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− | [[Image:Havasu Falls 1a md.jpg|right|180px]]With world population growing, demand for food (and hence {{wp|Virtual_water#Agricultural_products|water for farming}}) expected to grow by 70% <sup>[http://www.fao.org/news/story/en/item/35571/icode/]</sup>, rivers becoming polluted and one in eight people already without clean drinking water <sup>[http://water.org/learn-about-the-water-crisis/facts/]</sup>, some have warned that we are heading for a 'peak water' crisis with people lacking the necessary water to survive, and wars breaking out over the access to water supplies <sup>[http://www.timesonline.co.uk/tol/news/environment/article5562906.ece]</sup>.
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− | A grim picture, indeed. But fortunately, an entirely avoidable one. Water is one of the most abundant resources available to us on this blue planet. The only problem we may face is synthetic [[scarcity]]; this article aims to show that there is no real shortage of water, nor of techniques to purify and manage it. If we simply apply the water-management techniques {{em}} many of which are extremely simply, low-tech, low-cost things {{em}} we have all the water we could ever need.
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− | <includeonly>{{more|Fundamental resources/Water}}</includeonly>
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− | <noinclude>
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− | === Abundance of water ===
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− | [[Image:Pacific Ocean surface.jpg|180px|right|Pacific ocean]]Over 70% of the surface of the Earth is covered by water, with the average depth of the oceans being 3.8 kilometres (12,430 ft) {{en}} we live on what is primarily a water world. Wasting the fresh water that falls on the surface of the land should of course be avoided wherever possible, but having enough fresh water in any place ultimately comes down to energy, rather than water itself {{em}} energy to transport water and energy to purify it.
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− | ===The vast potential of rainwater harvesting===
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− | There is a very obvious solution to the 'water crisis' - we should use the distilled water that falls on our homes instead of diverting it into gutters. This way, water need not be pumped across long distances, which saves the energy needed to transport it and the considerable losses to leaks, which are often 30% or more.
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− | In just about any climate, all the water you need falls on your roof. Suppose you live in a climate that has only 35cm of rainfall per year (which would be classed as a semi-arid climate) and your house is small, with a footprint of 100m<sup>2</sup>. These are adverse conditions for rainwater harvesting, but such a house would still catch 35,000 liters of water a year, 95 liters a day, which is plenty to cover all domestic use.
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− | [[Image:UV_LED.jpg|right|thumb|182px|UV light is a clean and effective way to kill water-borne pathogens and requires no chemicals, only about 15W of electricity. As [[LEDs]] get cheaper and more energy-efficient, the use of UV-emitting LEDs to sterilize water becomes more and more attractive.]]If a {{wp|Slow_sand_filter|slow sand filter}} or something similar is used, rainwater can be filtered without an input of energy or of chemicals. This purifies it to a standard suitable for cooking, cleaning, showers, toilets - all purposes except for drinking. Less than 2 liters of drinking water a day is required, and this purification can be done in several cheap ways, including by concentrated sunlight, or cheap ultraviolet LEDs. Using these methods, rainwater catchment and purification can then be done at very little cost.
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− | Nanofilters are another effective way of filtering out both suspended particles (which cause unpleasant tastes, smells and discoloration) and pathogens. The Tata Swach is a device that uses nanofilters to give very pure water. It retails for only $21.
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− | Decentralizing water-production in this way would eliminate the need for a complicated water-grid and would make people more independent and resilient in the case of [[disasters]].
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− | ===Desalination===
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− | The vast majority of mankind's water needs can be met by rainwater catchment. In those few climates where there is not enough rain to meet water demand (such as North Africa and the Middle East) we can create the most vital of human requirements - fresh water - from the most abundant of resources - seawater.
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− | 97.5% of Spaceship Earth's water is in its oceans. Though warnings of water shortages invariably dismiss desalination <i>a priori</i> as too expensive or energy-intensive <sup>[http://www.gdrc.org/uem/water/urban-water.html][http://www.reuters.com/article/idUSL1834918020070619][http://www.merinews.com/article/water-crisis-a-glaring-problem/15765583.shtml]</sup>, this is only a valid argument if the energy supply is limited. As long as we have large amounts of renewable energy at our disposal (which we do - see the [[#Energy|energy section]]), we can always create fresh water as required from seawater. Abundant energy means abundant fresh water. Happily, the areas most in need of desalination plants tend to be extremely sunny regions: North Africa, the Middle East, Australia, Mexico etc. These regions are extremely well-suited to solar power and desalination plants set up here could readily power themselves with a few fields of photovoltaic panels.
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− | Moreover, though desalination does require a lot of energy, this requirement is steadily falling as technology improves. Currently large-scale desalination generally uses {{wp|Reverse_osmosis|reverse osmosis}}, where seawater is forced under pressure through a membrane. The benchmark amount of energy required for this process is 3.5 kilowatt hours per cubic meter of water <sup>[http://www.nwc.gov.au/resources/documents/Waterlines_-_Trends_in_Desalination_-_REPLACE_%282%29.pdf p.10]</sup>. There are several promising technologies which are expected to bring this requirement to 1kWh/m<sup>3</sup> or below within the next decade {{em}}
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− | * '''[http://www.businessweek.com/magazine/content/11_12/b4220041560310.htm Forward osmosis]''' {{em}} Forward osmosis pre-treats seawater using a solution to draw some of the salt out of it. This partially desalted water requires less energy to desalinate using a membrane filter. The inventor, Robert McGinnis, has calculated the energy requirements at 0.24 kWh/m<sup>3</sup> <sup>[http://www.yale.edu/env/elimelech/Research_Page/desalination/desalination_presentation3.pdf (p. 18)]</sup>
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− | * '''Nanofiltration''' is an advanced form of reverse osmosis using filters made of [[carbon nanotubes]], which are big enough to let water molecules pass though, but small enough to filter out salt particles, impurities and pathogens. Nanofiltration uses only a quarter the energy of conventional methods of desalination<sup>[http://www.technologyreview.com/read_article.aspx?ch=nanotech&sc=&id=16977&pg=1]</sup>. IBM are conducting research into nanofiltration-based desalination <sup>[http://www.inhabitat.com/2010/04/07/ibm-saudi-researchers-team-up-on-solar-powered-desalination-technology/]</sup>.
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− | * '''{{wp|Solar_humidification|Solar desalination}}''' is a simple and ancient method of desalination that uses no electricity at all, just the heat of the sun to evaporate seawater, which separates the salt from the water. It is only feasible in very hot countries, but these tend to be the ones most in need of water.
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− | * The above technologies could decrease the amount of energy needed for desalination from 3.5kWh/m<sup>3</sup> to less than 1kWh/m<sup>3</sup>. This would be enough to revolutionize the world water system, but there is an even more radical solution which proposes to use no energy at all to desalinate water, but to actually ''generate'' electricity from a desalination process. '''Microbial desalination cells''' use [[Energy#Bacteria|electrically active microbes]] to suck sodium and chlorine ions out of the water, simultaneously desalinating water and generating a flow of electrons. A [http://www.sciencedirect.com/science/article/pii/S0960852410010114 paper] published in July 2010 reported that a microbial desalination cell ran successfully for 4 months, removing 99% of salt from water and constantly generating electricity.
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− | ===Atmospheric water generators===
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− | {{wp|Atmospheric_water_generator|Atmospheric water generators}} condense water from the air. This water is clean and ready to drink. It is interesting to note that even very dry air contains about 5ml water per cubic meter of air, so even in a desert, you could condense enough water from the air to sustain a person or to grow food.
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− | An interesting [http://sculptors.com/~salsbury/Articles/atmospheric-condensing.html article] by Patrick G. Salsbury analyses the enormous potential of atmospheric water generators to help meet humanity's water needs. He calculates that a device smaller than a microwave oven (using a crude prototype design and a very conservative estimate) provides 110l of clean water a day. [http://www.aquasciences.com/ Aqua Sciences] have a condensor the size of a truck trailer that makes up to 4500l a day - enough for 90 people.
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− | ===Microbial wastewater treatment===
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− | [[Energy#Bacteria|Microbial fuel cells]] can be fitted to sewage water treatment facilities to generate electricity. One investigation found that the organic impurities in sewage contain 9.3 times as much energy as is needed to treat the water<sup>[http://scitation.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=JLEED9000130000002000045000001&idtype=cvips&gifs=yes&ref=no]</sup>. It should be possible to integrate microbial energy-harvesting systems with water treatment facilities to create a self-sustaining facility that creates both clean water and clean electricity.
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− | === Using less domestic water ===
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− | In the USA in 2006, the average water use per person per day was 575 litres. Compare this with 149 litres in the UK and 4 litres in Mozambique. 50 litres of water is sufficient for a person<sup>[http://en.wikipedia.org/wiki/Water_resources#Uses_of_fresh_water][http://www.youtube.com/watch?v=t1DfNlxlk-A#t=3m44s]</sup>, without requiring sacrifices in lifestyle, just by improving system design. As shown above, even the higher figures can be met by rainwater.
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− | {{wp|Greywater|Greywater}} is the run-off from showers, sinks etc. It is water that has been used, but is not so dirty it cannot be used for purposes like gardening or washing clothes. Houses can be fitted with greywater recycling systems, where, for example, the output of the shower becomes the input of the dishwasher. This significantly reduces the amount of water needed to run a home.
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− | Using composting toilets rather than flush toilets would save 26.7%<sup>[http://www.epa.gov/watersense/pubs/indoor.html]</sup> of water use in the home. Composting toilets are also a source of fertilizer for growing food - and electrodes could even harvest electricity from the bacteria they contain (see [[Fundamental resources/Energy|Energy]]).
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− | With the concern about conserving water in recent years, designers have developed toilets, sinks, dishwashers and washing machines that use a fraction of the water used by conventional designs.
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− | However, reducing the domestic use of water is only a small part of the puzzle. Agriculture is the main cause of water use {{em}}
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− | {{frame1|Water-efficient agriculture}}
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, rivers becoming polluted and one in eight people already without clean drinking water
, some have warned that we are heading for a 'peak water' crisis with people lacking the necessary water to survive, and wars breaking out over the access to water supplies
. Already, about half of all infectious disease is caused by contaminated drinking water.
A grim picture, indeed. But fortunately, an entirely avoidable one. Water is one of the most abundant resources available to us on this blue planet. The only problem we may face is synthetic scarcity; this article aims to show that there is no real shortage of water, nor of techniques to purify and manage it. If we simply apply the water-management techniques — many of which are extremely simple, low-tech, low-cost things — we have all the water we could ever need.