Concerns have been raised on the deterioration of heather moorland due to management
in the UK. A study was therefore conducted on the impacts of moorland management on
the soils and hydrology of a catchment on Dartmoor. Soil moisture was measured gridwise
using TDR on 19 occasions. At 23 sites within this grid, physical properties of the
topsoil were obtained. At three locations, tensiometer nests were installed, recording soil
suction at 10 cm depth intervals. At the catchment scale, stream discharge and rainfall
were recorded. Grazing densities within the watershed were estimated and the observed
patterns were related to vegetation types.
Results from the TDR grid showed that in dry conditions, soil moisture patterns are
heterogeneous in contrast to a more uniform pattern in wet periods. A threshold soil
moisture content of about 0.60 cm3 cm-3 divides the two conditions. The exponential
relationship between average hillslope soil moisture content and stream discharge also
revealed the division between wet and dry states. A regression analysis showed that
during dry conditions, the vegetation plays a significant role in determining the soil water
status. During wet conditions, topography becomes more important. In these conditions,
the soil water movement is mainly lateral, whereas in the dry state, this is vertical in the
soil profile. Tensiometer data showed that most soil water movement is in the topsoil.
Analyses suggested that soil moisture under vegetation classes associated with higher
grazing pressures is higher in similar topographic conditions. Soil bulk density is higher
and the total porosity is lower near the soil surface. This suggests that less rainfall is
required to reach the soil moisture threshold and water will be transported laterally down
the slope.
A heather burning experiment revealed that the direct effect of temperature is shallow.
Soil moisture levels do not change over the course of the burn. However, in dry situations
during summer, soil moisture contents under burned plots are higher than under unburned
vegetation probably due to reduced transpiration. If this effect is similar at the hillslope
scale, when the soil is wetting up, the soil moisture threshold value could be reached at an
earlier stage and accelerated lateral water movement could be the result.
It can be concluded therefore, that moorland management could accelerate water
movement on the hillslopes causing higher discharge peaks in wet periods and
consequently low flows in summer. However, the effects are subtle and encouraging
vegetation heterogeneity could play a role in buffering water to prevent loss to the stream.
Date of Award | 2002 |
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Original language | English |
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Awarding Institution | |
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- Ecology
- Soil science
- Hydrology
- Heather moorland
Hillslope and watershed scale hydrological processes and grazing management in a Dartmoor catchment, Southwest England
Meyles, E. W. (Author). 2002
Student thesis: PhD