Trends and Outlook: Agricultural Water Management in Southern Africa COUNTRY REPORT SOUTH AFRICA Joe Stevens and Barbara van Koppen 2015 Table of Contents List of Tables .................................................................................................................... ii List of Figures ................................................................................................................... ii List of Boxes .................................................................................................................... iii Acronyms ........................................................................................................................ iv Acknowledgements .......................................................................................................... v 1 Introduction ............................................................................................................... 1 1.1 Agricultural water management for poverty alleviation and sustainable growth .................. 1 1.2 Trends in irrigated area ....................................................................................................... 2 1.3 Study aim and method ........................................................................................................ 3 1.4 Definitions and research approach ...................................................................................... 4 2. Water resources ........................................................................................................... 7 2.1 Climate ............................................................................................................................... 7 2.2 Temperature ...................................................................................................................... 9 2.3 Evaporation ...................................................................................................................... 10 2.4 Surface runoff and water availability ................................................................................. 12 2.4.1 National water storage levels .............................................................................................. 12 2.5 Groundwater .................................................................................................................... 15 2.6 Transboundary water resources ........................................................................................ 19 2.7 Climate related disasters ................................................................................................... 20 2.7.1 Droughts ............................................................................................................................... 20 2.7.2 Floods ................................................................................................................................... 22 2.8 Status of irrigation ............................................................................................................ 22 3. Water policies, legal frameworks and institutions ....................................................... 24 3.1 Legislation and policies ..................................................................................................... 24 3.2 Public organisations and departments ............................................................................... 26 3.3 Water services and agwater management institutions ....................................................... 27 3.3.1 Department of Water Affairs (DWA) ................................................................................... 27 3.3.2 Catchment management agencies (CMAs) .......................................................................... 28 3.3.3 Water User Associations (WUAs) ......................................................................................... 29 3.3.4 International water bodies .................................................................................................. 29 3.3.5 Water services provision ...................................................................................................... 29 4. Investment in agwater ................................................................................................ 30 4.1 Department of Water Affairs (DWA) .................................................................................. 30 4.2 Department of Agriculture, Forestry and Fisheries (DAFF) .................................................. 32 4.3 Employment in agriculture ................................................................................................ 34 5. Water allocation, pricing and investments .................................................................. 35 5.1 Water used for agriculture as per WMA ............................................................................ 35 5.2 Water allocation ............................................................................................................... 36 5.3 Water pricing and charges ................................................................................................. 37 5.4 Investments in water resource infrastructure .................................................................... 39 ii 6. Food security, nutrition and poverty ........................................................................... 40 7. Case study: Flag Boshielo Irrigation Scheme in Limpopo Province ................................ 42 7.1 Political-economic context ................................................................................................ 42 7.2 Smallholder irrigation ....................................................................................................... 44 7.3 The Flag Boshielo Irrigation Scheme in the pre-independence era ...................................... 47 7.4 Collapse and responses ..................................................................................................... 51 7.5 Investments for self-supply ............................................................................................... 54 7.6 Other case studies: four smaller schemes in Limpopo Province .......................................... 55 8. Conclusions and recommendations ............................................................................. 57 8.1 Hydrological hazards ......................................................................................................... 57 8.2 Lessons from past and present investments ...................................................................... 58 8.2.1 Irrigation scheme investments by government, donors and NGOs .................................... 58 8.2.2 Investments by individuals or groups for self-supply .......................................................... 59 8.2.3 Investments by agri-business ............................................................................................... 59 8.2 Cross-sectoral synergies .................................................................................................... 60 References ..................................................................................................................... 60 List of Tables Table 1: Distribution of registered dams according to reservoir storage capacity............................... 13 Table 2: Status of 25 major dams in South Africa ................................................................................. 15 Table 3: Transboundary aquifers within South Africa .......................................................................... 19 Table 4: Allocation agreements and specifications by transboundary river basin ............................... 20 Table 5: Area irrigated in various provinces of South Africa ................................................................ 22 Table 6: Role of public organisations and departments in management and implementation of policies and legislation .......................................................................................................................... 26 Table 7: Total expenditure of DWA on water infrastructure development ......................................... 31 Table 8: Major infrastructure projects with DWA ................................................................................ 31 Table 9: Expenditure trend of the DAFF (excluding the allocation for administration) ....................... 32 Table 10: Expenditure on farmer support program as percentage of total expenditure by DAFF ....... 33 Table 11: Summary of irrigation water use per ha and cumulative in 19 catchments for 2002 .......... 38 List of Figures Figure 1: Irrigated area as proportion of arable area ............................................................................. 3 Figure 2: Classification of types of investments in irrigation based on types of investors ..................... 5 Figure 3: Percentage of normal rainfall for the hydrological season 2011/12 ....................................... 8 Figure 4: Percentage of normal rainfall for the hydrological season 2011/12 ....................................... 8 Figure 5: Provincial average rainfall (mm) for the period of October 2011 to September 2012 ........... 9 iii Figure 6: Annual mean temperature anomalies (base period 1961-1990) of 27 climate stations in South Africa ........................................................................................................................................... 10 Figure 7: Average S-pan evaporation 2011/2012 hydrological year .................................................... 11 Figure 8: Average S-pan evaporation 2010/2011 hydrological year .................................................... 11 Figure 9: The national water storages for the period 2000 till 2012 .................................................... 13 Figure 10: Comparison of water storages per WMA for 2011 and 2012 .............................................. 14 Figure 11: Groundwater level trends (2011/2012 hydrological year) .................................................. 17 Figure 12: Increasing salinity trend of one of the monitoring boreholes of the Lower Orange catchment ............................................................................................................................................. 18 Figure 13: Indication of dry conditions in South Africa using Standard Precipitation Index ................ 21 Figure 14: Distribution of irrigation methods ....................................................................................... 23 Figure 15: Nine water management areas in South Africa ................................................................... 28 Figure 16: Employment trend 2008-2013 in agriculture ...................................................................... 34 Figure 17: Relative use of water withdrawals per sector ..................................................................... 36 Figure 18: National food self-sufficiency index ..................................................................................... 40 Figure 19: Incidence of severe malnutrition among children under five years (2001-2011) ............... 41 Figure 20: Changes in child malnutrition (stunting, wasting and under-weight) from 1993-2008 ...... 41 Figure 21: National poverty lines: poverty headcount and poverty gap .............................................. 42 Figure 22: Agricultural sector expenditures/budgets (2008 Rand) ...................................................... 44 Figure 23: Flag Bushel Irrigation Scheme .............................................................................................. 48 List of Boxes Box 1: KwaZulu-Natal Department of Agriciulture and Environmental Affairs expenditure trends..…33 iv Acronyms ADA Agri-business Development Agency AMD acid mine drainage ANC African National Congress ARC Agricultural Research Council ARDC Agricultural and Rural Development Corporation AWC Arthur W. Creighton CAADP Comprehensive African Agricultural Development Program CASP Comprehensive Agricultural Support Programme CMA Catchment Management Agency CSFP Comprehensive Farmer Support Programme CSIR Council for Scientific and Industrial Research DAFF Department of Agriculture, Forestry and Fisheries DEA Department of Environmental Affairs DWA Department of Water Affairs FANR Food, Agricuture and Natural Resources [Division} FAO Food and Agricultural Organization of the United Nations GDP Gross Domestic Product ha hectare IWMI International Water Management Institute LBPTC Lesotho Basic Permanent Technical Committee LHWC Lesotho Highlands Water Commission LPL lower-bound poverty line mg/l milligram per liter NEPAD New Partnership for Africa’s Development NGO non-governmental organization NSK Nordelike Sentrale Katoen NTK Noord Transvaal Kooperasie [North Transvaal Cooperative] O&M operation and maintenance OTK Oos Transvaal Kooperasie [East Transvaal Cooperative] pa per annum PPP Public Private Partnership PTO Permission to Occupy PWC Permanent Water Commission RAP Regional Agricultural Policy RDP Reconstruction and Development Programme ReSAKSS – SA Southern Africa Regional Strategic Analysis, Knowledge and Support Systems RESIS Revitalisation of Smallholder Irrigation Schemes RSA Republic of South Africa RSAP IV Regional Strategic Action Plan IV v SADC Southern African Development Community SAPWAT South African Procedure for estimating irrigation WATer requirements SPI standardized precipitation index TCTA Trans-Caledon Tunnel Authority TPTC Tripartite Permanent Technical Committee UPL upper-bound poverty line USAID United States Agency for International Development WARMS Water Authorisation, Registration and Management System WMA Water Management Area WRC Water Research Commission WSA Water Services Authority WSDP water services development plan WSP Water Services Provider WTE Water Trading Entity WUA Water User Association Acknowledgements This report is one of the outputs of the research project ‘Trends and Outlook: Agricultural Water Management in Southern Africa’. This research project was implemented by the Southern Africa Regional Program of the International Water Management Institute (IWMI) as part of the Southern Africa Regional Strategic Analysis, Knowledge and Support Systems (ReSAKSS - SA) project. The study covers agricultural water management at the regional level, with a focus on national agricultural water management in Malawi, South Africa, Zambia and Zimbabwe. A team of researchers has contributed to the project’s realization: M. Akayombokwa, Y. Altchenko, P. Chilonda, T. Dlamini, H. Gemo, M. Hanjra, J. Jiyane, F. Kalibwani, I. Kumwenda, G. Lacombe, J. Lautze, S. Madyiawa, G. Matchaya, M. Matete, A. Mishra, J. Mutiro, C. Nhemachena, S. Nhlengethwa, J. Stevens, B. van Koppen, K. Villholth, C. Xueliang and C. Zawe. The research project was supported by the United States Agency for International Development’s (USAID’s) Feed the Future Program. (The project enhanced regional food security through increased agricultural productivity to sustainably reduce hunger: supporting the achievement of Comprehensive African Agricultural Development Program (CAADP) Pillar 1 in Southern Africa) through USAID’s Southern Africa Regional Program. We thank USAID for its support. 1 1 Introduction 1.1 Agricultural water management for poverty alleviation and sustainable growth About 70 percent of citizens of the Southern African Development Community (SADC) depend on rainfed agriculture for their livelihoods (SADC 2003). Moreover, enhanced and sustainable development of this sector is the engine of improved economic growth, socio- human development, food and nutrition security and alleviation of poverty (SADC 2014a). Broad-based agricultural growth with agriculture-based industrialization can replace the extractive, capital-intensive and often ‘jobless growth’ path as currently persists in SADC’s dual economies. Inclusive agricultural growth not only contributes to national food security at affordable prices, export and foreign currency; it also creates employment for the rapidly growing new generations, narrows the wealth gaps, and stabilizes SADC’s young democracies. However, rain fed agriculture is directly exposed to the hazards of climate. SADC’s rainfall patterns are characterised by high and unpredictable variability over the seasons, years, and decades. Moreover, Southern Africa is predicted to warm up faster than the rest of the world (IPCC, 2014). It is one of the few regions in the world that will experience significantly drier conditions, more extreme and unpredictable dry spells, droughts, and floods, while sea levels will rise faster here than elsewhere. These increased temperatures and less predictable, more variable extreme events hold SADC’s farmers and economy ‘hostage to hydrology’. This is also true where average rainfall is abundant. These predictions of long-term climate- induced changes render the need for ‘no regret’ measures today even more urgent. A key ‘no regret’ measure that turns these climate hazards into opportunities is improved agricultural water management, or ‘agwater management’. Agwater management encompasses a broad menu of techniques ranging from improved on-field water harvesting and soil moisture retention to year-round water storage for year-round fully controlled irrigation of crops, trees and livestock feed; improved water supplies for livestock; and the development of fisheries and aquaculture. Agricultural water management was a vital component in Asia’s Green Revolution to boost the ‘trickle-up’ growth path through poverty alleviation (Jazairy, 1992). The CAADP of the African Union’s (AU’s) New Partnership for Africa’s Development (NEPAD) recognized this unlocked potential throughout Africa by prioritizing the first of its four pillars, that of ‘Sustainable Land and Water Management’. In pillar one, African states committed to the doubling of irrigated area from the 3.5 percent at the time to 7 percent by 2015 (CAADP 2009). 2 SADC’s Regional Indicative Strategic Development Plan (2003, revised in 2007 and 2015) re- affirms CAADP goals, including pillar one. SADC operationalizes this through both its Water Division and the Food, Agriculture and Natural Resources (FANR) Division. The SADC Regional Agricultural Policy (RAP) (SADC 2014a) envisages the improvement of the management of water resources for agriculture (SADC 2014a, section 10.5). In the results framework, outcome 1.4 foresees that water infrastructure for agriculture is expanded and upgraded. The RAP commits to assess the effective utilisation of existing irrigation infrastructure and to promote new infrastructure development (SADC 2014a, section 16.1 (75)). In terms of monitoring, the RAP results framework signals the need to provide baseline data on the number of dams, irrigated area and irrigation management practiced in the SADC region (SADC 2014b). The Regional Strategic Action Plan IV (RSAP IV) (SADC 2015), which is based on the SADC Water Policy (2006) and Strategy (2007) aims at ‘An equitable and sustainable utilization of water for social and environmental justice, regional integration and economic benefit for present and future generations’. Noting that there is about 50 million hectares (ha) of irrigable land available within the SADC Region of which only 3.4 million ha (7 percent) is currently irrigated, the RSAP IV emphasizes the importance of infrastructure development and water resource management for food security in the water-food nexus, and the stronger urgency to take action in the view of climate variability and change. RSAP IV also highlights the benefits of multipurpose dams for both energy and irrigation. At local level, SADC Water commits to conduct action-research to develop and sustainably implement resilient water- related infrastructure; and to innovate affordable and appropriate technologies and innovative approaches and practices. Priority interventions are the demonstration and upscaling of community-based water for livelihoods projects (SADC 2015). 1.2 Trends in irrigated area In spite of the major unlocked potentials and strong policy commitments, the average percentage of arable land in SADC has only slightly increased from 7.6 percent in 1990 to 8.4 percent in 2012 according to the Food and Agricultural Organization of the United Nations (FAO’s) AQUASTAT (see Figure 1). A peak was reached a decade earlier. Moreover, the high average percentage of irrigated land is largely the result of irrigation by large-scale agribusiness in only four countries (Madagascar, Mauritius, South Africa and Swaziland). Moreover, both smallholder irrigation in South Africa and irrigated land area in Madagascar declined. 3 Figure 1: Irrigated area as proportion of arable area Source: FAO AQUASTAT This raises a pertinent question: why is irrigation expansion stagnating, and how can this be turned around? Unfortunately, there is no systematic regional body of knowledge to analyze these trends and provide answers. As the Regional Agricultural Policy observes, there is not even a base line on irrigation management practiced in the region, neither for the upgrading of existing infrastructure nor for new investments. Moreover, in spite of the clearly related common goals of the Water and FANR divisions in SADC and in national states, forums to bring these sectors and other relevant stakeholders together are rare. Potential synergies between sectors that would allow each sector to better achieve its goals remain untapped. The present study on ‘Trends and Outlook: Agricultural Water Management in Southern Africa’ seeks to fill these gaps. The project is part of the ReSAKSS – SA project, implemented by the Southern Africa Regional Program of the IWMI. It is supported by USAID’s Feed the Future Program through USAID’s Southern Africa Regional Program. At the interface of both water and agriculture, the IWMI is well placed to enable such dialogue and provide a robust knowledge base on inclusive agricultural growth in general, and agwater management in particular. 1.3 Study aim and method In order to explain the current stagnation and find ways to overcome this, the following questions will be answered:  What are the precise hydrological hazards of climate variability and change, and what is the meaning of ‘water scarcity’ for agriculture in SADC? - 5.0 10.0 15.0 20.0 25.0 30.0 35.0 40.0 A n go la B o ts w an a Le so th o M ad ag as ca r M al aw i M au ri ti u s M o za m b iq u e N am ib ia So u th A fr ic a Sw az ila n d Ta n za n ia Za m b ia Zi m b ab w e SA D C SA D C -e xc l. SA SA D C -L I SA D C -M I P e rc e n t Average level : 2000-2003 Average 2003 Average level : 2003-2008 Average level : 2009-2012 7% increase -SADC RISDP Target 4  What lessons can be learnt from past and current investments in agwater management in SADC, in particular from their strengths and weaknesses in sustainably contributing to poverty alleviation, food security and agricultural and economic growth?  How can SADC and national government, non-governmental organizations (NGOs) and donors build on these strengths and overcome weaknesses?  What are the untapped synergies between the public sector agencies with mandates in agriculture and those with mandates in water management, so that both sectors can achieve their goals more effectively? The method to answer these generic questions consisted of both an extensive literature review and analysis of past performance (Mutiro and Lautze 2015), as well as interviews with key stakeholders at SADC and national levels. Further national studies with illustrative in- depth case studies were conducted in four selected countries: Malawi, South Africa, Zambia and Zimbabwe. This report is the Country Report for South Africa. The Synthesis Report and the four country reports of the Trends and Outlook: Agricultural Water Management in Southern Africa Project are available at www.iwmi.org - Southern Africa Regional Program. 1.4 Definitions and research approach Agwater management encompasses a wide range of interrelated hard- and software measures to ensure that the right quantities of water of the right quality reaches the right sites of agricultural (and other) uses at the right time. Improved water control enables crop diversification, stabilizes and increases crop yields, and enables more cropping seasons, including the slack and hunger seasons. Storage in dams or in ‘green infrastructure’ (such as recharged aquifers or managed wetlands) attenuates floods. Hardware typically includes (combinations of) infrastructure to harvest and store precipitation and run-off water by recharging aquifers, to convey and apply water, and to drain excess water. This study focuses primarily on water supply to crops through infrastructure that extends beyond in-field soil and water conservation alone. There are various classification systems of agwater management – and even more blends: by source (well, surface storage, stream, wetland, groundwater); by technology (which often determines the scale as well); by ownership and/or management either by individuals or communal groups; by plot size and/or scheme size; by goal of investment and type of beneficiaries (household food security; marketing); by formal or informal in terms of formalized, written and state-backed rules; whether privately invested in capital costs and/or operation and maintenance (O&M), and rehabilitation, or by government, NGOs or otherwise; etc. http://www.iwmi.org/ 5 Figure 2: Classification of types of investments in irrigation based on types of investors For the present purpose of learning lessons for investments, we build on the latter; so the main criterion to distinguish the different types of irrigation is: who is the main investor in the construction and installation of infrastructure? Capital costs are usually the most expensive part of irrigation. Moreover, claims to the water stored and conveyed tend to go together with investments in the infrastructure and subsequent maintenance (‘hydraulic property rights creation’) (Coward 1986). As we will see, although their performance varies widely, each type is quite specific in terms of the historical and political-economic context in which it emerged and continues to exist, and its strengths and weaknesses in contributing to poverty alleviation and socio-economic growth. The first type of irrigation investments are by governments, both before and after independence. International donors and financers typically work through governments, while most NGOs also work in close collaboration. Government- or NGO-financed schemes are typically collective schemes. They may be accompanied by resettlement at local or wider scales. The involvement of government can range from very strong (in government-run schemes) to a role that is limited to design and financing of the infrastructure construction and sometimes rehabilitation, leaving all other tasks to communities. In addition to investing in infrastructure, governments also play unique roles as regulator and custodian of the nation’s land and water resources in SADC’s evolving resource tenure systems. Governments influence the next two types of irrigation in both capacities. The second type of irrigation investments are by citizens – also known as self-supply – where citizens are the key investors in infrastructure for their own benefits. That is done by 6 individuals or groups, and often is seen as informal. Adaptation to climate variability through these investments has been at the heart of agrarian societies’ survival since time immemorial. One strategy for people is move to and from water through their settlement patterns. Both farmers and pastoralists look for the better-watered areas with better rainfall and fertile soils throughout the seasons, also using receding floods and water that accumulates in valley bottoms or entire floodplains for dry season cropping and grazing. People’s other age-old strategy is to make water move to them, which requires investments in infrastructure. Household wells provide groundwater for domestic uses, livestock, and small-scale production at and around homesteads. Free gravity energy has long been tapped in mountainous areas in river-diversions, sometimes with night storage. These are typically for domestic uses, irrigation, brick making and other uses. The availability of new appropriate technologies boosts innovation. Multi-purpose infrastructure is the rule; single uses are the rare exception, because rural (and peri-urban) people have multiple water needs, and multi- purpose infrastructure is more cost-effective. People also use and re-use the changing multiple water sources for greater environmental resilience. The public sector plays a role in supporting technology development and uptake, for example by stimulating market-led equipment supply chains. The Regional Agriculture Policy (SADC 2014a) promotes the removal of import tariffs on equipment for that reason. Effective forward and backward linkages as a result of broader agricultural support for inputs, marketing and skills development are a key ‘pull’ factor to convince farmers to invest in infrastructure. Further, government’s land and water policies, laws and regulations also affect investments for self-supply. The third type of investments in infrastructure are those by agri-business. Colonial settlement and state formation was largely shaped around this type of investment, and it forms the basis for SADC’s dual economy of highly mechanized, often export-oriented large-scale farming; alongside largely manual smallholder agriculture, lack of electricity, poverty and unemployment. The financial crisis of 2008 fuelled further foreign or national investments in SADC’s abundant land and related water and mineral resources, also dubbed as ‘land and water grabs’ (Mehta, 2012). Governments play key roles in these investments through their national investment policies, public-private partnerships and, especially, their post-colonial custodianship of both land and water resources. In South Africa with its specific colonial history, the dominant form of agricultural production is by this last form of investors: medium- to large-scale farming. These capital-intensive farms cover most of the country’s 12.7 million hectares (ha) that are cultivated (which is 10 percent of the total land area). Slightly more than 1.3 million ha of this cultivated land (i.e. 10 percent) is under irrigation (DAFF, 2010). Only an estimated 3 percent of these are irrigation schemes in the former homelands, cultivated by smallholders. The Sections two to six (by Joe Stevens of the University of Pretoria) provide a detailed national analysis of what is largely 7 agri-business agriculture and overall water resources availability and sectoral uses, water policies, laws, institutions and investments and national food security, nutrition and poverty. The case study in Section seven focuses on the Flag Boshielo (smallholder) Irrigation Scheme in a former homeland of one of the poorest provinces: Limpopo Province (by Barbara van Koppen, IWMI). Four comparative small case studies were compiled by Janane Jiyane and Barbara van Koppen. 2. Water resources Water is a common thread that connects the three critical issues of food, energy and climate change. It is one of the key focus areas in enabling growth and development, and plays an important role in the green economy. Water is essential for social and economic developments and for the maintaining of healthy ecosystems. Sustainable economic development is only possible if we recognise the limited capacity of ecosystems to supply the necessary water needed for agriculture, industry, energy, generation and the production of many goods and services required by society. The National Development Plan: Vision 2030 identifies water as a strategic resource that is critical for social and economic development (National Planning Commission, 2011). 2.1 Climate Climate includes processes such as precipitation or rainfall, evaporation and temperature that are variable, and can have important implications on runoff, dam storage levels, and supply of water for domestic purposes, rain-fed agriculture, groundwater recharge, forestry, and biodiversity, as well as for maintaining or changing sea levels. A reduction in rainfall or its variability and an increase in evaporation due to higher temperatures have impacts on the country’s scarce water resources. The climate varies from desert to semi-desert in the west to sub-humid along the eastern coastal areas. The natural availability of water across the country is highly uneven due to the poor spatial distribution of rainfall. This is compounded by the strong seasonality of rainfall over virtually the entire country, and the high within- season variability of rainfall. The country’s average annual rainfall is 450 mm per year, well below the world’s average of 860 mm, while evaporation is comparatively high (Stats SA, 2010). Only 10 percent of the country receives an annual precipitation of more than 750 mm, and approximately 62 percent of South Africa’s water resource is used for agricultural purposes. Rainfall in South Africa has a water supply potential per capita of just over 1 100 m3 pa. Both commercial farming and especially subsistence farming may be affected by less availability of water owing to adverse climate change. This is expected to vary across the different agro-climatic zones, provinces and different agricultural systems in the country. In general, less rain was received during the 2011/12 hydrological year (Figure 3) as compared to the previous period of 8 2010/11 (Figure 4). The central part of the country receives its rain mainly in summer. However Figure 3 shows that the central interior experienced heavy rainfall rain in June; this could be a contribution of changes in climate. Figure 3 shows that approximately half of the country experienced dry to very dry conditions. Only parts of Western, Eastern and Northern Cape Provinces received fair rainfall. The month of May was the driest month as almost the whole country received very little or no rain (Figure 3). Figure 3: Percentage of normal rainfall for the hydrological season 2011/12 Source: SAWS in DWA undated Figure 4: Percentage of normal rainfall for the hydrological season 2011/12 Source: SAWS in DWA undated Figure 5 shows the average provincial rainfall for 2011/2012, and according to this figure most provinces experienced high rainfall during the months December and January 2011/2012. Mpumalanga and Limpopo Provinces received the most during January as a result of the tropical cyclone Dando, which caused floods during that time. KwaZulu-Natal 9 was hit by tropical cyclone Irina in March, resulting in the high rainfall. The Western Cape received the highest rainfall during June-August as it was expected as the southern-western region of the country receives winter rainfall. Figure 5: Provincial average rainfall (mm) for the period of October 2011 to September 2012 Source: DWA undated The rainfall trend, per province, over an 11 year period, is showing a downward trend in rainfall as of 2001-2009. The country received the least rain (≥ 40 mm pa) between 2005 and 2009, with the exception of the Western Cape which received between 60-80 mm pa. 2.2 Temperature There has been a noticeable increase in temperatures across the country in the past 40 years. During the summer months of 2011/12, temperatures greater than 26 ℃ were observed in the Northern Cape, North West, Limpopo and northern parts of KwaZulu-Natal Provinces (SAWS, 2014). The winter months saw temperatures soaring to below 10 ℃, resulting in some parts of the country experiencing cold conditions and snow fall. The statistical evidence is showing that South Africa is getting hotter over the past four decades. Kruger and Shongwe (2004) analyzed climate data from 26 weather stations across the country (Figure 6). Of these, 23 showed that the average annual maximum temperature had increased, in 13 of them significantly. Average annual minimum temperatures also showed an increase, of which 18 were significant. In general, their analysis indicates that the country’s average yearly temperatures increased by 0.13°C per decade between 1960 and 2003, with varying increases across the seasons: fall 0.21°C, winter 0.13°C, spring 0.08°C and summer 0.12°C. There was also an increase in the number of warmer days and a decrease in the number of cooler days. 10 Figure 6: Annual mean temperature anomalies (base period 1961-1990) of 27 climate stations in South Africa Source: Kruger et al 2012 These changes in temperature, together with the already scarce water resources in the country are expected to have a significant effect on all sectors of the economy, in particular agriculture. For example, anecdotal evidence suggests that climate change could lead to a fall of about 1.5 percent in the country’s gross domestic product (GDP) by 2050 – a fall roughly equivalent to the total annual foreign direct investment in South Africa at present. Moreover, climate change and the resulting loss of biodiversity could do irreparable damage to the country’s tourism industry, which is worth an estimated R100 billion/pa (about USD 10 million). 2.3 Evaporation As shown in Figures 7 and 8, evaporation appears to have increased over a wide area in South Africa. In 2011/12 the Lower Orange and Lower Vaal Water Management Areas (WMAs) being the most affected and Limpopo to some extent. In 2010/11, the most affected area was in the Lower Orange WMA. The high evaporation in these areas can be linked to very high temperatures between January and March 2012. 11 Figure 7: Average S-pan evaporation 2011/2012 hydrological year Source: DWA undated Figure 8: Average S-pan evaporation 2010/2011 hydrological year Source: DWA undated 12 2.4 Surface runoff and water availability The surface runoff is the total amount of water from precipitation flowing into a river or a stream or the sum of the direct run off and base flow. Direct runoff is the sum of surface and interflow (Stats SA, 2010). About one third of the precipitation that falls over the land runs into streams and rivers and is returned to the oceans. The other two thirds is evaporated, transpired or infiltrates into groundwater. The drainage, vegetation, land use and soil types have an influence on runoff. Also human factors such as urbanisation and development can reduce infiltration. In South Africa the construction of drainage networks, removal of soil and vegetation (degradation) and cultivation of land surface, increase the runoff volumes and shorten runoff times into streams and rivers. During the period 2011/2012 the surface runoff was generally lower than previous years, except for the southern and Western Cape, as these areas experienced heavy winter rains which caused flooding in July 2012 (DWA, 2013b). South Africa experiences uneven spatial distribution and seasonal rainfall as illustrated, and therefore some of the country’s catchments and water management areas are experiencing water stress. The uneven distribution of rainfall together with the rapid population growth (approximately 52 million people (Stats SA, 2013) and economic development are exacerbating the problem of adequate supply. Approximately 9 500 km3 pa of the total requirements for water of 12 871 km3 pa is abstracted from the surface water resources, while the remainder comes from groundwater, the re-use of return flows and the interception of water by afforestation. Total requirements therefore represent approximately 20 percent of the total Mean Annual Runoff of 49 040 km3 pa. A further 8 percent is lost by evaporation from storage and conveyance along rivers, and 6 percent through land use. Approximately 66 percent of the Mean Annual Runoff country wide remains in the rivers. The temporal flow distribution of the remaining water has been significantly altered as a result of upstream regulation and use, and it therefore no longer reflects the characteristics of the natural stream. It however fulfils the substantial requirements of the Ecological Reserve and the downstream international commitments. 2.4.1 National water storage levels Generally, the surface water resources are highly developed over the country, with about 350 major dams and many smaller storage dams, having a total capacity of more than 37 000 km3, or more than 66 percent of the Mean Annual Runoff. This includes the draining of Lesotho (4 800 km3 pa) and Swaziland (500 km3 pa). In South Africa 4 755 dams were registered up to 2012 in terms of section 120 of National Water Act. In terms of this Section, all dams with a safety risk (i.e. if the wall height exceeds 5m and if the storage capacity exceeds 50 000 m3 must be registered by the dam owners (DWA, 2013b). Table 1 provides the distribution of registered dams according to reservoir storage capacity. 13 Table 1: Distribution of registered dams according to reservoir storage capacity Capacity(x106 m3) Number percent 0.00-0.05 152 3.1 0.05-0.10 1 181 24.8 0.10-0.25 1 710 36 0.25-1.00 1 078 22.7 1.00-10.00 437 9.2 10.00-100.00 129 2.7 100-1 000 60 1.3 1 000-10 000 8 0.2 Total 4 755 100 Source: DWA 2013b There have been fluctuations in the storage levels in the past 13 years with 2011/2012 being the 9th highest in total storage (DWA, 2013b). This could be an indication of the lower rainfall and runoff experienced during 2011/2012 (Figure 9).The storage levels in 2011/12 showed a decrease in storage till June 2012, thereafter a gradual increase. Generally the storage (2011/12) was lower than during 2010/11 (DWA, 2013b). Figure 9: The national water storages for the period 2000 till 2012 Source: DWA 2013b Some provinces have dams with large capacities while others have small capacity. The Free State Province has five large dams with total full supply capacity of greater than 1 000 million 14 m3 namely; Gariep, Vanderkloof, Sterkfontein, Vaal and Bloemhof. Gauteng has only 5 very small dams with total full supply capacity of 114.8 million m3. Northern Cape has few small dams with total full supply capacity of 145.5 million m3 which is the lowest of all the provinces. The Western Cape has many very small dams with Tweewaterskloof Dam being the largest. The storage situations of reservoirs within the provinces for 2011/12 were lower compared to the previous hydrological year with the exception of the Western Cape, which showed higher storage than the previous period (DWA, 2013b). This could be attributed to less rainfall experienced during the reporting period. The high rainfall in the Western Cape caused flooding in some areas. The Upper Orange WMA had the highest full supply capacity followed by the Upper Vaal and Usutu to Mhlathuze. Because of the volumes of water in the Upper Orange, there are a number of transfers to other catchments (Figure 10). The Upper Vaal receives a transfer from the Lesotho Highlands to ensure it meets the water demand. The Lower Vaal, Lower Orange and Olifants/Doorn have the least number of dams with very low capacities. Although Usutu to Mhlathuze has eight dams, their total capacity is low at 115.3 million m3. Figure 10: Comparison of water storages per WMA for 2011 and 2012 Source: DWA 2013b Table 2 illustrates the storage status of 25 major dams in the country. 15 Table 2: Status of 25 major dams in South Africa Source: DWA 2013b 2.5 Groundwater Responses of groundwater quantity and quality are different from surface waters in that groundwater depends on geological structures, soil conditions, rainfall patterns and anthropogenic activities in the recharge zones of the aquifer systems. Aquifer media in South Africa is classified as illustrated in Figure 11. The Department of Water Affairs (DWA)1 has produced Hydrogeological Maps at a scale of 1:500 000 covering most of the country, indicating aquifer types and related aquifer properties. The Department also developed a National Groundwater Strategy in 2010 (DWAF, 2010). One of its aims is that the knowledge and use of groundwater is increased along with the capacity to ensure sustainable management. Some aquifers extend across international borders (transboundary aquifers), resulting in a joint responsibility for their management and development. 1 The name was Department of Water Affairs and Forestry. When Forestry moved to the department of agriculture, the name became Department of Water Affairs (DWA), as used in this report. In 2014 the name changed to Department of Water and Sanitation (DWS). 16 The Utilizable Groundwater Exploitation Potential in South Africa is estimated at 10 343 km3 per year (7 500 km3 in a drought year), allowing for factors such as physical constraints on extraction, potability, and a maximum allowable drawdown (DWAF, 2010; Middleton and Bailey, 2009). The country only uses between 2 000 km3 and 4 000 km3 per year of this groundwater currently. This is approximately 16.1P of the country’s total water use (both surface and groundwater) based on the information registered in Water Authorisation, Registration and Management System (WARMS) (DWAF 2007). The actual percentage is perceived to be higher considering that Schedule 1 use is not registered in the system. The biggest challenge for South Africa is that the groundwater resources are not evenly distributed, but spread variably over the country. This can be an advantage in providing water for small-scale local use, but for distributing it to centres of need will require a large number of boreholes and connecting pipelines. Groundwater level trends for 2011/12 are illustrated in Figure 11. The north-eastern parts of the country received “below normal” rainfall, which affected groundwater recharge, resulting in the decline in groundwater levels. Due to continuation of local abstraction rates, a general decline in the aquifer saturation levels has been observed in some areas specifically the Limpopo Region (Limpopo, Luvuvhu and Letaba and the Olifants Catchments). These are the catchments that experience a long-term declining condition (water table recession rates in the order of 0.3 to 1 m pa). Towards the west, ground water level trends are also declining, although varying between 0.2 and 5 m pa. High water level declines were observed at bulk water supply schemes such as Grootfontein (5 m since June 2012) and certain dolomitic aquifer compartments in Gauteng (2 m since October 2011 in the Far West Rand). The annual rainfall for this region was significantly lower during 2011/12, with only 490 mm measured in Pretoria East, unlike the previous year where prolonged and heavy rainfall events were experienced from mid-December 2010 and led to significant recharges. Groundwater levels in KwaZulu-Natal reported similar declining trends (DWA, 2013b). The south-western regions of the country experienced significant groundwater recharges. High winter rainfall and snowfall in some regions initiated a replenishment of aquifer systems thus the rising water levels. Aquifer saturation levels of the Brandwag Aquifer Unit (east of Beaufort West) increased by almost 38 m due to the good rains received during that time. This particular recharge event was enhanced by significant snowfalls and associated winter rainfall in the Western Cape during the past two hydrological years (2010/11 and 2011/12) (DWA 2013b). 17 Figure 11: Groundwater level trends (2011/2012 hydrological year) Source: DWA 2010 Concerning is the fact that very little research could be found on the groundwater-surface water interaction and related impacts. DWA is currently using a surface-ground water interaction model to quantify the impact; however the applicability on a large scale is questionable (DWA, 2010). Groundwater quality The north-western parts of the country indicate low quality conditions with electric connectivity recording above 520 mS/m. Groundwater quality deterioration in the northern sub-catchment of the Lower Orange, i.e. the Nossob and Auob Rivers flowing from Namibia, is a concern, and the cause for that is not clear yet. The groundwater salinity trends for the 2011/12 hydrological year are illustrated in Figure 12. For the larger part of the country, salinity trends were quite stable and varied (standard deviation) between < 5 mg/l (almost stable) and 50 mg/l. These are representing small water quality oscillations due to internal aquifer quality modulation and annual recharge events replenishing the aquifer systems with good quality rainwater. Groundwater salinity improved in the Limpopo and Olifants Catchments and some localised aquifer systems in the Crocodile-West and Marico Catchments. Similarly, salinity improved in the northern parts of the Lower Vaal. In other areas groundwater quality deteriorated mainly showing higher salinity values. Although these increasing salinity values were significant (in the order of 205 -160 mg/l), they manifested after April-May 2012, and could be an 18 indication of sporadic local pollution due to local recharge events after a long dry period, especially those in the Gouritz, Fish to Tsitsikamma and the Mzimvubu to Keiskamma Catchments. However, the salinity increase in the Upper Orange and Lower Vaal is part of a long-term decreasing water quality trend in the order of about 15 mg/l pa. Figure 12: Increasing salinity trend of one of the monitoring boreholes of the Lower Orange catchment Source: DWA 2010 To illustrate the alarmingly rapid deterioration of groundwater quality in the Lower Orange, Figure 12 was plotted showing salinity trends from 1996 to 2012. Since then, electrical conductivity increased from 220 mS/m to about 435 mS/m in this borehole. The acid mine drainage (AMD) is one of the water quality challenges emanating from mining activities. The seepage water from abandoned open pits, mine waste dumps, tailings, stockpiles and mine shafts is highly acidic. The most affected areas by AMD are the gold mines in the Western Basin (Krugersdorp area), the Central Basin (Roodepoort to Boksburg) and the Eastern Basin (Brakpan, Springs and Nigel areas) of the Witwatersrand. Mining in these areas ceased in 2010, and since then the underground voids have been filling up with AMD. Other areas affected by mining activities include Mpumalanga, Limpopo and Kwa-Zulu Natal. Various remedies are being implemented:  Reducing the ingress of water into the underground workings to reduce the volumes of water which need to be pumped out and treated to more acceptable levels.  Reducing or stopping decant of AMD into the river system, and only releasing during high water flows. 19  Treating and neutralising the water that is pumped out to enable productive uses (well- controlled irrigation) or discharge to river systems.  Implementing waste discharge charges to be paid by mines. Lastly, DWA is also tightening the control of hydraulic fracturing in areas like the Karoo and Free State. Uncertainty exists regarding the impact of this on the environment, and especially on groundwater quantity and quality, and also on the provision of water. 2.6 Transboundary water resources The bulk of South Africa’s water resources are transboundary in nature and this has implications for quality, quantity and environmental and disaster management. South Africa shares four international river basins, namely Orange, Inkomati, Limpopo and Maputo with six neighbouring countries, namely Botswana, Lesotho, Namibia, Swaziland, Mozambique and Zimbabwe (Table 3). To ensure good management of water resources, bilateral cooperation agreements were signed between South Africa and each of the countries involved. South Africa is signatory to the SADC Protocol on Shared Water Courses, making an obligation to cooperate with its neighbours in the management of water resources. Table 3: Transboundary aquifers within South Africa Transboundary River basin Riparian States Transboundary aquifers within the river basin Aquifer riparian state within river basin Orange Botswana Lesotho Namibia South Africa Gariep Coastal Aquifer Karoo Sedimentary Aquifer Kalahari Aquifer Promfret Vergelegen Dolomite Aquifer Namibia-South Africa Lesotho-South Africa Botswana-South Africa Botswana, Namibia, South Africa Botswana -South Africa Limpopo Botswana Mozambique South Africa Zimbabwe Pafuri Aquifer Tuli-Sashe Aquifer Ramotswa Dolomite Aquifer Limpopo Granulite Aquifer Mozambique, South Africa and Zimbabwe Incomati Swaziland Mozambique South Africa Incomati Coastal aquifer Mozambique, South Africa and Swaziland Maputo Swaziland Mozambique South Africa Incomati Coastal aquifer Mozambique, South Africa and Swaziland Source: Turton et al 2005 Table 4 illustrates the allocation agreements and specifications by transboundary river basin. 20 Table 4: Allocation agreements and specifications by transboundary river basin Source: CSIR 2010 2.7 Climate related disasters The most common extreme events in South Africa are drought and floods. These can be destructive resulting in loss of life and damage to infrastructure. Floods can also have positive effects such as recharging natural ecosystems. The impact of drought is usually shown by reduction in flows, as there is less or no rain at all. Reduced flow could translate into low dam storage. 2.7.1 Droughts Drought is usually driven by natural climate variability which also affects the availability of water. The percentage of normal rainfall has been fluctuating in terms of space and time over the past few years. Very dry conditions are putting severe pressure on South Africa’s scarce resources, and are therefore a threat to food security. Drought conditions are also a threat to livestock farming as it diminishes food and water supply. It contributes to poverty, poor health, malnutrition as communities cannot plant or crops become damaged. In the coastal 21 areas, when freshwater runs low, seawaters move in rendering water saline. The levels of groundwater, dams and flows in rivers are affected during drought conditions resulting in limited resources. Water restrictions are usually implemented in some areas as a way of managing resources. Figure 13: Indication of dry conditions in South Africa using Standard Precipitation Index Source: DWA undated Drought conditions are a result of low rainfall and very high temperatures, resulting in less runoff, low storage levels and loss of soil moisture. Dry conditions are usually indicated by using a standardized precipitation index (SPI). Twelve- and twenty four-month SPI maps give an indication of areas where prolonged droughts existed because of below-normal rainfall recorded over a period of one year or longer. Figure 13 illustrates the extent of dry conditions experienced in the country. There is clear indication that parts of North West, Limpopo, Free State, Mpumalanga and Northern Cape Provinces were affected by moderate to extremely dry conditions. 22 2.7.2 Floods Flow gauging stations are used for early flood warning both in the country and in neighbouring states. Unfortunately, some of the stations are no longer working well because some of the instruments and telemetry systems were damaged during heavy rains and were never repaired. A majority of the big dams have free overflow spillways; which means that, when they are full, the quantity of water that flows in flows out at the same time. This gives a challenge as these dams have limited options to be operated for flood management. In January 2012, heavy rains fell in south east Africa (including Mozambique) affecting the Limpopo and Mpumalanga Provinces of South Africa. Roads were damaged and bridges washed away and lives were lost. In South Africa, the Hoedspruit area was the most affected with people having to be lifted to safety from trees and rooftops. The flooding was as a result of a severe tropical low pressure system Tropical Cyclone Dando, a fourth storm to hit the country during the season. The January floods were influenced by La Nina. In March 2012 flooding also hit St. Lucia, Richards Bay and Durban in the Kwa-Zulu Natal Province due to Tropical Storm Irina which caused severe damage to houses and infrastructure. The storm also affected Mozambique and Swaziland. The Liesbeek River burst its banks. The Western Cape experienced floods in the third quarter of the hydrological year which were accompanied by very cold weather. Port Elizabeth and surrounding areas in Eastern Cape had its share of flooding and snow in July 2012. 2.8 Status of irrigation Of the total cultivated land area estimated at 12.7 million ha (about 76 percent of total potentially arable land), 11.2 million ha is dryland farming, and 1.8 million ha irrigated (producing about 25–30 percent of the country's agricultural products). The total dryland (rainfed) crops in 2002 were just over 3 million ha, which totalled over 16 million tons production. Of the total agricultural production of USD 2 311 900 000 in 2002, irrigation agriculture produced 55 percent of the agricultural produce by value, making this a key role player in the South African economy. Table 5: Area irrigated in various provinces of South Africa Province Area irrigated (ha) Western Cape 286 004 Northern Cape 188 903 Free State 137 887 Eastern Cape 188 901 KwaZulu Natal 131 032 Mpumalanga 129 308 Limpopo 161 127 Northwest 101 593 23 Province Area irrigated (ha) Gauteng 29 372 Total 1 354 127 Source: DAFF 2010 According to DAFF (2010) approximately 1 354 127 ha is currently irrigated (Table 5) of which 3 percent are small scale irrigation schemes. Various irrigation methods are used for the irrigation of the approximately 1.3 million ha (Figure 2.12). Figure 14: Distribution of irrigation methods Source: DWA 2007 The distribution of farm activities in the nine provinces indicates that all the provinces except Gauteng are important for farming, with varying degrees of importance in the four main farm activities. Large proportions of field crop farming are located in the arid zone of the Free State (32 percent), the North West (17 percent) and Mpumalanga (14 percent), and also in the winter rainfall zone in the Western Cape (14 percent) with the least in Gauteng. The winter rainfall zone of the Western Cape Province (45 percent) is also the most important area for horticulture, followed by the desert zone of the Northern Cape Province (16 percent). In the arid zone the most important provinces for this activity are Limpopo (14 percent) and the Eastern Cape and Mpumalanga (6 percent each), with the least important being Gauteng. Mixed farming is also more prominent in the Northern Cape (24 percent), the Western Cape and the Free State (15 percent each) and least prominent in Gauteng. This implies that field crop farming is most suitable in the arid zone, horticulture in the winter rainfall zone and livestock farming in the desert zone. The Free State, Limpopo, Mpumalanga, North West, Eastern Cape, Western Cape and Northern Cape are important provinces for 24 farming activities in the three agro-ecological zones. The sub-tropical wet zone (mainly the KwaZulu-Natal Province) is particularly important for sugar cane. The main irrigated field crops produced (covering just below two thirds of the irrigated area) include maize, wheat, dry beans and soya beans. The horticulture crops (on over one third of the irrigated area) include a huge variety of deciduous fruit (peaches, apricots, plums, prunes and table grapes); pome and stone fruit (apples and pears); citrus; subtropical fruit (banana, mangoes, papaya, etc.), viticulture (wine grapes) and the huge vegetable industry. The real gross income from horticulture crops moderated from 4.4 percent registered in 2012 to 2.4 percent during 2013. Among the horticulture crops, vegetables (35.6 percent) deciduous and other fruit (24.5 percent), viticulture (14.3 percent) and citrus (13.4 percent) accounted for 85 percent of the total real income of horticulture products in 2013 (BFAB, 2013). The real gross income of field crops during 2013 is mainly attributed to maize (49.3 percent), sugar (16.1 percent), wheat (11 percent), sunflower seed (5.8 percent) and soya beans (5.3 percent). Together these five commodities accounted for 88 percent of the total real income of field crops, of which a small percentage is produced under irrigated conditions. 3. Water policies, legal frameworks and institutions 3.1 Legislation and policies In South Africa there are various policies and Acts steering the management and protection of agricultural water resources. The relationships between the Constitution, the National Development Plan: Vision 2030, the National Water Act and the National Water Resource Strategy are important to understand as it provides:  The national framework for managing water resources.  The framework for the preparation of catchment management strategies.  Provision of water-related information.  Identification of development opportunities and constraints. In 1994 the newly elected government put forward as its manifesto the Reconstruction and Development Programme (RDP). This initiative was based on the fundamental concept that people who are affected by decisions should take part in making them, and it set out five key programmes: meeting basic needs; developing our human resources; democratising the state and society; building the economy; and implementing the RDP. Water is an essential ingredient in each of these programs. The Constitution of the Republic of South Africa (RSA, 1996) contains both a Bill of Rights and the framework for government in South Africa. Two provisions of the Bill of Rights are 25 particularly relevant to the management of water resources. These are sections 27 and 24, which state that:  Everyone has the right to have access to sufficient food and water, and the state must take reasonable legislative and other measures, within its available resources, to achieve the progressive realisation of these rights.  Everyone has the right to an environment that is not harmful to their health or wellbeing, and to have the environment protected, for the benefit of present and future generations, through reasonable legislative and other measures that prevent pollution and ecological degradation, promote conservation, and secure sustainable development and use of natural resources while promoting justifiable economic and social development. These two documents provided the impetus for a complete review and revision of the policy and law relating to water, and resulted in the development of the National Water Policy for South Africa (RSA, 1997a) and the National Water Act (RSA, 1998). The Policy and the Act are founded on the principles of equity, sustainability and efficiency. The 1994 Water Supply and Sanitation Policy White Paper (now superseded by the Strategic Framework for Water Services (DWAF, 2003)), and the Water Services Act, 1997 (RSA, 1997b), which deal with the provision of potable water and sanitation services, are particularly closely related to the Act. The National Water Resource Strategy (DWA, 2013a) responds to South Africa’s vision for 2030, as articulated in the National Development Plan and to the national government outcomes outlined in National Government’s Programme of Action for 2010-2014. These priorities are key drivers for change and, as such, are the national strategic imperatives that shape this Strategy. In its Vision 2030, the National Development Plan articulates the national development goal of eradicating poverty and sharply reducing inequality by 2030 (NPC, 2011). To achieve this, government has defined a New Growth Path, one of inclusive growth and development, with a focus on diversification and wide participation by South African citizens within a vibrant and growing economy. As water plays a central role in all sectors, including agriculture, energy, mining, industry, tourism, urban growth and rural development, the allocation, development and protection of water is an essential prerequisite for inclusive economic growth, poverty reduction and the significant reduction of inequality in South Africa. The National Water Resource Strategy provides a framework that ensures water is protected and conserved over the long-term, but also contributes to the attainment of the social and economic goals of the country. Above all, the National Water Resource Strategy warns that it will be increasingly difficult and costly to meet the growing demands for water. A range of measures are initiated (DWA, 2013a):  Greater focus on water conservation and demand management.  Increased utilisation of ground water.  Re-use of water at the coast as well as in inland systems.  Using the most cost-effective and suitable sites for dams and transfer schemes. 26  Desalination of sea water and de-acidification of mine water.  Catchment rehabilitation, clearing of invasive alien plants and rainwater harvesting. Land reform and policy The establishment of an “integrated and inclusive rural economy” has been identified in the National Development Plan as one of the key goals for achieving their vision 2030. In real terms (measured in 2013 values) more than R69 billion ZAR (USD 6,9 billion) has been spent by the state on the three main subprograms of land reform since 1994, with a variety of instruments that have changed over time. Yet, these programs share one characteristic, namely they all represent attempts to solve the problem of skewed distribution of land in South Africa. The impact of this land reform on agriculture and especially irrigation is immense, since it not only applies to the transfer of productive agriculture land to new owners but also reallocation of water to newly established irrigation schemes. Therefore the National Development Plan (NPC, 2011) is quite clear: land reform has to start with the (re- )creation of a comprehensive farmer support program whose main aim is to ensure that new entrants into agriculture can farm profitably at whatever scale they decide. It has become clear that a systematic withdrawal of support from white farmers since the 1980s was not replaced by farmer support to new entrants over the past two decades since 1994. Different institutions adhere largely to an application-based or demand-led approach to post transfer support. This means that land reform beneficiaries who need support must approach project officers working for Provincial Departments of Agriculture. The lack of farmer support that exist has compounded the ill effects of South Africa‘s distorted rural space, while the little support that exists is not aimed at addressing the legacy of “betterment” nor of the Marketing Act, and has left the country bereft of food processing and trading enterprises. The National Department of Agriculture’s Comprehensive Farmer Support Programme (CFSP) and the Landcare Programme as well as the Strategic Plan for South Africa Agriculture describe the kinds of farming support it seeks to offer. 3.2 Public organisations and departments Various public organisations and departments are involved in the administration, management and protection of water resources and implementing of policies and legislation (Table 6). Table 6: Role of public organisations and departments in management and implementation of policies and legislation Public organisations and departments Main function National: Department of Agriculture, Forestry Legislation, administration, farmer support programs, development 27 Public organisations and departments Main function and Fisheries (DAFF) of infrastructure on small scale irrigation schemes and aquaculture Department of Water Affairs (DWA) Legislation, administration, bulk water supply, regulation and pricing, water strategies Department of Environmental Affairs (DEA) Environmental impact assessment (biodiversity) and protection of wetlands, lakes, mountain catchment areas, mineral and petroleum resource development and estuaries like Lake St Lucia Council of Geoscience Groundwater studies and research Research organisations such as: Water Research Commission (WRC) Council for Scientific and Industrial Research (CSIR) Agricultural Research Council (ARC) Research on a various aspects regarding water use and agwater Department of Rural Development and Land Reform Agrarian reform Department of Mineral Affairs Mining and pollution (AMD) Department of Tourism Protection of conservation areas (SANPARKS: all the declared conservation parks; Ecological Reserve and pollution) Department of Energy Power generation, use of coal, integrated resource planning Department of Trade and Industry Industrial Policy Action Plan: job creation, agro processing b. Provincial: Provincial Departments of Agriculture (9) Implementation of agriculture policy at provincial level (Landcare and Farmer Support Programme) CMSa Management and administration of water at catchment level (9) Water boards (15) Supplying water to municipalities WSPs The main objective is implementation of the Water Services Act (Act 108 of 1997) which incorporates providing for the right of access to basic water supply WSAs Any municipality responsible for ensuring access to water services in the Act. It may perform the functions of a WSP 3.3 Water services and agwater management institutions The National Water Act (1998) provides the framework for water resource management and outlines the different water management institutions as well as the specific functions of the different institutions. 3.3.1 Department of Water Affairs (DWA) DWA is responsible for administering all aspects of the National Water Act delegated to it by the Minister or Director-General. As the various water resource management institutions are established and the responsibility and authority for water resource management is delegated or assigned to them, the Department’s role will change. It will increasingly focus on national policy, a regulatory framework for water resource management, and ensuring that other institutions are effectively fulfilling their roles and responsibilities. 28 3.3.2 Catchment management agencies (CMAs) CMAs represent the second tier of the water resource management framework. A CMA will be established in each of the 9 water management areas. Each CMA is responsible for the progressive development and broad implementation of a catchment management strategy. The catchment management strategy must be consistent with the National Water Resource Strategy, within its WMA. Currently two CMAs are well functioning namely Inkomati and Breede Overberg. In order to facilitate the management of water resources, the country was divided into 19 WMAs. In 2012 the number has been reduced to nine. Each area is managed by a CMA (Figure 15). Figure 15: Nine water management areas in South Africa Source: DWA 2013a 29 3.3.3 Water User Associations (WUAs) WUAs are associations of individual water users that undertake water-related activities for their mutual benefit. Water management activities may be devolved to WUAs in which case they become the third tier of water management institutions. The precise modalities have been under review since 2014. 3.3.4 International water bodies In addition to CMAs and WUAs, the Act provides for the following types of water management institutions: a. Bodies responsible for international water management such as:  Trans-Caledon Tunnel Authority (TCTA): state owned entity with mission to finance and implement bulk raw water infrastructure. It was created in 1986 to develop Lesotho Highland Water Project. In 2012 the TCTA Lesotho Highlands Water Commission (LHWC) was established (Lesotho, RSA).  Swaziland/RSA Joint Water Commission.  Orange/Senqu River Basin Commission (Botswana, Lesotho, Namibia and RSA).  Limpopo Basin Permanent Technical Committee (LBPTC) (Botswana, Mozambique, RSA and Zimbabwe).  Botswana/RSA Joint Permanent Technical Water Committee.  Mozambique/RSA Joint Water Commission (joint development and utilization of water resources of the Komati River Basin).  Permanent Water Commission (PWC) (Namibia, South Africa).  Swaziland/Mozambique/RSA Tripartite Permanent Technical Committee (TPTC). b. Any other persons or bodies that fulfil the functions of a water management institutions in terms of the Act. 3.3.5 Water services provision The main objectives of the Water Services Act (Act 108 of 1997) (RSA 1997) is to provide for the right of access to basic water supply and sanitation necessary to secure sufficient water and an environment not harmful to human health or well-being. The Act also establishes the institutional arrangements for water services provision, and sets out the responsibilities for each of the institutions. The following are the key institutions in water service provision. a. Water boards Government-owned water boards play a key role in South African water sector. They operate dams, bulk water supply infrastructure, some retail infrastructure and some wastewater systems. Some also provide technical assistance to municipalities. Through their role in the operation of dams they also play an important role in water resource management. The water boards report to DWA. There are 15 water boards in South Africa. The three largest 30 Water Boards are Rand Water in Gauteng Province, Umgeni Water in KwaZulu-Natal Province and Overberg Water in the Western Cape. b. Water Services Authority (WSA) A WSA is defined as any municipality responsible for ensuring access to water services in terms of the Act. It may perform the functions of a WSP, and may also form a joint venture with another water services institution to provide water services. In providing water services, a WSA must prepare a water service development plan (WSDP) to ensure effective efficient, affordable and sustainable access to water services. The WSDP should be in line with the catchment management strategy of that WMA. The plan provides a linkage between water services provision and water resources management. c. Water Services Provider (WSP) The main duty of a WSP is to provide water services in accordance with the Constitution, the Water Services Act and by-laws of the WSA, and in terms of any specific conditions set by the WSA in a contract. 4. Investment in agwater The departments responsible for investing in agwater development and the necessary infrastructure required for the distribution of bulk water in the country are DWA and DAFF. 4.1 Department of Water Affairs (DWA) DWA develops, maintains and rehabilitates the bulk national water resource infrastructure to meet a basic social need and ensure economic growth. However, significant challenges remain in addressing the backlogs in maintenance, rehabilitation and refurbishment that impact on the operational efficiency of the national water resource infrastructure. In response to these problems, the department started a dam safety rehabilitation programme in 2005 to rehabilitate and refurbish 25 dams throughout the country. A similar programme has been started to rehabilitate the water conveyance infrastructure. Implementing the appropriate pricing structures for bulk raw water supply will ensure that water resources are used and managed in a sustainable and effective manner. Under the current pricing strategy, annual water tariffs increases are capped and exclude certain categories of users from paying cost-recovering tariffs. The longer term aim is to ensure that tariffs will be reflective of the costs of maintaining, rehabilitating and refurbishing water resource infrastructure. Greater emphasis will be placed on eradicating the licence backlogs to ensure that water is equitably distributed and managed effectively. In Table 7 the total expenditure of DWA for the last eight years are indicated, with an indication of the expenditure on infrastructure development in the department. The purpose 31 of this program is to ensure a reliable supply of water, with accessible risk, from bulk raw water resources infrastructure to meet demand for South Africa and to solicit and source funding to construct, operate and maintain bulk raw water resources infrastructure in an efficient and effective manner by strategically managing risks and assets. Table 7: Total expenditure of DWA on water infrastructure development Year DWA Total budget (ZAR) Total expenditure on infrastructure development (ZAR) % expenditure on infrastructure development 2006 385 190 000 85 250 000 22.1 2007 480 290 000 118 590 000 24.7 2008 579 530 000 164 430 000 28.4 2009 734 260 000 251 940 000 34.3 2010 702 370 000 213 240 000 30.4 2011 816 490 000 238 400 000 29.2 2012 864 150 000 225 150 000 26.1 2013 1 037 560 000 256 520 000 24.7 In 2009/10, DWA was restructured to focus its attention on its core functions of policy formulation, water resource management, infrastructure development, capacity building, intergovernmental and intra-sectoral coordination, and water regulation. As a result of the restructuring, the forestry function was moved to the Department of Agriculture, Forestry and Fisheries, while the sanitation function was moved to the Department of Human Settlements (and moved back to the Department of Water and Sanitation in 2014). The total expenditure increased from R3.9 billion in 2006/07 to R7.3 billion in 2009/10, at an average annual rate of 24 percent. This significant increase is driven by expenditure on the development of bulk water infrastructure. This includes funds allocated for the construction of new dams and ancillary infrastructure such as water treatment works and distribution pipelines, and the rehabilitation and repair of existing bulk infrastructure. Between 2006/07 and 2009/10, expenditure in the National Water Resources Infrastructure program increased at an average annual rate of 43.5 percent, from R852.5 million to R2.5 billion. This made it the fastest growing program within the department. Table 8: Major infrastructure projects with DWA Project name /implementing agent Project objective Total Project Cost (USD) Lesotho Highland Water Project Phase 11 To augment the Vaal river system (hydropower and water transfer) 750 000 000 Komati (TCTA) Water pipeline in Mpumalanga 170 000 000 Mokolo Crocodile water augmentation project (TCTA) Delivering of water in Limpopo province 150 000 000 32 Project name /implementing agent Project objective Total Project Cost (USD) Mkomazi water project Smithfield dam (KZN) Augment water supply to eThekwini , uMgungudlovo and surrounding areas 100 000 000 Lusiksiki regional water supply scheme: Zaludam on the Xura river To secure water supply for domestic and small scale irrigation in Lusiksiki and surrounding areas 500 000 000 Lower Orange River: Vioolsdrift dam To increase the yield of the Orange river to cater for the increasing demand in the area 560 100 000 Mooiriver –Welverdiend dam To secure water supply to domestic and industrial areas in the Lower Mvoti basin area (Stanger area) 100 000 000 Western Cape water supply: Voёlvlei supplement scheme Augment water supply to cape town and surrounding areas 500 000 000 Midvaal regulatory and sanitation Increase capacity of water waste treatment system in Gauteng 500 000 000 Koonap River- Foxwood Dam To secure water supply for domestic and small scale irrigation in Adelaide and surrounding districts (Eastern Cape) 40 000 000 Mzimvubu water resources development (KZN) Dam for hydro electricity and ensure water supply to northern parts of Lower KZN during dry periods and for irrigation 65 000 000 Olifants river resource development (Limpopo) Dam and bulk water distribution 16 100 000 000 Source: DWA, 2012 4.2 Department of Agriculture, Forestry and Fisheries (DAFF) Total expenditure increased from R3.6 billion in 2008/09 to R5 billion in 2011/12, at an average annual rate of 11.7 percent, and is projected to increase to R6.3 billion over the medium term, at an average annual rate of 8.4 percent (Table 9). The historical increase is due to funds transferred to the department from DWA and DEA for forestry and fishery in 2009/10 and 2010/11. Table 9: Expenditure trend of the DAFF (excluding the allocation for administration) Agric production, health & food security (USD) Food security and agrarian reform (USD) Trade promotion and market access (USD) Forestry (USD) Fisheries (USD) Total (USD) 2008 116 764 100 79 793 400 18 661 400 80 414 300 17 821 300 313 454 500 2009 102 923 000 90 061 900 18 521 800 86 158 700 20 004 100 224 969 500 2010 123 440 700 104 845 400 14 533 300 68 212 900 25 904 100 336 936 400 2011 168 975 700 125 394 000 20 539 800 89 535 000 34 553 200 358 397 700 2012 189 160 300 140 863 500 21 203 300 12 6177 500 41 179 100 518 583 700 2013 194 846 400 160 026 300 22 383 200 119 335 800 35 241 000 531 832 700 33 Moreover, the conditional grant allocation for the Comprehensive Agricultural Support Programme (CASP), Ilima/Letsema, and LandCare, mainly to support small scale and newly established farmers, increased from R1.4 billion in 2011/12 to R2.2 billion in 2014/15, at an average annual rate of 9.9 percent. Table 10 illustrates the percentage expenditure of the total expenditure on farmer support and agrarian reform, which varies between 25 and 30 percent of the total annual expenditure by the national Department of Agriculture. Table 10: Expenditure on farmer support program as percentage of total expenditure by DAFF Year 2008 2009 2010 2011 2012 2013 % expenditure of total expenditure 25.5 28.4 31.1 28.6 27.2 30.1 Provincial Departments of Agriculture like Limpopo and KwaZulu Natal (see Box 1 below) allocate a substantial percentage of the provincial budget for infrastructure development of small scale irrigation schemes in the respective provinces. Box !: KwaZulu-Natal Department of Agriciulture and Environmental Affairs expenditure trends The budget of the Department increased from R2.850 billion in 2013/14 to R3.241 billion in 2016/17, which is an annual average increase of 4.4 percent in nominal terms. The Department’s budget provides for the following agricultural activities:  Crop production: The Department will continue in its efforts to realise the potential of agricultural land through its mechanisation program, with the aim of ploughing and planting more than 20 000 ha. It will continue to ensure that its current mechanisation fleet will be optimally utilised and hence only replacement tractors and implements will be acquired. The Department will also continue with the liming program that commenced in 2011/12, with more than 4 000 ha to be limed in 2014/15.  Livestock development: The livestock intervention program is a long term program, focusing on primary animal health care and provision of basic infrastructure. In 2014/15, the focus will be on animal identification due to the increased number of incidents of stock theft and livestock wandering around causing accidents. Further activities will include provision of water (i.e. scooping of dams), drilling and equipping of boreholes, rehabilitation and building of new dip tanks, training of farmers and Livestock Associations, de-worming and vaccination of animals, livestock auction sales, etc.  Land reform: The Department will continue to provide post-settlement support to new farmers on commercial farms transferred to them. The transfer of Agri-business Development Agency (ADA) to the Department has been concluded and will result in a more effective and efficient coordination and implementation strategy. Key among ADA’s programmes is to develop and broaden access to the value chain to black commercial farmers, thereby integrating previously marginalised farmers into the main stream economy. In line with the agricultural policy to support the National Development Plan’s target of creating one million jobs in agriculture by 2030, over R7 billion will be spent on conditional grants to Provinces to support about 435 000 subsistence and 54 000 smallholder farmers and to improve agricultural extension services.  Food security: The Department will continue to support households through a range of food security interventions to alleviate food insecurity and grow the production capacity of farmers.  Transfers to Mjindi: (R12.286 million in 2013/14 financial year): The rehabilitation of the irrigation infrastructure will remain a major priority for Mjindi, ensuring that farmers receive an efficient 34 uninterrupted supply of water. This will enable the scheme to operate at optimal capacity and improve the quality of life for the farmers and the people of Umkhanyakude. This will also improve the Province’s food security.  Transfers to the ADA: The Agency’s 2014/15 strategic goals include improving agricultural productivity and competitiveness of previously disadvantaged commercial farmers, and increasing income and employment in commercial agriculture. The Agency will continue to focus on three sectors along the value chain, namely livestock development, sugar cane, and fruit and crop production. 4.3 Employment in agriculture The agriculture, forestry and fisheries sectors contributed 2.4 percent to GDP in 2010, a decrease from 2.9 percent in 2009. By contrast, the tertiary sector contributed 67.2 percent to GDP. In total, the agriculture, forestry and fisheries sector employed approximately 672 000 workers in 2013. Based on the annual average of the quarterly observations (to address seasonal fluctuations and limit the effect of the rolling sample base) employment in agriculture in 2008 was 657 000 people from where it decreased by 88 000 to reach 568 000 in 2011. From 2011 it increased slightly by 103 000 to reach 672 000 during 2013 (Figure 16). Figure 16: Employment trend 2008-2013 in agriculture The National Planning Commission believes that agriculture has the potential to create one million new jobs by 2030. This target is set in the context of the sector shedding almost one million jobs over the last three decades. The agriculture value chain is one of the priority sectors in government’s Industrial Policy Action Plan 2 for economic growth and job creation. With the implementation of agro-processing initiatives under this plan and plans to elevate agriculture to a priority sector in the new growth path, the department will attempt to reverse declining employment trends over the medium to long term. Resources will be 35 redirected to smallholder farmer support programmes, such as extension services, and farmer training and market access support. Important is that the expansion of employment should be supported by domestic and international markets. 5. Water allocation, pricing and investments Irrigation is the largest water user. Because of water scarcity, water use needs to be regulated in terms of a system of permissions and authorisations (RSA, 1998). 5.1 Water used for agriculture as per WMA There is a large variation in water requirements across the country due to the different water use sectors and their requirements with respect to quantity, quality, distribution in time and assurance of supply:  Rural requirements, mainly domestic use and stock watering.  Urban requirements, which include all water used in urban areas such as domestic, industrial, parks and communal.  Mining and bulk users, with the latter essentially representing large industrial users outside urban areas.  Power generation.  Irrigation for agricultural production.  Afforestation as a formally declared stream flow reduction activity.  Transfers of water out of a particular area, which constitutes a requirement for water from that area. Figure 17 displays the proportions of use of water withdrawals by sector in South Africa, showing that irrigation is by far the largest user (60 percent). 36 Figure 17: Relative use of water withdrawals per sector Source: DWA 2013a 5.2 Water allocation Due to water scarcity, there is a need to regulate the water usage to ensure sustainable, equitable and efficient utilization of the resource. The National Water Act distinguishes permissible use, General Authorisation, Existing Lawful Use (before 1998), and licensed water use (for water uptake after 1998). Equitable access to water, or the benefits derived from its use, is critical to the eradication of poverty and promoting economic growth. Equity means that everyone has fair opportunities to access, use and control of the water resources. The system of water allocations uses water pricing, limited term allocations and other administrative mechanisms to bring supply and requirements into balance in a manner which is beneficial in the public interest. (NWA, 1998). One of the fundamentals of water allocation is that any form of abstraction, transfer, storage or other influence on a natural stream gives effects in the entire downstream river system. The DWA is running a water allocation reform program, with objectives to ensure meaningful transformation in water use. The process of compulsory licensing is used to convert Existing Lawful Uses into licenses so that there is one single water law system. In this process, over- allocations or unused allocations are taken away in order to implement the Reserve and re- allocate water to achieve more equity. Compulsory licensing has been initiated in three catchments namely Tosca (Northern Cape), Jan Dissel (Western Cape), and Mhlathuze (KwaZulu-Natal) during 2012 (DWA, 2013a). 37 5.3 Water pricing and charges The Raw Water Pricing Strategy specifies the determination of the costs incurred to make water from a water resource available to users. The costs included in making water available to users include the following elements:  Cost of operation and maintenance (O&M) of publicly provided schemes.  Capital costs, comparing a return of paid-up assets, repayment of loans and, in some cases, contributions to fund a new scheme to make sure that this does not necessitate a sudden tariff increase.  Overheads such as the administration and support required to operate such schemes.  Allowance to provide for the depreciation, replacement of refurbishment of state owned infrastructure.  Catchment management costs.  Social and environmental costs. The Pricing Strategy, which relates to charges for any water use, is established in terms of the process described in section 56 of the Act. The full pricing strategy applies to the use of water described in section 21 of NWA, which includes taking water from a resource, discharging waste into the resource, storing water, and other uses such as the recreational use of water. It also addresses the setting of tariffs by DWA and water management institutions established in terms of the Act. It does not deal with treated water supplied in bulk by, for instance, water boards, and distributed to households via WSAs, as this is dealt with in the Water Services Act. All water use charges are specific to each of the four end-use sectors, namely:  Municipal (WSAs)  Industry, mining and energy  Agriculture  Stream flow reduction activities (currently forestry only) For irrigation, Table 11 provides an overview of the use per ha, and the total use of irrigation water. Water allocations per ha have been calculated according to the following:  In government water schemes, water user association schemes and irrigation board schemes: Water quotas in cubic metres per hectare have historically been determined and were as such taken up in every water use entitlement; and  For private irrigation outside of such schemes, the average annual crop water requirement of the likely crop mix in that specific area is determined with the South Africa Procedure for the estimating WATer requirements (SAPWAT), taking local conditions and climate into account. Table 11 also shows the irrigation tariffs (c/m3) in the 19 catchments initially envisaged as WMAs for the 19 CMAs. This highlights considerably variability. Tariffs depend on the 38 infrastructure involved, the cost of managing it, the socio-economic circumstances, and the demographic characteristics of each area. Commercial agriculture attracts the full charges, while the emerging farmers using government water schemes receive subsidized rates for five years at a progressively decreasing rate from inception of the subsidy on a specific scheme. Depreciation charges will be phased in over the sixth year. The price of water varies according to location and is calculated on a system, catchment or sub-catchment basis. It included O&M and capital costs. Table 11: Summary of irrigation water use per ha and cumulative in 19 catchments for 2002 Water management areas Weighted average irrigation allocation (m3/ha) Estimated irrigation water use (m3) Cost of irrigation water (c/m3) 1 Limpopo 7 725 168 602 202 1.1 2 Luvuvhu to Letaba 9 622 86 190 884 0.6 3 Crocodile west and Marico 6 977 147 858 418 4.0 4 Olifants 8 300 925 96 793 1.8 5 Incomati 10 064 359 810 260 1.5 6 Usutu to Mhlatuze 11 150 468 008 927 1.7 7 Thukela 7 700 137 126 990 0.9 8 Upper Vaal 7 211 455 888 149 1.8 9 Middle Vaal 6 762 180 540 943 2.8 10 Lower Vaal 9 111 77 983 239 4.5 11 Mvoti to Umzimkulu 4 600 71 706 660 3.3 12 Mzimvubu to Keiskamma 7 642 832 631 624 1.1 13 Upper Orange 9 975 384 614 358 2.4 14 Lower Orange 14 347 328 673 347 1.3 15 Fish to Tsitsikamma 11 651 305 340 806 3.4 16 Gourits 6 987 959 890 800 3.1 17 Olifants/Doring 12 000 959 918 774 2.8 18 Breede 7 223 372 918 774 6.9 19 Berg 7 467 126 921 070 4.3 Total 6 906 906 864 Source: Stats SA, 2010 The existing and future CMAs for each of the nine WMAs are responsible for management, including the setting of charges and the collection of revenue for water use in their jurisdiction. Water resource management charges are calculated on the basis of the actual costs of water resource management activities within the catchment per unit of water (m3) that is used. Charges are based on recovering the costs of managing the total volume of water that is allocated for use in each WMA. This is determined by deducting the requirement of the Reserve, water required used by downstream WMAs and by any specific water reserved for transfer via water works to neighbouring areas from the total volume of water available in the area. For billing purposes these unit charges will be added to the 39 annual water use charge. The water resources management charges are invoiced monthly according to a farm’s water allocation, regardless of the amount of water that was used during that specific time. Non-revenue water South Africa experiences the continuing problem of “non-revenue water”, or water that is lost before it is delivered to customers. Water losses currently stand at 36.8 percent. Physical leakages account for a total of 25.4 percent of all water losses with the balance stemming from theft or inaccurate metering. Non-revenue water stems mainly from practices such as poor planning, limited financial resources to implement the necessary programs, poor infrastructure asset maintenance and lack of capacity, but also the lack of proper auditing. An estimated 1.58 billion m3 of supplied water is unaccounted for each year in South Africa. At a nominal cost of R4.50 per m3, this represents a loss of more than R7 billion (USD 758 million). Agriculture, which accounts for 60 percent of all water withdrawals experiences estimated water losses of between 30 percent and 40 percent. Cutting of non-revenue water in municipalities receives considerable attention. 5.4 Investments in water resource infrastructure Water resource infrastructure is either financed by National Treasury or ‘off-budget’ through the TCTA. In addition, the Water Trading Entity (WTE) was established within DWA to promote the efficient management of bulk infrastructure. However the entity is currently facing severe technical, financial and management challenges, which are limiting its capacity to finance and manage the bulk water infrastructure efficiently (DWA Budget Review, 2012).