forestry

The sponge functions of a landscape refer to its ability to soak up, store and slowly release water.

It is possible to distinguish 3 sponge functions:

1. Intercept rainfall where it falls and stimulate infiltration into the soil;

2. Slow down the runoffthat has formed on the surface, is drained from groundwater, or is accumulated in streams;

3. Temporarily store excess water in the soil, groundwater or surface water bodies.

Sponge functions of a territory play the role of regulator of water. They lye at the heart of a complex system of interconnected physical processes, binding all actors and sectors together (see illustration scheme). The parameters within these sponge loops are numerous. We have become champions at monitoring them separately in every sector, while clearly seeing that they are intrinsically linked. If we organize ourselves to positively activate sponge loops, we unlock a chain reaction of benefits in favour of water availability, quality, safety, food production and biodiversity, all at once. 

Sponge functions are context-specific and must be evaluated for a myriad of different hydrometeorological events, ranging from annual floods and droughts to more extreme events. The greater the sponge functions in the landscape, the more rainwater can be stored and/or used by vegetation, and surface runoff slowed, thus reducing or avoiding flooding downstream. However, it is important to note that sponge functions are not unlimited. Once full, a sponge can no longer store water to reduce the impact of floods, and once empty, it can no longer provide water in the event of a drought,  yet for more frequently occurring events, this approach will contribute to the reduction of impacts both in space and time. 

<p>The biophysical environment is the biotic and abiotic surrounding of an organism or population, and consequently includes the factors that have an influence in their survival, development and evolution. The biophysical environment can vary in scale from microscopic to global in extent. It can also be subdivided according to its attributes. Examples include the marine environment, the atmospheric environment and the terrestrial environment. The number of biophysical environments is countless, given that each living organism has its own environment.</p><p>The symbiosis between the physical environment and the biological life forms within the environment includes all variables that comprise the Earth’s biosphere.</p><p>The&nbsp; biophysical&nbsp; environment&nbsp; can&nbsp; be&nbsp; divided&nbsp; into&nbsp; two&nbsp; categories:&nbsp; the&nbsp; natural&nbsp; environment&nbsp; and&nbsp; the built environment with some overlap between the two. Following the industrial revolution the built environment has become an increasingly significant part of the Earth's environment.</p><p>The scope of the biophysical environment is all that contained in the biosphere, which is that part of the Earth in which all life occurs.</p><p>When narrowed down to the aquatic environment, and particularly in the context of the Water Framework Directive, these are often&nbsp; referred&nbsp; to&nbsp; as&nbsp; water&nbsp; quality,&nbsp; water&nbsp; quantity&nbsp; and&nbsp; hydromorphology.</p>

Urban forest parks or protected areas provide multiple benefits including increased water infiltration, pollutant filtration, reductions in peak flow and maintenance of base flows. Urban forests also have many other aesthetic, biodiversity and quality of life benefits.
- Based on Stella definitions, adapted by NWRM project experts and validated by the European Commission

Areas that are inundated by surface or ground water with frequency sufficient to support a prevalence of vegetative or aquatic life that requires saturated or seasonally saturated soil conditions for growth or reproduction.
Wetlands provide both stormwater attenuation and treatment, comprising shallow ponds and marshy areas covered in aquatic vegetation.ﾠ Wetlands detain flows for an extended period to allow sediments to settle and to remove contaminants.ﾠ They also provide runoff attenuation and can provide significant ecological benefits.

Water retention covers a wide set of mechanisms (see synthesis document n°1) the effect of which are to increase the capture of water by aquifers, soil, and aquatic and water dependent ecosystems.
More precisely it refers to capabilities of catchments (including wetlands, rivers and floodplains but also other land areas) to hold or retain as much water as possible during periods of abundant or even excessive precipitation, so that water is available for use during dry periods and runoff peaks are minimized.

"Water sensitive driving" requires an awareness of the wet areas (mires, peatlands, etc.) in the landscape and an ability to avoid them while conducting forestry operations. Water sensitive driving is focussed primarily on minimizing water quality impacts of forestry including nutrient leakage and an increased potential for methylmercury formation.

Afforestation of reservoir catchments can have multiple benefits. It can reduce sediment inputs from the catchment, lengthening the life of the reservoir, and may also have beneficial effects on water quality in some cases when peatlands are afforested. Afforestation can reduce peak flows and help to maintain base flows. The benefits of afforestation must be balanced against the potential for increased evapotranspiration from a rapidly growing forest.
- Based on Stella definitions, adapted by NWRM project experts and validated by the European Commission

Ditch blocking in managed peatland forests can be used to slow water and trap sediment after forest harvesting. The ditches can be made of wood logs or gabions, for example.
- Elaborated by NWRM project experts and validated by the European Commission

There is some evidence that planting trees on some Mediterranean hillslopes can assist in cloud formation and precipitation. The forests assist in "trapping" rising air and condensing atmospheric water vapour. This work has been pursued by Milan Milan, amongst others.
- Based on Stella definitions, adapted by NWRM project experts and validated by the European Commission