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Indicator Assessment
Past trends
As a spatially and temporally comprehensive set of harmonised soil moisture data over a sufficient soil depth is not available, assessments of past trends in soil moisture rely on hydrological models driven by data on climate, soil characteristics, land cover and phenological phases. These simulations take account of changes in available energy, humidity and wind speed, but disregard artificial drainage and irrigation practices. Modelling of soil moisture content over the past 60 years suggests that there has been little change at the global and pan-European levels [i]. At the sub-continental scale, however, significant trends in summer soil moisture content can be observed (Figure 1). Soil moisture content has increased in parts of northern Europe, probably because of increases in precipitation amounts. In contrast, soil moisture has decreased in most of the Mediterranean region, particularly in south-eastern Europe, south-western Europe and southern France. The substantial increases in soil moisture content modelled over western Turkey should be considered with caution because of the limited availability of climate and soil data in the region, which affects the accuracy of the modelled trends [ii].
Projections
Based on the results of 12 RCMs, the projected changes in soil moisture anomaly (Palmer Drought Severity Index) show a strong latitudinal gradient, from pronounced drier conditions in southern Europe to wetter conditions in northern European regions in all seasons (Figure 2). The largest changes in the soil moisture index between 2021–2050 and the baseline period (1961–1990) are projected for the summer period in the Mediterranean, especially in north-eastern Spain and south-eastern Europe [iii].
Projections for the end of the 21st century show significant decreases in summer soil moisture content in the Mediterranean region and central Europe, and increases in the north-eastern part of Europe [iv].
[i] Justin Sheffield, Eric F. Wood, and Michael L. Roderick, ‘Little Change in Global Drought over the Past 60 Years’,Nature 491, no. 7424 (15 November 2012): 435–38, doi:10.1038/nature11575; Blaž Kurnik, Lučka Kajfež-Bogataj, and Stephanie Horion, ‘An Assessment of Actual Evapotranspiration and Soil Water Deficit in Agricultural Regions in Europe’,International Journal of Climatology 35, no. 9 (2015): 2451–71, doi:10.1002/joc.4154.
[ii] see Kurnik, Kajfež-Bogataj, and Horion, ‘An Assessment of Actual Evapotranspiration and Soil Water Deficit in Agricultural Regions in Europe’, for details.
[iii] Georg Heinrich and Andreas Gobiet, ‘The Future of Dry and Wet Spells in Europe: A Comprehensive Study Based on the ENSEMBLES Regional Climate Models’,International Journal of Climatology 32, no. 13 (15 November 2012): 1951–70, doi:10.1002/joc.2421.
[iv] P. Calanca et al., ‘Global Warming and the Summertime Evapotranspiration Regime of the Alpine Region’,Climatic Change 79 (2006): 65–78, doi:10.1007/s10584-006-9103-9; J.I. López-Moreno, S. Goyette, and M. Beniston, ‘Impact of Climate Change on Snowpack in the Pyrenees: Horizontal Spatial Variability and Vertical Gradients’,Journal of Hydrology 374, no. 3–4 (2009): 384–96, doi:10.1016/j.jhydrol.2009.06.049; B. Orlowsky and S. I. Seneviratne, ‘Elusive Drought: Uncertainty in Observed Trends and Short- and Long-Term CMIP5 Projections’,Hydrology and Earth System Sciences 17, no. 5 (7 May 2013): 1765–81, doi:10.5194/hess-17-1765-2013.
In April 2013, the European Commission (EC) presented the EU Adaptation Strategy Package. This package consists of the EU Strategy on adaptation to climate change (COM/2013/216 final) and a number of supporting documents. The overall aim of the EU Adaptation Strategy is to contribute to a more climate-resilient Europe.
One of the objectives of the EU Adaptation Strategy is Better informed decision-making, which will be achieved by bridging the knowledge gap and further developing the European climate adaptation platform (Climate-ADAPT) as the ‘one-stop shop’ for adaptation information in Europe. Climate-ADAPT has been developed jointly by the EC and the EEA to share knowledge on (1) observed and projected climate change and its impacts on environmental and social systems and on human health, (2) relevant research, (3) EU, transnational, national and subnational adaptation strategies and plans, and (4) adaptation case studies.
Further objectives include Promoting adaptation in key vulnerablesectors through climate-proofing EU sector policies and Promoting action by Member States. Most EU Member States have already adopted national adaptation strategies and many have also prepared action plans on climate change adaptation. The EC also supports adaptation in cities through the Covenant of Mayors for Climate and Energy initiative.
In September 2016, the EC presented an indicative roadmap for the evaluation of the EU Adaptation Strategy by 2018.
In November 2013, the European Parliament and the European Council adopted the 7th EU Environment Action Programme (7th EAP) to 2020, ‘Living well, within the limits of our planet’. The 7th EAP is intended to help guide EU action on environment and climate change up to and beyond 2020. It highlights that ‘Action to mitigate and adapt to climate change will increase the resilience of the Union’s economy and society, while stimulating innovation and protecting the Union’s natural resources.’ Consequently, several priority objectives of the 7th EAP refer to climate change adaptation.
No targets have been specified.
Past trends
Soil moisture was estimated using an algorithm for calculating the water balance at the surface and in the sub-surface horizons (up to 1m depth). The model uses the recommendations of the Food and Agriculture Organisation of the United Nations (FAO) for estimating the available water content in soils. It calculates soil moisture by adding and subtracting the losses and gains in the various parameters of the soil water budget, expressed in terms of the water column (in millimetres).
Written in volumetric units, the soil water balance (SWB) can be represented by Equation 1:
D * Capital delta_SWB / Capital delta_t = RR(t) – ETA(t) – SRO(t) – DP(t) (1)
where D (in millimetres) is the depth of the modelled soil profile (root zone), and Capital delta_SWB (in cubic metres per cubic metre) is the change of the water volume over an area with depth D between two consecutive steps (Capital delta_t). RR (in millimetres per day) is the amount of precipitation at the surface, ETA (in millimetres per day) is the actual evapotranspiration, SRO (in millimetres per day) is the surface runoff and DP (in millimetres per day) is the deep percolation.
Thus, as precipitation increases, actual evapotranspiration (ETA), total runoff (SRO) and deep percolation (DP) decrease the soil moisture content in the root zone. Pedotransfer functions were used to calculate the field capacity, wilting point and soil saturation point characteristics required to calculate the SWB.
In addition to climate data, the equation takes account of other parameters such as, land cover, phenological phases, and hydrological soil properties.
Input data: The model uses a range of inputs. Daily meteorological station data were obtained from the European Climate Assessment and Data set (ECA&D), compiled by the Royal Netherlands Meteorological Institute (KNMI). Land cover information from the Corine Land Cover 2006 project (CLC2006) was used to identify the type of land cover and to calculate the crop coefficient for three phenological stages (start, middle and end of season). Intra-annual variation of the crop coefficient kc was calculated from the Normalised Difference Vegetation Index (NDVI), applying the same linear relationship between kc and NDVI for all stations and over the whole validation period. Hydrological soil properties (namely soil saturation point, field capacity and wilting point) were calculated using soil characteristics (soil texture and soil organic matter) from the European Soil map (ESDB version 2.0).
Projections
Calculation of the Palmer Drought Severity Index (PDSI) opposes atmospheric water supply to soil water demand using a rather simple soil-water balance model.
The PDSI measures the deviation from climatically normal soil moisture conditions for the current month without regarding conditions of preceding months, accounting for local climate features.
Not applicable
No methodology references available.
Soil moisture can be measured or estimated by various methods, based either on in-situ measurements, spatially continuous information derived from satellite imagery, or hydrological and land surface models.
Soil moisture measurements are expensive and do not provide a good spatial representation of the soil wetness conditions due to the high variability of soil moisture on a local scale. In most of the studies, soil moisture is simulated by land surface, hydrological and soil water balance models. Modellers can choose the spatial and temporal resolutions of the end product, depending on the resolution of the input data and the computation capacities. The vertical distribution of the soil moisture can be represented with different compartments within the model.
Specifically for the projections (Palmer Drought Severity Index), regional climate model (RCM) simulations provided by the ENSEMBLES project are used to analyse changes in dry and wet conditions in Europe by the mid of the 21st century under the A1B emission scenario. Eight RCMs are selected to capture the uncertainties of the projected changes.
Quantitative information, from both observations and modelling, on the past trends and impacts of climate change on soil and the various related feedbacks is very limited. For example, data have been collected in forest soil surveys, but issues with survey quality — at least in the first European forest soil survey — makes comparison between countries (and between surveys) difficult. To date, assessments have relied mainly on local case studies that have analysed how soil reacts under changing climate in combination with evolving agricultural and forest practices. Thus, Europe-wide soil information to help policymakers identify appropriate adaptation measures is absent. There is an urgent need to establish harmonised monitoring networks to provide a better and more quantitative understanding of this system. Currently, EU-wide soil indicators are (partly) based on estimates and modelling studies, most of which have not yet been validated. It is still common to use precipitation (sometimes combined with evaporation-based indicators, such as the SPI or the Palmer Drought Severity Index) to describe changes in soil moisture, despite the high sensitivity of the assessment to the specific method used.
When documenting and modelling changes in soil, biodiversity and forest indicators, it is not always feasible to track long-term changes (signal) given the significant short-term variations (noise) that may occur (e.g. seasonal variations of soil organic carbon as a result of land management). Therefore, detected changes cannot always be causally attributed to climate change. Human activity, such as land use and management, can be more important for terrestrial ecosystem components than climate change, both for explaining past trends and for future projections.
No uncertainty has been specified
For references, please go to https://eea.europa.eu./data-and-maps/indicators/water-retention-4/assessment or scan the QR code.
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