HETEROFOR 1.0: a spatially explicit model for exploring the response of structurally complex forests to uncertain future conditions – Part 2: Phenology and water cycle

Wergifosse, Louis de; André, Frédéric; Beudez, Nicolas; Coligny, François de; Goosse, Hugues; Jonard, François; Ponette, Quentin; Titeux, Hugues; Vincke, Caroline; Jonard, Mathieu

doi:10.5194/gmd-13-1459-2020

Cited by 8 publications

(6 citation statements)

References 173 publications

(181 reference statements)

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“…However, SWHC values similar to, or even higher than our estimate of 390 mm have been published for temperate forests (e.g. 338 mm for the Hesse Beech forest in North-Eastern France, De La Motte et al, 2020, or 450 mm for a mixed Beech-Oak forest near Louvain-la-Neuve in Belgium, De Wergifosse et al, 2020). The value of 390 mm for SWHC was 1.9 times higher than the database estimate of 207 mm for the FR-Fon grid point (Badeau et al, 2010).…”

Section: Discussionsupporting

confidence: 74%

Contribution of deep soil layers to the transpiration of a temperate deciduous forest: quantification and implications for the modelling of productivity

Maysonnave

Delpierre

François

et al. 2022

Preprint

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Climate change is imposing drier atmospheric and edaphic conditions on temperate forests. Here, we investigated how subsoil (down to 300 cm) water extraction contributed to the provision of water in the Fontainebleau-Barbeau temperate oak forest over two years, including the 2018 record drought. Deep water provision was key to sustain canopy transpiration during drought, with layers below 150 cm contributing up to 60% of the transpired water in August 2018, despite their very low density of fine roots. We further showed that soil databases used to parameterize ecosystem models clearly underestimated the amount of water extractable from the soil by trees. The consensus database established for France gave an estimate of 207 mm for the soil water holding capacity (SWHC) at our study site, when our estimate based on the analysis of soil water content measurements was 1.9 times higher, reaching 390+/-17 mm. Running the CASTANEA forest model with the database-derived SWHC yielded a 350 gC m-2 y-1 average underestimation of annual gross primary productivity under Global Change Biology For Review Only current climate, reaching up to 700 gC m-2 y-1 under climate change scenario RCP8.5. Correctly estimating SWHC is a challenge for accurate simulations of the carbon cycle in a changing climate and we showed that subsoil SWC measurements are needed for this.

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Section: Discussionsupporting

confidence: 74%

Contribution of deep soil layers to the transpiration of a temperate deciduous forest: quantification and implications for the modelling of productivity

Maysonnave

Delpierre

François

et al. 2022

Preprint

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“…With our simulations, we were unable to distinguish between the transpiration deficit under constant and timedependent atmospheric CO 2 concentration since the water balance is calculated before photosynthesis in HETEROFOR and the stomatal conductance for water does not depend on atmospheric CO 2 concentration contrary to that for CO 2 (Dufrêne et al, 2005;Jonard et al 2020;de Wergifosse et al 2020a). Therefore, our transpiration simulations are more reliable for the constant atmospheric CO 2 modality.…”

Section: Discussionmentioning

confidence: 83%

“…In the same study, the simulated GPP was related to the NPP reconstructed from tree growth measurement and this relationship displayed high Pearson's correlation coefficients (0.89 and 0.91 for sessile oak and European beech, respectively). Regarding water balance evaluated in de Wergifosse et al (2020a), the model satisfactorily simulated the soil water content temporal dynamics (correlation coefficients between simulations and observations ranging from 0.83 to 0.95 according to the site) and the individual transpiration (0.85 and 0.89 for oak and beech, respectively). Finally, the budburst model previously described, a one-phase model based on the Uniforc model (Chuine 2000), which simulates the forcing period, has been chosen among two other budburst models (two-phase models accounting for the forcing and chilling periods) implemented in HETEROFOR as it reproduced best the interannual variability.…”

Section: Model Description and Performancesmentioning

confidence: 82%

“…Hereafter, we present a brief overview of the model functioning limited to the description of the options retained for the simulation experiments carried out in this study. For a more in-depth description, we refer the reader to Jonard et al (2020) andde Wergifosse et al (2020a).…”

Section: Model Description and Performancesmentioning

confidence: 99%

“…In this study, we will address the question of how and to what extent changing climate and CO 2 conditions will impact forest productivity in six contrasting and structurally complex stands in Wallonia and assess how the site components and thinning operations modulate the response. To do so, we will use HETEROFOR (Jonard et al 2020;de Wergifosse et al 2020a), a process-based tree growth model running at the individual level with different climate projections based on three GHG emission scenarios.…”

Section: Introductionmentioning

confidence: 99%

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CO2 fertilization, transpiration deficit and vegetation period drive the response of mixed broadleaved forests to a changing climate in Wallonia

Wergifosse

André

Goosse

et al. 2020

Annals of Forest Science

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& Key message The change in forest productivity was simulated in six stands in Wallonia (Belgium) following different climate scenarios using a process-based and spatially explicit tree growth model. Simulations revealed a strong and positive impact of the CO 2 fertilization while the negative effect of the transpiration deficit was compensated by longer vegetation periods. The site modulated significantly the forest productivity, mainly through the stand and soil characteristics. & Context Forest net primary production (NPP) reflects forest vitality and is likely to be affected by climate change. & Aims Simulating the impact of changing environmental conditions on NPP and two of its main drivers (transpiration deficit and vegetation period) in six Belgian stands and decomposing the site effect. & Methods Based on the tree growth model HETEROFOR, simulations were performed for each stand between 2011 and 2100 using three climate scenarios and two CO 2 modalities (constant vs time dependent). Then, the climate conditions, soils and stands were interchanged to decompose the site effect in these three components.

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Developing landscape-scale forest restoration targets that embrace spatial pattern

Rudge

Levick

Bartolo³

et al. 2022

Landsc Ecol

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Context Forest restoration plays an important role in global efforts to slow biodiversity loss and mitigate climate change. Vegetation in remnant forests can form striking patterns that relate to ecological processes, but restoration targets tend to overlook spatial pattern. While observations of intact reference ecosystems can help to inform restoration targets, field surveys are ill-equipped to map and quantify spatial pattern at a range of scales, and new approaches are needed. Objective This review sought to explore practical options for creating landscape-scale forest restoration targets that embrace spatial pattern. Methods We assessed how hierarchy theory, satellite remote sensing, landscape pattern analysis, drone-based remote sensing and spatial point pattern analysis could be applied to assess the spatial pattern of reference landscapes and inform forest restoration targets. Results Hierarchy theory provides an intuitive framework for stratifying landscapes as nested hierarchies of sub-catchments, forest patches and stands of trees. Several publicly available tools can map patches within landscapes, and landscape pattern analysis can be applied to quantify the spatial pattern of these patches. Drones can collect point clouds and orthomosaics at the stand scale, a plethora of software can create maps of individual trees, and spatial point pattern analysis can be applied to quantify the spatial pattern of mapped trees. Conclusions This review explored several practical options for producing landscape scale forest restoration targets that embrace spatial pattern. With the decade on ecosystem restoration underway, there is a pressing need to refine and operationalise these ideas.

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HETEROFOR 1.0: a spatially explicit model for exploring the response of structurally complex forests to uncertain future conditions – Part 2: Phenology and water cycle

Cited by 8 publications

References 173 publications

Contribution of deep soil layers to the transpiration of a temperate deciduous forest: quantification and implications for the modelling of productivity

Contribution of deep soil layers to the transpiration of a temperate deciduous forest: quantification and implications for the modelling of productivity

CO2 fertilization, transpiration deficit and vegetation period drive the response of mixed broadleaved forests to a changing climate in Wallonia

Developing landscape-scale forest restoration targets that embrace spatial pattern

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