Your search keyword '"Dufrêne, Eric"' showing total 6 results

1. Environmental control of carbon allocation matters for modelling forest growth.

Author

Guillemot J, Francois C, Hmimina G, Dufrêne E, Martin-StPaul NK, Soudani K, Marie G, Ourcival JM, and Delpierre N

Subjects

Calibration, Photosynthesis, Plant Leaves anatomy & histology, Plant Leaves physiology, Seasons, Time Factors, Wood growth & development, Carbon metabolism, Environment, Forests, Models, Biological, Plant Development

Abstract

We aimed to evaluate the importance of modulations of within-tree carbon (C) allocation by water and low-temperature stress for the prediction of annual forest growth with a process-based model. A new C allocation scheme was implemented in the CASTANEA model that accounts for lagged and direct environmental controls of C allocation. Different approaches (static vs dynamic) to modelling C allocation were then compared in a model-data fusion procedure, using satellite-derived leaf production estimates and biometric measurements at c. 10 4 sites. The modelling of the environmental control of C allocation significantly improved the ability of CASTANEA to predict the spatial and year-to-year variability of aboveground forest growth along regional gradients. A significant effect of the previous year's water stress on the C allocation to leaves and wood was reported. Our results also are consistent with a prominent role of the environmental modulation of sink demand in the wood growth of the studied species. Data available at large scales can inform forest models about the processes driving annual and seasonal C allocation. Our results call for a greater consideration of C allocation drivers, especially sink-demand fluctuations, for the simulations of current and future forest productivity with process-based models., (© 2016 The Authors. New Phytologist © 2016 New Phytologist Trust.)

Published

2017

2. Wood phenology, not carbon input, controls the interannual variability of wood growth in a temperate oak forest.

Author

Delpierre N, Berveiller D, Granda E, and Dufrêne E

Subjects

Biomass, Dehydration, Seasons, Carbon metabolism, Forests, Quercus growth & development, Quercus metabolism, Wood growth & development, Wood metabolism

Abstract

Although the analysis of flux data has increased our understanding of the interannual variability of carbon inputs into forest ecosystems, we still know little about the determinants of wood growth. Here, we aimed to identify which drivers control the interannual variability of wood growth in a mesic temperate deciduous forest. We analysed a 9-yr time series of carbon fluxes and aboveground wood growth (AWG), reconstructed at a weekly time-scale through the combination of dendrometer and wood density data. Carbon inputs and AWG anomalies appeared to be uncorrelated from the seasonal to interannual scales. More than 90% of the interannual variability of AWG was explained by a combination of the growth intensity during a first 'critical period' of the wood growing season, occurring close to the seasonal maximum, and the timing of the first summer growth halt. Both atmospheric and soil water stress exerted a strong control on the interannual variability of AWG at the study site, despite its mesic conditions, whilst not affecting carbon inputs. Carbon sink activity, not carbon inputs, determined the interannual variations in wood growth at the study site. Our results provide a functional understanding of the dependence of radial growth on precipitation observed in dendrological studies., (© 2015 The Authors. New Phytologist © 2015 New Phytologist Trust.)

Published

2016

3. Assessing the effects of management on forest growth across France: insights from a new functional-structural model.

Author

Guillemot J, Delpierre N, Vallet P, François C, Martin-StPaul NK, Soudani K, Nicolas M, Badeau V, and Dufrêne E

Subjects

Biomass, Climate Change, Computer Simulation, Dehydration, Ecosystem, Fagus anatomy & histology, Fagus growth & development, Fagus physiology, Forests, France, Quercus anatomy & histology, Quercus growth & development, Quercus physiology, Trees anatomy & histology, Trees physiology, Carbon metabolism, Models, Biological, Trees growth & development

Abstract

Background and Aims: The structure of a forest stand, i.e. the distribution of tree size features, has strong effects on its functioning. The management of the structure is therefore an important tool in mitigating the impact of predicted changes in climate on forests, especially with respect to drought. Here, a new functional-structural model is presented and is used to assess the effects of management on forest functioning at a national scale., Methods: The stand process-based model (PBM) CASTANEA was coupled to a stand structure module (SSM) based on empirical tree-to-tree competition rules. The calibration of the SSM was based on a thorough analysis of intersite and interannual variability of competition asymmetry. The coupled CASTANEA-SSM model was evaluated across France using forest inventory data, and used to compare the effect of contrasted silvicultural practices on simulated stand carbon fluxes and growth., Key Results: The asymmetry of competition varied consistently with stand productivity at both spatial and temporal scales. The modelling of the competition rules enabled efficient prediction of changes in stand structure within the CASTANEA PBM. The coupled model predicted an increase in net primary productivity (NPP) with management intensity, resulting in higher growth. This positive effect of management was found to vary at a national scale across France: the highest increases in NPP were attained in forests facing moderate to high water stress; however, the absolute effect of management on simulated stand growth remained moderate to low because stand thinning involved changes in carbon allocation at the tree scale., Conclusions: This modelling approach helps to identify the areas where management efforts should be concentrated in order to mitigate near-future drought impact on national forest productivity. Around a quarter of the French temperate oak and beech forests are currently in zones of high vulnerability, where management could thus mitigate the influence of climate change on forest yield.

Published

2014

4. Modeling annual production and carbon fluxes of a large managed temperate forest using forest inventories, satellite data and field measurements.

Author

Le Maire G, Davi H, Soudani K, François C, Le Dantec V, and Dufrêne E

Subjects

Climate, Computer Simulation, Ecosystem, France, Trees anatomy & histology, Trees metabolism, Wood growth & development, Carbon metabolism, Models, Biological, Satellite Communications, Trees growth & development

Abstract

We evaluated annual productivity and carbon fluxes over the Fontainebleau forest, a large heterogeneous forest region of 17,000 ha, in terms of species composition, canopy structure, stand age, soil type and water and mineral resources. The model is a physiological process-based forest ecosystem model coupled with an allocation model and a soil model. The simulations were done stand by stand, i.e., 2992 forest management units of simulation. Some input parameters that are spatially variable and to which the model is sensitive were calculated for each stand from forest inventory attributes, a network of 8800 soil pits, satellite data and field measurements. These parameters are: (1) vegetation attributes: species, age, height, maximal leaf area index of the year, aboveground biomass and foliar nitrogen content; and (2) soil attributes: available soil water capacity, soil depth and soil carbon content. Main outputs of the simulations are wood production and carbon fluxes on a daily to yearly basis. Results showed that the forest is a carbon sink, with a net ecosystem exchange of 371 g C m(-2) year(-1). Net primary productivity is estimated at 630 g C m(-2) year(-1) over the entire forest. Reasonably good agreement was found between simulated trunk relative growth rate (2.74%) and regional production estimated from the National Forest Inventory (IFN) (2.52%), as well as between simulated and measured annual wood production at the forest scale (about 71,000 and 68,000 m(3) year(-1), respectively). Results are discussed species by species.

Published

2005

5. The 2018 European heatwave led to stem dehydration but not to consistent growth reductions in forests

Author

Salomón, Roberto L., Peters, Richard L., Zweifel, Roman, Sass-Klaassen, Ute G.W., Stegehuis, Annemiek I., Smiljanic, Marko, Poyatos, Rafael, Babst, Flurin, Cienciala, Emil, Fonti, Patrick, Lerink, Bass J.W., Lindner, Marcus, Martínez-Vilalta, Jordi, Mencuccini, Maurizio, Nabuurs, Gert-Jan, van der Maaten, Ernst, von Arx, Georg, Bär, Andreas, Akhmetzyanov, Linar, Balanzategui, Daniel, Bellan, Michal, Bendix, Jörg, Berveiller, Daniel, Blaženec, Miroslav, Čada, Vojtěch, Carraro, Vinicio, Cecchini, Sébastien, Chan, Tommy, Conedera, Marco, Delpierre, Nicolas, Delzon, Sylvain, Ditmarová, Lubica, Dolezal, Jiri, Dufrêne, Eric, Edvardsson, Johannes, Ehekircher, Stefan, Forner, Alicia, Frouz, Jan, Ganthaler, Andrea, Gryc, Vladimír, Güney, Aylin, Heinrich, Ingo, Hentschel, Rainer, Janda, Pavel, Ježík, Marek, Kahle, Hans-Peter, Knüsel, Simon, Krejza, Jan, Kuberski, Łukasz, Kučera, Jiří, Lebourgeois, François, Mikoláš, Martin, Matula, Radim, Mayr, Stefan, Oberhuber, Walter, Obojes, Nikolaus, Osborne, Bruce, Paljakka, Teemu, Plichta, Roman, Rabbel, Inke, Rathgeber, Cyrille B.K., Salmon, Yann, Saunder, Matthew, Scharnweber, Tobias, Sitková, Zuzana, Stangler, Dominik Florian, Stereńczak, Krzysztof, Stereńczak, Marko, Střelcová, Katarína, Světlík, Jan, Svodoba, Miroslav, Tobin, Brian, Trotsiuk, Volodymyr, Urban, Josef, Valladares Ros, Fernando, Vavrčík, Hanuš, Vejpustková, Monika, Walthert, Lorenz, Wilmking, Martin, Zin, Ewa, Zou, Junliang, Steppe, Kathy, Institute for Atmospheric and Earth System Research (INAR), Ecosystem processes (INAR Forest Sciences), Department of Forest Sciences, University of Helsinki, Viikki Plant Science Centre (ViPS), Micrometeorology and biogeochemical cycles, Ministerio de Ciencia e Innovación (España), Swiss National Science Foundation, and Ministerio de Economía y Competitividad (España)

Subjects

Agriculture and Food Sciences, Climate, Ecophysiology, Bos- en Landschapsecologie, General Physics and Astronomy, Forests, Trees, CARBON, Soil, HYDRAULIC SAFETY MARGINS, ECOSYSTEMS, Forest and Landscape Ecology, SAP FLOW, Plant ecology, TEMPERATURE, DROUGHT, 4112 Forestry, Multidisciplinary, PRODUCTIVITY, Dehydration, Ecology, Norway, Climate-change ecology, Pinus sylvestris, PE&RC, Droughts, SUMMER, Vegetatie, Bos- en Landschapsecologie, Climate Research, Infrared Rays, Climate Change, Science, Article, General Biochemistry, Genetics and Molecular Biology, TREE WATER-DEFICIT, Life Science, Bosecologie en Bosbeheer, Picea, Vegetatie, 1172 Environmental sciences, Ecosystem, Vegetation, Water, Forest Science, General Chemistry, Heat, Forest Ecology and Forest Management, Vegetation, Forest and Landscape Ecology, Forest ecology, RESPONSES

Abstract

Heatwaves exert disproportionately strong and sometimes irreversible impacts on forest ecosystems. These impacts remain poorly understood at the tree and species level and across large spatial scales. Here, we investigate the effects of the record-breaking 2018 European heatwave on tree growth and tree water status using a collection of high-temporal resolution dendrometer data from 21 species across 53 sites. Relative to the two preceding years, annual stem growth was not consistently reduced by the 2018 heatwave but stems experienced twice the temporary shrinkage due to depletion of water reserves. Conifer species were less capable of rehydrating overnight than broadleaves across gradients of soil and atmospheric drought, suggesting less resilience toward transient stress. In particular, Norway spruce and Scots pine experienced extensive stem dehydration. Our high-resolution dendrometer network was suitable to disentangle the effects of a severe heatwave on tree growth and desiccation at large-spatial scales in situ, and provided insights on which species may be more vulnerable to climate extremes., This work utilised the network of dendrometer observations established by the COST Action network STReESS (grant FP1106). We acknowledge the involved networks TreeNet, Swiss Long-term Forest Ecosystem Research Programme LWF, French National Network for Long-term FOrest ECOsystem Monitoring RENECOFOR, the German Long Term Ecosystem Research Network LTER-D, the Italian Long Term Ecosystem Research Network ILTER, the Integrated Carbon Observation System ICOS and Tree-Watch.net. R.L.S. acknowledges funding from the Special Research Fund (BOF) of Ghent University for Postdoctoral Fellowships and the Spanish Ministry of Science, Innovation, and Universities (Juan de la Cierva Programme, grant IJC2018-036123-I). R.L.P., R.Z., P.F., and G.v.A. acknowledge funding from the Federal Office for the Environment FOEN (00.0365.PZ I 0427-0562, 09.0064.PJ/R301-0223; project treenet.info) and the Swiss National Science Foundation SNF (20FI21_148992, 20FI_173691, P2BSP3_184475; project LOTFOR 150205 and Grant 20FI20_173691; project ICOS-CH). J.M.V. and M.M. acknowledge funding from the Spanish MINECO via competitive grants CGL2013-46808-R and CGL2017-89149-C2-1-R. R.P. acknowledges funding from the grant RTI2018-095297-J-I00 (Spain) and by a Humboldt Research Fellowship for Experienced Researchers (Germany).

Published

2022

6. Comparison of seasonal variations in water-use efficiency calculated from the carbon isotope composition of tree rings and flux data in a temperate forest.

Author

MICHELOT, ALICE, EGLIN, THOMAS, DUFRÊNE, ERIC, LELARGE-TROUVERIE, CAROLINE, and DAMESIN, CLAIRE

Subjects

FORESTS & forestry, WATER efficiency, CARBON, BIOTIC communities, OAK, SUGARS, PHLOEM

Abstract

Tree-ring δC is often interpreted in terms of intrinsic water-use efficiency (WUE) using a carbon isotope discrimination model established at the leaf level. We examined whether intra-ring δC could be used to assess variations in intrinsic WUE ( W, the ratio of carbon assimilation and stomatal conductance to water) and variations in ecosystem WUE ( W, the ratio of C assimilation and transpiration) at a seasonal scale. Intra-ring δC was measured in 30- to 60- µm-thick slices in eight oak trees ( Quercus petraea). Canopy W was simulated using a physiologically process-based model. High between-tree variability was observed in the seasonal variations of intra-ring δC. Six trees showed significant positive correlations between W calculated from intra-ring δC and canopy W averaged over several days during latewood formation. These results suggest that latewood is a seasonal recorder of W trends, with a temporal lag corresponding to the mixing time of sugars in the phloem. These six trees also showed significant negative correlations between photosynthetic discrimination Δ calculated from intra-ring δC, and ecosystem W, during latewood formation. Despite the observed between-tree variability, these results indicate that intra-ring δC can be used to access seasonal variations in past W. [ABSTRACT FROM AUTHOR]

Published

2011