The soil is important since it represents the main land storage of heat and water that is available for subsequent release into the atmosphere. The multi-layer soil model has a fairly realistic representation of the vertical density and temperature profiles of the soil which allows a good representation of its thermal properties.
Structure of the soil
The structure of the soil is not usually uniform throughout the top layers of the earth but for a given location is normally similar within the top ~1.3m of soil. Variations of density of the soil and fluxes of heat and moisture are more related to the texture of the soil and the water or ice content. Vegetation roots also have an impact on the retention of water.
There is an exchange of heat, moisture and momentum between the atmosphere and underlying surface according to the vegetation type.
The IFS multi-layer soil model uses four layers to represent the top ~1.3m of soil and the complex heat fluxes and interactions between them. These are sufficient to represent correctly all timescales from one day to one year. The soil model represents the vertical structure of the soil and the evolution of soil temperature and liquid water content in each layer. The heat and moisture energy flux is represented by the model:
an interception layer collects water from precipitation and dew fall. Infiltration and run-off are represented depending on soil texture and standard deviation of subgrid orography. A fraction of the water flux (rain or snow melt) is considered runoff according to the soil texture, soil water content and the standard deviation of orography (runoff can be up to 30% of rainfall in complex orography or mountainous regions).
The fluxes are illustrated and explained in Fig2.1.4.5-1.
The characteristics of each grid box are updated through the forecast period (e.g. model snowfall might increase the area or depth of snow cover; model rainfall might increase soil moisture rather than be removed by run-off). The areal extent of each land surface tile type (listed above) can vary in a rapid, interactive way during the model run, as rain falls then evaporates or snow accumulates then melts, etc. The slope and aspect of orography within each grid box (e.g. south-facing, steepness) is not taken into account and HTESSEL may consequently under- or over-estimate solar heating and runoff.
The soil type for each land grid box is defined by an offline dataset and this soil type is used for all the layers. Each soil type has its own physical characteristics:
when the water flux at the surface exceeds the maximum infiltration rate the excess water is considered surface runoff.
Fig2.1.4.5-1: Schematic of four-level soil model with land surface tiles. Surface heat and moisture are illustrated in the schematic using the maximum selection of six different surfaces ('tiles'). The four layers of soil have differing moisture contents which vary:
| aS | Albedo of weighted average of tiled surfaces | Ti | Temperature of soil layer i |
| KS | Downward short wave radiation | Fi | Mass of frozen water in soil layer i |
| LS | Downward long wave radiation | Wi | Mass of liquid water in soil layer i |
| HS | Sensible heat flux | Gi | Conductive heat flux between soil layers I and I+1 |
| ES | Latent heat flux | Ri | Liquid water flux between soil layers I and I+1 |
| RS | Net water flux at the surface (precipitation, evaporation, runoff) | RB | Water flux at base of model soil layer (Free draining, Downward only) |
| GB | Conductive heat flux at base of model soil layer = 0 |
Table2.1.4.5-1: List of symbols for parameters shown in Fig2.1.4.5-1.
Soil temperature is a forecast variable in IFS. It needs to be initialised at each analysis cycle but there are relatively few directly measured observations. Soil surface (skin) temperature is derived from the expected air temperature structure in the lowest 2 m together with energy fluxes (from HTESSEL) and an analysis of observed screen level (2 m) temperatures.
Soil moisture is a measure of the water content within the ground. It is commonly expressed as a percentage of the soil water content compared with the water that the ground could hold when fully saturated. The evaluation and prediction of soil moisture is important as this governs the efficiency of evapotranspiration from vegetation. Thus:
For each soil type and location there is a pre-defined value of the ability to hold moisture and this is used to assess the impact of model rainfall. The HTESSEL system includes allowance for water capture by interception of precipitation and dew fall, and at the same time, there are infiltration and run-off schemes that take account of soil texture and the standard deviation of sub-grid scale orography.
Soil moisture is a forecast variable in IFS. It needs to be initialised at each analysis cycle but there are very few directly measured observations. Soil surface (skin) moisture is derived from:
The 2m temperature and humidity are diagnostic parameters of the model, so their analysis only has an indirect effect on atmosphere through the soil and snow variables.
Fig2.1.4.5-2: Measurements from the Soil Moisture and Ocean Salinity satellite mission (SMOS) polar orbiter satellite data. At L-band frequency (1.4 GHz) the surface emission is strongly related to soil moisture over continental surfaces. Surface radiation at this frequency is influenced by the vegetation layer (and hence soil moisture if the vegetation type is known), but proximity of lakes etc cause difficulties with interpretation.
Fig2.1.4.5-3: Examples of Soil Moisture at T+00 and T+192 DT 00UTC 06 March 2023.
Example soil moisture chart VT 00UTC 06 March 2023 showing moisture in soil level 1, the surface layer. The legend shows:
Note the change in soil moisture over France from ~60% of field capacity (greens) to above 60% of saturation (blues). This is largely due to rain exceeding evaporation in these areas during the forecast period. Conversely, parts of northern Morocco, northern Algeria and northern Tunisia have become a little drier.
See the current soil moisture chart. Select "Layer 1 2 3" from the drop down menu for the average moisture in the top metre of the earth.
Rarely in moist areas there are some soil moisture plots (except over Europe) indicating the soil is exceptionally dry.
Grid point data is plotted for Europe. Elsewhere, for (most) other parts of the world, soil moisture is interpolated from surrounding grids points. Field capacity, saturation, wilting point etc. depend on the soil type so can consequently be affected. Users should check nearby soil moisture before accepting misleading soil moisture actual and forecast data.
Recent periods of persistent rain over Britain over the winter of 2023/24 increased the soil moisture content in the river valleys and countryside around Reading. Soil water storage in all model soil layers had been consistently between 120% and 150% of field capacity but generally below saturation. Nevertheless there were areas of standing water in low-lying areas.
Fig2.1.4.5-5: Example of surface and soil water budget. DT12UTC 12 Feb 2024, VT12-14 Feb 20-24. Temperate mid-latitudes.
A tropical system moved over the Northern Territories, Australia depositing a period of significant rainfall.
The coarse soil type allows the water to penetrate instead of creating runoff even after the heavy rain.
Recycling of moisture by evaporation often has an impact on maintaining cyclones over the dessert.
Fig2.1.4.5-4: Example of surface and soil water budget. DT00UTC 21 Jan 2024, VT21-23 Jan 20-24. Desert areas.
The model soil moisture charts sometimes show moisture layers below the surface in dry desert areas. There is very little ground truth so there must be some uncertainty.
Soil moisture charts consistently give an indication of water below the surface in mid-Sahara (near 23N 7E). This should not be relied on. However, it may well be correct as the area is around the oasis town of Tamanrasset in Algeria. There is indication of water in layers 2 and 3 in Arabia, locally as high as 60%, but there is little data to confirm this.
Fig2.1.4.5-6: Example of soil moisture in desert areas. DT and VT 12UTC 07 Sep 2023. In the area around Tamanrasset (Algeria) and much of Saudi Arabia, soil moisture charts show dry surface layers (level 1, orange) and about 20% moisture in lower layers (levels 2 and 3, green) and locally as high as 60% in Saudi Arabia.
Fig2.1.4.5-7: Afilal Oasis lies within the area where the model indicates soil with moderate moisture content in level 2 (~25% of Field Capacity) and level 3 (~40% of Field Capacity). Level 1 has water content below the wilting point) and remains so as there is no vegetation and roots to bring water upwards from lower layers. Nevertheless, subterranean water is locally sufficient to reach the surface at Afilal Oasis as springs. Soil moisture is a mean over a grid square. Local details and individual oases are unlikely to be captured. Soil moisture and soil type is not necessarily representative of an individual location.
(Note: In older material there may be references to issues that have subsequently been addressed)
(FUG Associated with Cy49r1)