Assessing the energy and carbon footprints of exploiting and treating brackish groundwater in Cape Town

Gobin, Aumashvini; Sparks, Debbie; Okedi, J.; Armitage, Neil; Ahjum, Fadiel

doi:10.4314/wsa.v45i1.08

Cited by 9 publications

(11 citation statements)

References 13 publications

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“…Despite the constitutional mandate requiring that key actors, such as government departments, local communities, industry, experts and researchers, are consulted to ensure meaningful, well-informed and effective policy instruments within the water, energy and climate change sectors, application of the PA appears to be lacking. The prevailing lack of coordinated and integrated approaches in the widely touted sectoral policies [12,13,11,3] demonstrates limited application of the PA in planning and implementation processes. These shortcomings suggest a lack of understanding of the interlinkages between the key socio-economic and environmental processes in the WECC nexus.…”

Section: Participatory Approach In the Management Of The Wecc Nexusmentioning

confidence: 99%

“…As is the case globally, South Africa lacks integrated approaches for the management of different nexus configurations such as WECC [10,11,12]. This is as demonstrated by the preponderance of fragmented approaches in the planning and development of policies and strategies for addressing growing water, energy, and climate change challenges in the country [13,3]. This observation, coupled with a lack of urgency to implement mitigation measures as proposed by different scientists in the country, suggests that there is limited coordination and collaboration among key stakeholders such as researchers, policymakers and communities.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Towards improved Water-Energy-Climate Change nexus assessment in South Africa: A Participatory Approach

Mathetsa¹,

Simatele²,

Rampedi³

2021

Preprint

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This paper discusses the use of a participatory approach to assess the level of understanding of the Water-Energy-Climate Change nexus in South Africa. The aim is to facilitate the development of well-coordinated, systematic, and holistic strategies for efficient management of the nexus and its implications in the country. The assessment was guided by the broader Integrated Water Resource Management framework, which promotes a participatory approach in the administration of water resources. The paper argues that despite the reasonable level of understanding of WECC, there is still a lack of integrated policy development and planning among key stakeholders. This is exacerbated by limited coordination and consultation among these stakeholders, particularly policymakers. This necessitates the urgent adoption of holistic and systems thinking approaches, and the promotion of collaboration among different stakeholders mandated to manage WECC sectors. Until such approaches are adopted, the WECC nexus will continue to impede the country’s socio-economic development and environmental wellbeing.

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Section: Participatory Approach In the Management Of The Wecc Nexusmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Towards improved Water-Energy-Climate Change nexus assessment in South Africa: A Participatory Approach

Mathetsa¹,

Simatele²,

Rampedi³

2021

Preprint

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“…Tanzania [25] A life cycle assessment of desalination and mine-water reclamation as alternatives for portable water supply. South Africa [58] Assessed the energy and carbon footprints of using centralized, decentralized or desalination options in treating brackish groundwater, Cape Town.…”

Section: Reference Description Countrymentioning

confidence: 99%

Applying the Water-Energy Nexus for Water Supply—A Diagnostic Review on Energy Use for Water Provision in Africa

Macharia¹,

Kreuzinger²,

Kitaka

2020

Water

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This work explores the application of the Water-Energy Nexus concept for water supply in the African context, where its operationalization is quite limited compared to developed regions. Furthermore, water supply and demand drivers and their influence on energy use are examined. This study found that there is limited literature available on the operationalization of the concept, and energy use is not considered a key performance indicator by water regulators and utilities. Regionally, most of the studies were carried out in the northern and southern Africa, where energy demand for water supply through desalination is high. An analysis of water supply and demand drivers show diminishing quantities of available freshwater, and increased anthropogenic pollutant loads in some areas are projected. Consequently, utilities will likely consider alternative energy-intensive water supply options. Increased population growth with the highest global urban growth rate is projected, with about 60% of the total population in Africa as urban dwellers by 2050. This implies huge growth in water demand that calls for investment in technology, infrastructure, and improved understanding of energy use and optimization, as the largest controllable input within utilities boundaries. However, it requires a data-driven understanding of the operational drivers for water supply and incorporation of energy assessment metrics to inform water-energy policies and to exploit the nexus opportunities.

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“…Meanwhile, the utility of chemicals consisting of Polyaluminium chloride, Polyacrylamide, Soda ash, Hydrochloric acid, Sodium hydroxide, Chlorine, Sodium hydrogen sul te, Sodium hypochlorite and Calcium carbonate contributed a total of 0.146 kg CO 2 -eq (4%). According to Gobin et al (2019), the quantity of chemicals will be higher when the productivity of potable water production is higher. For example, the use of lime, uoride, and carbon dioxide to reduce water hardness and produce good quality water can contribute to the carbon footprint.…”

Section: C0 2-eq Emissions In the Operation Processmentioning

confidence: 99%

“…Data loss and lack of information that are related to materials disposal, construction of plant infrastructure, tanks and transportation services are the most di cult issue to model the indirect carbon footprint emission. According to Gobin et al (2019), limited data accessibility such as chemicals and energy via data extraction using different models such as GaBi, West is the major limitation in the research of carbon footprint desalination in Cape Town, Africa. Therefore, further research needs to be done with the involvement of sensitivity analysis towards the construction, operation and dismantling phases.…”

Section: Relationship Between Limitations Strategies and Adaptionmentioning

confidence: 99%

Potential Reduction of Carbon Burden for Senak Seawater Desalination Plant in Malaysia

Ghani

Nazaran

Ali

et al. 2020

Preprint

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PurposeCarbon footprint calculation is one of the approaches available in the Life Cycle Assessment (LCA) system, which can be considered as a decision support tool for environmental sustainability management. Hence, this purpose of this study is to examine the potential contribution of the product, namely water through carbon footprint measurement. Seawater has been selected as the source for clean water transformation in Senak due to its ability to meet the growing demands of the local population and its ability to be recycled in the long term.MethodsIn this study, carbon footprint assessment was used to investigate seawater production systems from a desalination plant in Senok, Kelantan, Malaysia. Three stages of the desalination plant processing system have been investigated and the inventory database has been developed using the relevant model framework. The LCA method, in accordance with ISO14040-43 guidelines has been simplified with working unit selected is 1 per cubic meter of treated water produced from a salt water desalination source.Results and discussionOverall, the results of the study indicate that the Revolutionary Osmotic (RO) technology that has been used in the desalination plant in the study area is one of the best options to meet the demands of the environmental sustainability agenda (SDGs). This is due to a lower carbon dioxide (CO2) emission of about 3.5 × 10−2 kg of CO2 eq per m3/year that has been recorded for the entire operation of the system. The other pollutants involved the emission of NOx and Sox, which were considered to be insignificant. However, if the plant continues to operate completely on fossil fuel for the next 25 years, the emission is expected to affect the health of the community.ConclusionsSeveral factors that influence important errors in carbon footprint decisions such as the lack of EIA reporting data and the literature on carbon footprint in the Malaysian scenario. The total dependency of electrical source for SWRO process of fossil fuel is the most critical factor in the carbon footprint issue in this study. These findings can be used to develop a carbon footprint model that can commercialise carbon tax, carbon economy capital, energy security assurance, and standard carbon regulation and legislation in the context of local desalination projects.

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Assessing the energy and carbon footprints of exploiting and treating brackish groundwater in Cape Town

Cited by 9 publications

References 13 publications

Towards improved Water-Energy-Climate Change nexus assessment in South Africa: A Participatory Approach

Towards improved Water-Energy-Climate Change nexus assessment in South Africa: A Participatory Approach

Applying the Water-Energy Nexus for Water Supply—A Diagnostic Review on Energy Use for Water Provision in Africa

Potential Reduction of Carbon Burden for Senak Seawater Desalination Plant in Malaysia

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