(MENAFN- The Conversation) Access to clean water in the future is by no means certain for many regions in Africa. These include semi-arid regions like the Western Cape of South Africa, where droughts are predicted to , and wetter countries like Nigeria, where many water resources are . Population growth, industrialisation and pollution will also add to the problem for .
South Africa has recently experienced one of the worst droughts . In particular, the levels of dams in the Western Cape have been . The drought has had a bad effect on agriculture in the region which employs almost a quarter of the country's . Most of the shares this water scarcity.
Desalination has been proposed as one of many strategies to deal with the water shortages in the . are also building desalination plants.
Desalination involves removing salt from salty water, like sea water. In the process, a highly saline brine is produced which is discharged into the sea.
Desalination is sometimes said to be relatively compared to the building of dams or transfer schemes. But it's an expensive way of producing fresh water because it consumes a lot of . In addition, the brine put back into the sea can .
The world's main producers of desalinated water are in the Arabian Gulf region. In 2008 they were collectively producing about . Only about 1% of the world's population is dependent on desalinated water for the majority of their domestic use, but this is expected to increase to .
Other regional centres of production have emerged, such as the Mediterranean Sea and Red Sea and the coastal waters of . These are oil-rich or relatively wealthy countries which can afford the high energy cost of desalination. African countries are not as wealthy and have to consider the cost of desalination plants.
The challenges
There are two broad categories of desalination technologies.
The first large desalination plants to be built, mostly in the , are based on distillation technology. Here, salty water is heated until it evaporates and then condensed to produce fresh water. This technology requires a lot of energy.
Plants built more recently tend to use reverse osmosis technology. Here, salty water under high pressure is forced through a semi-permeable membrane. The salt stays behind while the water goes through. This is the most energy-efficient form of desalination technology, and most new plants outside the Middle East use .
The second process requires between 4 and 7 kilowatt hours of energy per cubic metre of water, depending on the technology used. A reverse osmosis plant with a capacity of 25,000 m3/day and energy demand of 5 kW h/m3 consumes about 125,000 kW h/day of energy. This plant could supply around 48 000 four-person homes with water. The energy used in desalination could supply about 10 300 of the same households .
The type of energy used is a problem too. Running plants on fossil fuels , which contributes to climate change.
Desalination plants can be harmful to the , particularly marine life.
Pipes used to suck water in to the plants can kill marine life and disturb sediments. And the saline brine released into the ocean tends to sink to the bottom layers of the ocean as this water is heavier. There, it kills species that aren't adapted to such saline conditions.
The brine is also relatively hot, leading to further environmental damage, as certain fragile marine ecosystems, particularly coral reefs, are sensitive to temperature. Chemicals and toxic metals that may be produced and added to the brine before and after treatment are another threat to environments.
Mitigating the risks
The environmental impact of desalination plants must be assessed before they are built. Cape Town is going to speed up the environmental assessment associated with a planned .
If possible, lightly salty groundwater should be used instead of sea water. This would use less energy and produce less brine. Where possible, desalination plants should use renewable energy.
Still, there's a case to be made that desalination is energy-expensive and environmentally harmful. A better course of action would therefore be to manage water resources more efficiently. This means reducing water losses and water demand and reusing waste water. But these problems are complex and require long-term planning and large infrastructure investments. Desalination in contrast allows the immediate need for an additional source of water to be satisfied.
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