The Rowden Moor experimental site (A.F.R.C. I.G.E.R., North Wyke) provided an opportunity to
characterise discharge regimes, elucidate runoff generation mechanisms and to consider
implications for solute movement under natural and drained conditions. Research was conducted
on a heavy clay grassland soil in an area of high rainfall (1053 mm a ˉ¹) in South West England. A
combined hydrometric and tensiometric study was undertaken within a nested experimental
design (1 m² to 1 ha) on one undrained and one drained site throughout a drainage season
(October to March).
Results at the hectare scale demonstrated that drainage did not substantially alter the volume of
field runoff ( ~ 400 mm) but did change the dominant flowpaths. Drainage diverted water from
surface/near surface routes to depth so that drain storm runoff was lagged by some 30 minutes
over undrained site discharge. The drained site also exhibited a more peaky regime, with a
maximum daily discharge of 45 mm being almost twice that for the undrained field.
At the field and plot scale, the significance of macropore flow was noted. To investigate this in
more detail, a tracer experiment was performed on an isolated soil block which had been mole
drained and so had enhanced macroporosity. Macropore flow was generated under unsaturated
conditions (little matric potential response and no water table was identified). Stable oxygen
concentrations were δ18O +3.5 and -5.8 in tracer and background water respectively. Drainflow
indicated that there was rapid interaction between applied tracer and soil water (peak flow δ18O
-1.1). Thus, the matrix-macropore interface was not a boundary between two separate domains of
old and new water, high and low conductivity but a site of rapid interchange and mixing.
Temporal variability of soil status and malric water composition, also indicated that limited areas
of the matrix were capable of transmitting rapid flow. It became clear that even in a heavy clay
soil such as that found at Rowden, where macropore flow was promoted by drainage operations,
the matrix still had an important role to play. On the basis of potential, soil moisture and
observation of tracers, it is proposed that discrete (finger-like) volumes of the matrix are capable
of rapid water transmission. Although it was frequently impossible to relate moisture content and
soil water potential because instrumentation monitored different volumes of soil, hysteretic soil
moisture behaviour over the drainage season was evident in both data sets.
This study confirmed the importance of rapid subsurface runoff generation mechanisms on
drained soils, but noted that discontinuous translatory flow in the matrix and macropore flow
occurred and that the two ‘domains’ were inextricably linked. Further work should be undertaken
at the detailed scale to elucidate the soil characteristics which promote rapid runoff mechanisms
and the consequences for water quality, especially where the soil subsurface represents a major
reservoir (e.g. nitrates).
Date of Award | 1995 |
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Original language | English |
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Awarding Institution | |
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AN INVESTIGATION OF SOIL WATER MOVEMENT ON DRAINED AND UNDRAINED CLAY GRASSLAND IN SOUTH WEST ENGLAND
ADDISON, P. J. (Author). 1995
Student thesis: PhD