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The impacts of future urban growth on streamflow in the Mgeni catchment.

Natural vegetation has been converted to land uses, such as agriculture, commercial forestry

and urban use, to meet increasing human demands for food, fuel and shelter. These land use

changes modify the surface conditions of an area, resulting in changes in hydrological

responses. Urban land use, in particular, has a significant impact on catchment hydrology as a

result of the increased impervious areas such as concrete, tar and roofs. To assess the future

hydrological impacts of urban land use, the scale and location of future urban areas must be

considered. The objective of this study was to assess the hydrological responses to future

urban growth in the Mgeni catchment, South Africa. An urban growth model was used to

generate scenarios of plausible future urban growth and these scenarios were modelled using

a hydrological model to determine the hydrological responses to urban growth.

The plausible future urban growth in the Mgeni catchment was modelled using the SLEUTH

Urban Growth model (SLEUTH). The SLEUTH acronym stands for the input layers required

for the model viz. Slope, Land use, Excluded areas, Urban Extent, Transport routes and

Hillshade. SLEUTH is able to provide the scale and location of future urban growth required

to assess the hydrological impacts of future urban growth. The data requirements and

modelling procedure for SLEUTH is relatively simply and therefore it is well suited to a

South African context. SLEUTH was calibrated and applied to the Mgeni catchment to

project future urban land use. When assessing the 95-100% probability class, the results

revealed that the Henley, Pietermaritzburg and Durban areas would experience the highest

urban growth in the Mgeni catchment by the year 2050. The outputs of the SLEUTH Model

for the Mgeni catchment showed a number of similarities to another application of SLEUTH

in Cape Town. These similarities indicate the SLEUTH performs in a similar way for the two

South African cities. Therefore, it was concluded that the SLEUTH Model is suitable to

account for urban growth in the Mgeni catchment, as required for use in hydrological impact

studies.

The hydrological responses to urban growth in the Mgeni catchment were assessed using the

ACRU model. The scenarios of plausible future urban growth generated by SLEUTH were

overlaid with current land cover layers to generate maps of plausible future urban land use.

The results showed extensive urban growth of >95% probability occurring in the Midmar,

Albert Falls, Henley, Pietermaritzburg, Table Mountain, Inanda and Durban Water

Management Areas (WMAs) by 2050. Increases in mean annual streamflows were observed

in many of these areas; however the Henley, Pietermaritzburg and Table Mountain WMAs

were shown to have greater increases in mean annual streamflow than the other areas that

showed similar increases in urban growth, thus indicating that these WMAs could be

particularly responsive to urban growth in the future. Furthermore, the results showed that the

type of urban land use is important in determining the hydrological responses of urban land

use, as the imperviousness differs between the different urban land uses.

Streamflow responses were shown to be influenced by the scale and location of urban growth

in the Mgeni catchment and specific areas, such as the WMAs along the Msunduzi River,

were identified as potentially responsive to urban growth. Summer streamflows were

indicated as being more responsive to urban land use changes than winter streamflows and

increases in streamflows due to urban growth start to over-ride the impacts of other land uses

which have substantial impacts on hydrological responses such as commercial forestry, and

commercial sugarcane by 2050, whereas in other areas increases were mitigated by the

presence of major dams. Lastly, it was shown that the type of urban land use, such as built up

urban areas when compared to informal urban areas for example, have a significant impact on

streamflow responses. These results are useful as they can be used to inform both water

resources planning as well as urban planning to ensure that South Africa’s valuable water

resources are protected. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2012.

Identiferoai:union.ndltd.org:netd.ac.za/oai:union.ndltd.org:ukzn/oai:http://researchspace.ukzn.ac.za:10413/9488
Date January 2012
CreatorsMauck, Benjamin Alan.
ContributorsWarburton, Michelle Lynn., Jewitt, Graham Paul Wyndham.
Source SetsSouth African National ETD Portal
Languageen_ZA
Detected LanguageEnglish
TypeThesis

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