Biomass production at 2085 horizon for the Maurienne valley (French Alps) estimated using a Bayesian Belief Network
Data files
Mar 27, 2024 version files 31.17 MB
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GrasslandEcologicalTypes.tiff
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RasterProd_S1_2020_Control.tiff
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RasterProd_S1_RCP4.5_2050_Control_GrasslandAndShrub.tiff
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RasterProd_S1_RCP4.5_2050_Control_OnlyGrassland.tiff
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RasterProd_S1_RCP4.5_2050_Lowland_GrasslandAndShrub.tiff
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RasterProd_S1_RCP4.5_2050_Lowland_OnlyGrassland.tiff
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RasterProd_S1_RCP4.5_2050_Wide_GrasslandAndShrub.tiff
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RasterProd_S1_RCP4.5_2050_Wide_OnlyGrassland.tiff
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RasterProd_S1_RCP4.5_2085_Control_GrasslandAndShrub.tiff
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RasterProd_S1_RCP4.5_2085_Control_OnlyGrassland.tiff
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RasterProd_S1_RCP4.5_2085_Lowland_GrasslandAndShrub.tiff
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RasterProd_S1_RCP4.5_2085_Lowland_OnlyGrassland.tiff
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RasterProd_S1_RCP4.5_2085_Wide_GrasslandAndShrub.tiff
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RasterProd_S1_RCP4.5_2085_Wide_OnlyGrassland.tiff
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RasterProd_S1_RCP8.5_2050_Control_GrasslandAndShrub.tiff
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RasterProd_S1_RCP8.5_2050_Control_OnlyGrassland.tiff
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RasterProd_S1_RCP8.5_2050_Lowland_GrasslandAndShrub.tiff
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RasterProd_S1_RCP8.5_2050_Lowland_OnlyGrassland.tiff
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RasterProd_S1_RCP8.5_2050_Wide_GrasslandAndShrub.tiff
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RasterProd_S1_RCP8.5_2050_Wide_OnlyGrassland.tiff
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RasterProd_S1_RCP8.5_2085_Control_GrasslandAndShrub.tiff
446.13 KB
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RasterProd_S1_RCP8.5_2085_Control_OnlyGrassland.tiff
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RasterProd_S1_RCP8.5_2085_Lowland_GrasslandAndShrub.tiff
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RasterProd_S1_RCP8.5_2085_Lowland_OnlyGrassland.tiff
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RasterProd_S1_RCP8.5_2085_Wide_GrasslandAndShrub.tiff
455.86 KB
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RasterProd_S1_RCP8.5_2085_Wide_OnlyGrassland.tiff
455.71 KB
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RasterProd_S2_RCP4.5_2050_Control_GrasslandAndShrub.tiff
399.05 KB
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RasterProd_S2_RCP4.5_2050_Control_OnlyGrassland.tiff
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RasterProd_S2_RCP4.5_2050_Lowland_GrasslandAndShrub.tiff
400.70 KB
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RasterProd_S2_RCP4.5_2050_Lowland_OnlyGrassland.tiff
380.18 KB
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RasterProd_S2_RCP4.5_2050_Wide_GrasslandAndShrub.tiff
404.49 KB
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RasterProd_S2_RCP4.5_2050_Wide_OnlyGrassland.tiff
384 KB
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RasterProd_S2_RCP4.5_2085_Control_GrasslandAndShrub.tiff
374.12 KB
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RasterProd_S2_RCP4.5_2085_Control_OnlyGrassland.tiff
370.76 KB
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RasterProd_S2_RCP4.5_2085_Lowland_GrasslandAndShrub.tiff
375.74 KB
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RasterProd_S2_RCP4.5_2085_Lowland_OnlyGrassland.tiff
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RasterProd_S2_RCP4.5_2085_Wide_GrasslandAndShrub.tiff
379.09 KB
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RasterProd_S2_RCP4.5_2085_Wide_OnlyGrassland.tiff
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RasterProd_S2_RCP8.5_2050_Control_GrasslandAndShrub.tiff
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RasterProd_S2_RCP8.5_2050_Control_OnlyGrassland.tiff
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RasterProd_S2_RCP8.5_2050_Lowland_GrasslandAndShrub.tiff
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RasterProd_S2_RCP8.5_2050_Lowland_OnlyGrassland.tiff
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RasterProd_S2_RCP8.5_2050_Wide_GrasslandAndShrub.tiff
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RasterProd_S2_RCP8.5_2050_Wide_OnlyGrassland.tiff
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RasterProd_S2_RCP8.5_2085_Control_GrasslandAndShrub.tiff
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RasterProd_S2_RCP8.5_2085_Control_OnlyGrassland.tiff
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RasterProd_S2_RCP8.5_2085_Lowland_GrasslandAndShrub.tiff
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RasterProd_S2_RCP8.5_2085_Lowland_OnlyGrassland.tiff
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RasterProd_S2_RCP8.5_2085_Wide_GrasslandAndShrub.tiff
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RasterProd_S2_RCP8.5_2085_Wide_OnlyGrassland.tiff
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RasterProd_S3_RCP4.5_2050_Control_GrasslandAndShrub.tiff
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RasterProd_S3_RCP4.5_2050_Control_OnlyGrassland.tiff
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RasterProd_S3_RCP4.5_2050_Lowland_GrasslandAndShrub.tiff
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RasterProd_S3_RCP4.5_2050_Lowland_OnlyGrassland.tiff
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RasterProd_S3_RCP4.5_2050_Wide_GrasslandAndShrub.tiff
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RasterProd_S3_RCP4.5_2050_Wide_OnlyGrassland.tiff
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RasterProd_S3_RCP4.5_2085_Control_GrasslandAndShrub.tiff
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RasterProd_S3_RCP4.5_2085_Control_OnlyGrassland.tiff
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RasterProd_S3_RCP4.5_2085_Lowland_GrasslandAndShrub.tiff
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RasterProd_S3_RCP4.5_2085_Lowland_OnlyGrassland.tiff
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RasterProd_S3_RCP4.5_2085_Wide_GrasslandAndShrub.tiff
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RasterProd_S3_RCP4.5_2085_Wide_OnlyGrassland.tiff
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RasterProd_S3_RCP8.5_2050_Control_GrasslandAndShrub.tiff
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RasterProd_S3_RCP8.5_2050_Control_OnlyGrassland.tiff
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RasterProd_S3_RCP8.5_2050_Lowland_GrasslandAndShrub.tiff
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RasterProd_S3_RCP8.5_2050_Lowland_OnlyGrassland.tiff
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RasterProd_S3_RCP8.5_2050_Wide_GrasslandAndShrub.tiff
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RasterProd_S3_RCP8.5_2050_Wide_OnlyGrassland.tiff
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RasterProd_S3_RCP8.5_2085_Control_GrasslandAndShrub.tiff
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RasterProd_S3_RCP8.5_2085_Control_OnlyGrassland.tiff
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RasterProd_S3_RCP8.5_2085_Lowland_GrasslandAndShrub.tiff
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RasterProd_S3_RCP8.5_2085_Lowland_OnlyGrassland.tiff
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RasterProd_S3_RCP8.5_2085_Wide_GrasslandAndShrub.tiff
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RasterProd_S3_RCP8.5_2085_Wide_OnlyGrassland.tiff
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README.md
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Abstract
In mountains, grasslands managed for livestock production sustain local economies, culture and identity. However, their future fodder production is highly uncertain under climate change: while an extended growing season may be beneficial, more frequent and intense summer droughts could also reduce fodder quantity and quality. Land use and land cover (LULC) changes are another major driver of regional grassland biomass production, but combined effects of future land use transitions and climate change are rarely quantified.
We modelled combined climate and LULC scenarios for grassland production of the Maurienne Valley (French Alps) by 2100. We built a Bayesian Belief Network (BBN) from long-term grassland production monitoring data complemented with expert knowledge. We assessed the potential of two candidate adaptations, intensification as an incremental solution, and silvopastoralism as a transformative solution to compensate combined impacts of two climate scenarios and three land use change scenarios.
Total biomass production was far more sensitive to LULC than to climate scenarios. Production losses were largest under the Conservation LULC scenario (-28% on average between 2020 and 2085), followed by the Tourism development scenario (-7%) and the Business-as-Usual scenario (+3%). Climate change under RCP 8.5 altered the seasonality of production by increasing potential production from May to July while decreasing summer regrowth. Intensification somewhat compensated effects of climate and LULC changes on biomass production, whereas silvopastoralism offered only marginal gains. The Bayesian network model explicitly captured a future increase in interannual variability in biomass production.
Synthesis and application: Changes in LULC are more decisive for global biomass production than climate change. However, under the most extreme climate change scenario (RCP8.5), the seasonal shift in production and increased interannnual variability threaten the current grass-based Protected Designation of Origin production system. Only the intensification adaptation solution showed significant gains in total biomass production. Still, the silvopastoralism would require less investment compared to the intensification and have a similar efficiency when assessing the gains of biomass by the surface concerned with adaptation solutions.
README: Biomass production at 2085 horizon for the Maurienne valley (French Alps) estimated using a Bayesian Belief Network
https://doi.org/10.5061/dryad.pg4f4qrxd
This datasets comprise raster of biomass production for the Maurienne valley (French Alps). Values are expressed in 10^3 kg.km^-2.year^-1 of dry biomass matter. Rasters are in EPSG: 4326. Those results are the product of a Bayesian Belief Network, a full description of the model is available in the main publication linked to this deposit.
Description of the data and file structure
We provide several rasters of biomass production for time periods: 2020, 2050, 2085; across three future scenarios of land use and land cover change (see 10.5061/dryad.83bk3jb0h); across two future scenarios of climate change (RCP 4.5 and RCP 8.5) and across three modalities of adaptation solution implementation (Control, Silvopastoralism, Irrigation and fertilization).
Scenarios of future Land Use and Land Cover change (LULC) : Three scenarios of future change are provided (Buisiness as Usual - S1, Conservation - S2, Tourism - S3). For each of those scenarios two dates are provided : 2050 and 2085. In 2020 only one map is available (for S1) as it is the current state of LULC. For a full description of those LULC scenarios, see the main article. All scenarios are also accessible on : https://doi.org/10.5061/dryad.83bk3jb0h
Control : No adaptation Solution
Silvopastoralism: two modalities: Only Grassland (no silvopastoralim), Grassland and Shrub (the silvopastoralism is implemented and recently encroached surfaces are producing biomass)
Irrigation and Fertilization: Control no implementation; Lowland, implemented only in low altitudes; Wide, implemented on low and medium altitudes.
We also provide an intermediary product of the model as raster: the precited grassland ecological type. Before estimating the biomass production, our model predict the likelyhood of each pixel to belong to a specific grassland type that controls its biomass production range. The model assigns at each pixel a probability to belong to each of those ecological type and we provide here the raster of the most probable state over our study site.
| Code | Grassland type |
|---|---|
| 1 | Thermophilous |
| 2 | Snowbed |
| 3 | Intermediate |
| 4 | Productive |
| 5 | Lowland |
Methods
This dataset was produced using a Bayesian Belief Network that estimate the biomass production across time and scenarios of future land use and land cover change.
For a full description of the methodology see: A Bayesian analysis of adaptation of mountain grassland production to global change published in JOAE in 2024.