Wetland hydrology controls the function of the wetland ecosystem and hence it is the
principal parameter for delineation and management of wetlands. It is defined as the water
table depth, duration, and frequency required for an area to develop anaerobic conditions in
the upper part of the soil profile leading to the formation of iron and manganese based soil
features called redoximorphic features. The redoximorphic features must occur at specific
depths in the soil profile with specific thickness and abundance to qualify for a hydric soil
indicators. Therefore, hydric soil indicators are used to evaluate the wetland hydrology if
such a relationship has been verified. The aims of the study were i) to determine soil
variation and hydric soils indicators along a toposequence, ii) to determine the relationships
between soil water saturation, redox potential and hydric soil morphological properties and
iii) to determine the distribution of soil properties and accumulation of soil organic carbon in
hydric and non-hydric soils.
The study was conducted at the upper head-water catchment of the Bokong wetlands in the
Maloti/Drakensberg Mountains, Lesotho. The soil temperature ranged between -10 and
23°C. The soils had a melanic A overlying an unspecified material with or without signs of
wetness, or a G horizon. The organic O occurred in small area. Soil profiles were dug along
a toposequence and described to the depth of 1000 mm or shallower if bedrock was
encountered. Redoximorphic features were described using standard soil survey
abundance categories. Soil samples were collected from each horizon and analysed for
selected physical and chemical soil properties.
The soils had low bulk density ranging from 0.26 in the topsoil to 1.1 Mg m-3 in the subsoil.
Significantly low bulk density was observed in the valleys and highest bulk densities were
observed on the summits. The soil organic carbon content ranged between 0.18% in the
subsoil and 14.9% in the topsoil. The soil also had a high dithionite extractable Fe (mean
93±53 g kg-1) and low CEC (mean 26±9 cmolc kg-1). Soil pH and CEC were relatively lower
in the valleys and higher on the summits. Principal component analysis indicated four
principal components accounted for 60% of the total variance. The first principal component
that contributed 23% of the variation showed high coefficients for soil properties related to
organic matter turnover, the second components were related to inherent fertility, the third
and fourth were related to acidity and textural variation.
Hydric indicators identified in Bokong were histisols (A1), histic epipedon (A2), thick dark
surfaces (A12), redox dark surfaces (F6), depleted dark surfaces (F7), redox depressions (F8), loamy gleyed matrix (F2) and umbric surfaces (F13). The thick dark surfaces with
many prominent depletions and gley matrix (A12 and F7) occurred in the valleys, while the
midslopes and footslopes were dominated by umbric surfaces (A13). The indicators F6, F7
and F8 were not common. Indicators that were related to the peat formation (A1, A2 and
F13) were frequently observed.
The relationship between soil water saturation and redoximorphic features was verified by
monitoring the groundwater table with piezometers, installed in ten representative wetlands
at depths of 50, 250, 500, 750, and 1000 mm for two years from September 2009 to August
2011. Redoximorphic feature abundance categories were converted into indices. Strong
correlations were observed between redoximorphic indices and cumulative saturation
percentage. The depth to chroma 3 and 4 (d_34) and depth to the gley matrix (d_gley)
correlations were R2 = 0.77 and R2 = 74 respectively. All redoximorphic indices were poorly
correlated with average seasonal high water table. Strong correlation were also observed
between profile darkening index (PDI) and cumulative saturation (R² = 0.88) and weak
correlations were observed between PDI and average seasonal high water table (R² = 0.63).
A paired t test indicated that soil pH, exchangeable Mg and Na, dithionite extractable Fe and
Al were significantly different between hydric and non-hydric soils. Hydric soils had
significantly higher Mg, Na and Fe content, and significantly low soil pH and Al content.
Generally it appeared that soluble phosphorus, Fe and exchangeable bases accumulated in
hydric soils, while the soil pH and Al content decreased. The mean soil organic carbon
contents were 3.61% in hydric soils and 3.38% in non-hydric soils. However, non-hydric soil
relatively stored more organic carbon (174.4 Mg C ha-1) than hydric soils (155.1 Mg C ha-1).
The mean soil organic carbon density of the study area was 166±78.3 Mg C ha-1) and the
estimated carbon stored was 21619 Mg C (0.022 Tg C; 1Tg = 1012g) within the 1000 mm soil
depth. About 384.9 Mg C was stored in the hydric soils within the study area, which was
about 1.9% of the total carbon stored in the area to the bedrok or depth of 1000 mm. Among
the wetland types, bogs had significantly higher organic carbon levels (6.17%) and stored
significantly higher carbon (179 Mg C ha-1) with at least 44% was store in the A1 horizon.
It was concluded that the strong correlation observed between PDI, d_34, d_gley and
cumulative saturation representing hydric indicators such as histisols (A1), histic epipedon
(A2), umbric surfaces (F13), loamy gleyed matrix (F2) can be used to determine the duration
and frequency of the water table in the landscape studied. These hydric indicators can be
used to delineate wetlands, however, more indicators can be developed.
Identifer | oai:union.ndltd.org:netd.ac.za/oai:union.ndltd.org:ufs/oai:etd.uovs.ac.za:etd-04102014-161222 |
Date | 10 April 2014 |
Creators | Mapeshoane, Botle Esther |
Contributors | Prof CW van Huyssteen |
Publisher | University of the Free State |
Source Sets | South African National ETD Portal |
Language | en-uk |
Detected Language | English |
Type | text |
Format | application/pdf |
Source | http://etd.uovs.ac.za//theses/available/etd-04102014-161222/restricted/ |
Rights | unrestricted, I hereby certify that, if appropriate, I have obtained and attached hereto a written permission statement from the owner(s) of each third party copyrighted matter to be included in my thesis, dissertation, or project report, allowing distribution as specified below. I certify that the version I submitted is the same as that approved by my advisory committee. I hereby grant to University Free State or its agents the non-exclusive license to archive and make accessible, under the conditions specified below, my thesis, dissertation, or project report in whole or in part in all forms of media, now or hereafter known. I retain all other ownership rights to the copyright of the thesis, dissertation or project report. I also retain the right to use in future works (such as articles or books) all or part of this thesis, dissertation, or project report. |
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