competition for nutrient, light and water in mixed conifer-broadleaf forests, whereas in this issue Lo et al (2019) demonstrated the low impact of increased CO2 availability in the productivity of pine forests. Both works used FORECAST Climate.…”

Section: Introductionmentioning

confidence: 89%

Modelling Forest Ecosystems: a crossroad between scales, techniques and applications

Blanco

Améztegui

Rodríguez

2020

Ecological Modelling

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into different modelling approaches to try to understand forest systems, from continental, regional or landscape-scales to individual-base models. Similarly, forest models have been developed at all kind of complexity levels, from very complex, integrative models to simpler models focused on one specific ecophysiological process. Thus, continuous efforts by the forest modelling community have provided a wealth of research and expertise, but at the same time have generated a dispersion and lack of linkages between different modelling approaches and applications.Forest science is integrative by nature: understanding climate, soil and water processes is as important as understanding plant eco-physiology to understand how forests work. Therefore, forest science has evolved during the last centuries to understand how trees and forests grow, and which patterns and processes rule their development through time and space. Following the common scientific method, empirical reductionist approaches tried to isolate and study one ecological factor or variable at a time (Popper 1968), trying to reduce the complexity inherent to ecological processes. On the contrary, theoretical ecological models explore the ecological interactions among the components that exist in a forest, assembling the pieces of evidence generated through traditional field and lab work (Kimmins et al. 2010). In this special issue, we want to show some of the latest developments in forest modelling, understanding forests like working systems in which human intervention has played and is still playing a historical role, and will likely do so in the future.Following the sharp increase in data availability, modelling is now being applied in forest ecosystems at multiple scales, from continental and regional studies on forests and species distribution to leaf scales modelling plague and pathogen infestation in individual branches. Similarly, models are being applied to understand short-time processes such as nutrient transport in cells, to extremely long scales such as genetic drift in tree populations. From the application point of view, models are also being applied from purely ecological issues, such as coexistence and resource competition among tree species, to multidisciplinary socio-economic-ecological issues, such as design of tourist routes inside natural reserves, estimating timber flow to sawmills under climate change scenarios, or engineering concerns such as designing forest harvesting machinery with lower ecological footprint (in energy, rut formation, noise, etc.).When organizing this special issue, we (the guest editors) decided to carry out a quick overview of current trends in forest modelling. To do so, we used Clarivate's Web of Science to carry out a search in the top five journals with "Forestry" as their unique category

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“…For this reason, they represent promising prospects for understanding and predicting forest ecosystems functioning changes. Studies have already tried to predict trends of forest productivity (Madani et al, 2018;Prislan et al, 2019;Tei et al, 2017), carbon storage (Gustafson et al, 2017;Lindner et al, 2014;Lo et al, 2019) or C, H2O and N dynamics (Dong et al, 2019) in the decades to come.…”

Section: Process-based Model Prediction In Context Of Global Changementioning

confidence: 99%

Reliable predictions of forest ecosystem functioning require flawless climate forcings

Jourdan

François

Delpierre

et al. 2021

Agricultural and Forest Meteorology

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CO2 fertilization plays a minor role in long-term carbon accumulation patterns in temperate pine forests in the southwestern Pyrenees

Cited by 14 publications

References 108 publications

Ecosystem services provision by Mediterranean forests will be compromised above 2℃ warming

Ecosystem services provision by Mediterranean forests will be compromised above 2℃ warming

Modelling Forest Ecosystems: a crossroad between scales, techniques and applications

Reliable predictions of forest ecosystem functioning require flawless climate forcings

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