Does money grow on trees? : the role of climate change finance in South Africa.

Newmarch, Jocelyn

02 October 2013

Rapid, human-forced climate change as a result of greenhouse gases is threatening the fabric of human civilisation itself. It is clear that we need to alter our development and poorer countries will need to develop while limiting their emissions, but it is not clear what sustainable development would entail. Climate change policy solutions have pivoted on carbon trading, under the auspices of the Clean Development Mechanism (CDM), but this too has failed to limit growth in carbon emissions. This report looks at the operations of the CDM in South Africa as a source of climate finance meant to facilitate sustainable development. Though South Africa has emphasised its commitment towards a low-carbon transition, in practice its national planners seek to preserve energy-intensive mineral and industrial sectors. This research draws on both primary and secondary documents as well as interviews with carbon professionals to conclude that CDM projects have played a limited role in South Africa, but has tended to reproduce the existing minerals and energy complex within the country.

Carbon offsetting--South Africa.

Greenhouse gases--South Africa.

Carbon and water footprint for a soft drink manufacturer in South Africa

Wessels, Maria Magdalena

11 1900

The aim of this study was to determine a carbon and water footprint for a beverage manufacturing company. The carbon footprint etermination was conducted on Scope 1 and Scope 2. The water footprint was determined on the blue water and grey water. The beverage production volumes of the beverage manufacturing company were used to determine both the carbon and the water footprint. The theoretical background to this study was based on both local and international beverage companies and the outcome for the carbon and water footprint was benchmarked against the local and international companies. The objectives of this study were achieved by calculating a carbon and water footprint for the beverage company. The carbon footprint unit of measure is g CO2e / litre produced and the water footprint is litre water/litre produced. The unit of measure for pollutant grey water footprint is measured in milligram. Based on the results achieved in this study, commendations for carbon and water footprint reductions were made to the beverage company. Reduction targets for production year 2020 were also recommended based on the implementation of the reduction plans. / Environmental Sciences / M. Sc. (Environmental Management)

363.7387460968

Soft drink Industry – South Africa

Evaluating current energy management strategy : case study of an automotive manufacturer in the Eastern Cape

Mahlati, Andile

January 2012

Historically, the most frequently used energy sources have been those nearest and easiest to consume. Unfortunately, society’s reliance on fossil fuel for power generation has occurred at the expense of the environment, coal being a major contribution to carbon dioxide (CO2) emission. Carbon dioxide is classified as a greenhouse gas (GHG); it contributes to the phenomenon of climate change (Haw & Hughes, 2007, p.1). According to Worrell (2011), industry uses nearly 40 percent of worldwide energy on economic activities. Value chain activities alone contribute almost 37 percent to global GHG. Organisations are socially and ethically required to minimise the carbon footprint of their operations. Reducing energy use makes perfect business sense; it saves money, enhances corporate reputations and helps everyone participate the fight against climate change (Carbon Trust, 2011). Gielen, Newman, and Patel (2008) strongly believe the overall energy and emissions trends can be mitigated through additional energy efficiency measures. However, implementing EnMS will enable organisations to establish systematic approaches and the processes necessary to improve energy performance, including energy efficiency, use and consumption (SANS 50001, 2011). The objective of this paper was to evaluate the current energy management strategy adopted by selected automotive manufacture in Eastern Cape. The research was motivated by the fact that previous researchers have focused more on technological aspects and less of management functions. The research paradigm followed in this paper was qualitative because a case study is used to gain an insight and understanding about more and less successful energy management strategies. In this report, background about the global energy outlook and its significant to economic development, factors behind energy demands, the link to climate change and providing effective energy management principles are covered. The energy management principles covered key elements for delivering successful energy management. Literature highlighted that, senior management commitment is the foundation of good energy management, which is delivered through a formal energy policy and a supporting energy strategy with action plan. High level commitment will provide: Advocacy from senior managers; Visibility of the issues across your organization; Impetus for the organisation to implement energy management; Resources, both human and financial. It will also demonstrate that good energy management is part of your organisation’s mission and as relevant as other management aspects. The empirical study is focused on the characteristics of the current management system and organisational structure employed with its relevant functions. Based on these reference points the paper concludes with recommendations for the case study organisation.

Impacts of greenhouse gases from coal power stations on climatic trends in Witbank areas, South Africa

Mafamadi, Mercia Aluwani

18 May 2018

MESHWR / Department of Hydrology and Water Resources / Greenhouse gases (GHGs) from coal power station affect the behaviour of climatic parameters such as the temperature, rainfall and evaporation, over a long period of time, hence causing climatic trends. This study focused on investigating the impacts of Greenhouse gases (GHGs) from coal power stations on climatic and hydrological trends in Witbank area. To accomplish this, linear regression (LR) and Mann-Kendall (MK) trend test were used to detect the hydro-climatic trends and their significance. GHG emissions were obtained from Eskom’s sustainability report on the Eskom website. Temperature data for the years 1950- 2000 and 1993-2016 and rainfall data for the years 1925-2000 and 1993-2016 were used. Double Mass Analysis (DMA) was used to check the homogeneity and consistency of temperature and rainfall data from South African Weather Services (SAWS) station with the Lynch database and Water Research Commission (WRC) data. Data was patched and extended using LR where necessary. Trends in temperature, precipitation and flow were assessed using MK trend test and LR based on monthly, seasonal, and annual scales. GHG emissions were compared with the hydro-climatic data over time in order to detect the impacts of GHG emissions on temperature, rainfall and streamflow. The MK results indicated that GHG emissions had some impacts on temperature with statistically significant increase in annual, monthly and seasonal time scales for the period 1950-2016. LR also produced the same results for annual temperature. Monthly and seasonal temperature could not be produced with the LR method because of data gaps. The MK and LR models produced similar results, indicating that there was a non-significant increase in temperature before coal power stations were introduced (1950-1974) and a significant increase in temperature after the commissioning of coal power stations (1975-2016). MK and LR also produced the same results for annual rainfall data, indicating that there was a significant increase in rainfall before coal power stations were introduced (1925-1974) and a non-significant increase after the commissioning of coal power stations (1975-2016). For monthly time scales MK and LR indicated increasing and decreasing trends before and after coal power stations were introduced. MK and LR results for streamflow stations B2H004 and B2H007 showed similar results indicating non-significant increase in annual and seasonal streamflow, but differed in monthly streamflow where MK showed significant increases whilst LR showed non-significant trends. The study concluded that GHGs from coal power stations had significant impacts on the hydro-climatic trends in Witbank area. GHGs from coal power stations caused significant increase in temperature as temperature increased by 3.7°C after coal power stations were introduced, whereas temperature had increased by 1.7 °C. It is recommened that more research should be done on alternative sources of energy such as wind and solar energy to check their suitability and applicability in South Africa. / NRF

Impact

Greenhouse gases

Coal

Power station

Climatic

551.60968276

Gases -- South Africa -- Mpumalanga

Greenhouse -- Climate

Methane emissions assessment in South African coal mines and their potential utilizations

Maseko, Lucky Albert

27 September 2012

M.Sc.(Eng.), Faculty of Engineering and the Built Environment, University of the Witwatersrand, 2011

Coalbed methane--South Africa

Coal mines and mining--South Africa

Greenhouse gases--South Africa

Greenhouse gas mitigation--South Africa

Estimation of the emissions of gases from a two landfill sites using the LandGEM and Afvalzorg models: Case study of the Weltervenden (Polokwane) and Thohoyandou landfills

Njoku, Prince Obinna

21 September 2018

MENVSC / Department of Ecology and Resource Management / Over the years it has been observed that the solid waste sector has been an increasingly major contributor to the amount of Greenhouse gases (GHGs) in the atmosphere. To some extent a great chunk of these GHGs in the atmosphere is from Landfill gas (LFG). This study employs two theoretical models (LandGEM and Afvalzorg models) to estimate the amount of LFG emitted from Weltervenden and Thohoyandou landfill sites located in Limpopo province of South Africa. Furthermore, the study investigated the appropriate technique of the LFG utilisation as a source of electricity and the number of households using electricity. LFGcost model was used to estimate the cost and benefits related to the implementation of a LFG utilisation technology. Also, the possible health and environmental impacts of the landfill emissions on the people living closer to the landfill site were determined. The LandGEM model’s simulation concludes that CH4 and CO2 peaked in the year 2020 with values of 3.323 × 103 Mg/year and 9.118 × 103 Mg/year, respectively, for the Thohoyandou landfill. Results from the Afvalzorg model indicate that the CH4 peaked in the year 2020 with value of 3.501 × 103 Mg/year. Meanwhile the total emission of CH4 from 2005-2040 by the LandGEM and Afvalzorg models are 66200 Mg/year and 69768 Mg/year, respectively. However, for the Weltervenden landfill, the total LFG peaked in the year 2023 while the CH4 peak at 4061 Mg/year and 3128 Mg/year for LandGEM and Afvalzorg models, respectively. Furthermore, results from the cost analysis and benefits for the implementation of a LFG utilisation technology in both landfills show that the implementation of such a utilisation technology will be economically feasible considering the sale of t CO2 equivalent in the carbon market. However, without considering the sales of t CO2 equivalent, not all the LFG engines are economically feasible for both landfills. This study also shows that the residents living closer to the Thohoyandou landfill are at a higher risk of environmental pollution and could suffer negative impacts from the landfill than residents living far from the landfill site. However, the Weltervenden landfill did not have lots of communities living closer to the landfill and therefore it was not included in this study. / NRF

Estimation

Emissions

Gases

Landfill site

LandGEM

Afvalzorg

363.738740968257

Gases -- South Africa -- Limpopo

Waste gases -- South Africa -- Limpopo

Pollution -- South Africa -- Limpopo