Air well (condenser)

High-mass air well of Belgian engineer Achile Knapen in Trans-en-Provence.

A 550 square metres (660 sq yd) radiative condenser in northwest India.^[1]

An air well or aerial well is a structure or device that collects water by promoting the condensation of moisture from air.^[2] Designs for air wells are many and varied, but the simplest designs are completely passive, require no external energy source and have few, if any, moving parts. A related, but quite distinct, technique of obtaining atmospheric moisture is the fog fence. An air well should not be confused with a dew pond. A dew pond is an artificial pond intended for watering livestock. The name dew pond (sometimes cloud pond or mist pond) derives from the widely held belief that the pond was filled by moisture from the air.^[3] In fact, dew ponds are primarily filled by rainwater.^[4]

All air well designs utilise a substrate with a temperature sufficiently low so that dew forms. This condensation releases latent heat which must be dissipated. Cooling of the substrate is typically achieved by radiating heat to the sky, during periods of cool breezes (particularly at night), or by conduction to some other heat sink.

Three principal designs are used for air wells: high mass, radiative and active. High-mass air wells were used in the early 20th century, but the approach failed. From the late 20th century, onwards, low-mass, radiative collectors proved to be much more successful. Thirdly, active collectors collect water in the same way as a dehumidifier, although the designs work well, they require an energy source making them uneconomical except in special circumstances. New, innovative designs seek to minimise the energy requirements of active condensers or make use of renewable energy resources.

Moisture

Global mean atmospheric water vapor.

An air well requires moisture from the air; and everywhere on Earth, even in the hottest climates, the surrounding atmosphere contains at least some water. According Beysens and Milimouk: "The atmosphere contains 12,900 km³ (3,000 cubic miles) of fresh water, composed of 98% water vapour and 2% condensed water (clouds): a figure comparable to the renewable liquid water resources of inhabited lands (12,500 km³)."^[5] The quantity of water vapour contained within the air is commonly reported as a relative humidity; and this depends on temperature – warmer air can contain more water vapour than cooler air. When air is cooled to the dew point it becomes saturated and moisture will condense on a suitable surface.^[6] For instance, the dew temperature of air at 20 °C (68 °F) and 80% relative humidity is 18 °C (64 °F). The dew temperature falls to 10 °C (50 °F) if the relative humidity is only 25%.^[5]

An effective air well must provide a substrate at a temperature that is sufficiently low to allow dew to form upon its surface. Dew is a form of precipitation that occurs naturally when atmospheric water vapour condenses onto a substrate. It is distinct from fog, in that fog is made of droplets of water that condense around particles in the air.^[5] Condensation of the dew releases latent heat which must be dissipated in order for water collection to continue.^[7] The substrate must be cooled; this is typically achieved by radiating heat to the sky, by periods of cool breezes (particularly at night) or by conduction to some other heat sink.

A stone mulch can significantly increase crop yields in arid areas. This is most notably the case in the Canary Islands: on the island of Lanzarote there is about 140 millimetres (5.5 in) of rain each year and there are no permanent rivers. Despite this, substantial crops can be grown by using a mulch of volcanic stones, a trick discovered after volcanic eruptions in 1730. Some credit the stone mulch with promoting dew; although the idea has inspired some thinkers, it seems unlikely that the effect is significant. Rather, plants are able to absorb dew directly from their leaves, and the main benefit of a stone mulch is to reduce water loss from the soil and to eliminate competition from weeds.^[8]

Heat sinks

There are three principal approaches to the design of the heat sinks that collect the moisture in the air wells: high mass, radiative and active. Early in the twentieth century, there was interest in high-mass air wells, but despite much experimentation including the construction of massive structures, this approach proved to be a failure.^[9]

From the late twentieth century onwards, there has been much investigation of low-mass, radiative collectors; these have proved to be much more successful. Also, since the invention of refrigeration systems there has been interest in active collectors that collect water in the same way as a dehumidifier; although these designs work well, they require an energy source which makes them uneconomical except in special circumstances.

Newer, innovative designs seek to minimise the energy requirements of active condensers or make use of renewable energy resources.

High-mass collectors

A number of inventors experimented with high-mass collectors. Notable investigators were the Russian engineer Friedrich Zibold (sometimes given as Friedrich Siebold),^[10] the French bioclimatologist Leon Chaptal, the German-Australian researcher Wolf Klaphake and the Belgian inventor Achille Knapen.

A section through Zibold's dew condenser. (a) is a truncated cone of beach pebbles 20 metres (66 ft) in diameter at the base and 8 metres (26 ft) in diameter at the top. (b) is a concrete bowl; a pipe (not shown) leads away from the base of the bowl to a collecting point. (c) is ground level and (d) is the natural limestone base.^[11]

Zibold’s collector

In 1900, near the site of the ancient Byzantine city of Theodosia, thirteen large piles of stones were discovered by Zibold who was a forester and engineer in charge of this area.^[12] Each stone pile covered just over 900 square metres (9,700 sq ft) and was about 10 metres (33 ft) tall. The finds were associated with the remains of 75 millimetres (3.0 in) diameter terracotta pipes that apparently led to wells and fountains in the city. Zibold concluded that the stacks of stone were condensers that supplied Theodosia with water; and calculated that each air well produced more than 55,400 litres (12,200 imp gal; 14,600 US gal) each day.^[10]

To verify his hypothesis Zibold constructed a stone-pile condenser at an altitude of 288 metres (945 ft) on Mt. Tepe-Oba near the ancient site of Theodosia. Zibold’s condenser was surrounded by a wall 1 metre (3 ft 3 in) high, 20 metres (66 ft) wide, around a bowl-shaped collection area with drainage. He used sea stones 10–40 centimetres (3.9–16 in) in diameter piled 6 metres (20 ft) high in a truncated cone that was 8 metres (26 ft) in diameter across the top. The shape of the stone pile allowed a good air flow with only minimal thermal contact between the stones.^[13]

Zibold's condenser began to operate in 1912 with a maximum daily production that was later estimated to have been 360 litres (79 imp gal; 95 US gal) – Zibold made no public record of his results at the time.^[10] The base developed leaks that forced the experiment to end in 1915 and the site was partially dismantled before being abandoned. (The site was rediscovered in 1993 and cleaned up.)^[13] Zibold's condenser was of approximately the same size as the ancient stone piles that had been found and although the yield was very much less than the yield Zibold had calculated for the original structures, the experiment was an inspiration for later developers.

Chaptal’s collector

Inspired by Zibold's work, Chaptal built a small air well near Montpellier in 1929. Chaptal's condenser was a pyramidal concrete structure 3 metres (9.8 ft) square and 2.5 metres (8 ft 2 in) high, it was filled with 8 cubic metres (280 cu ft) of limestone pieces being about 7.5 centimetres (3.0 in) in diameter. Small vent holes ringed the top and bottom of the pyramid. These holes could be closed or opened as required to control the flow of air. The structure was allowed to cool during the night and then warm moist air was let in during the day. Dew formed on the limestone pieces and collected in a reservoir below ground level. The amount of water obtained varied from 1 litre (0.22 imp gal; 0.26 US gal) to 2.5 litres (0.55 imp gal; 0.66 US gal) per day depending on the atmospheric conditions.^[13][14]

Chaptal did not consider his experiment a success. When he retired in 1946, he put the condenser out of order, possibly because he did not want to leave an improper installation to mislead those who might later continue studies on air wells.^[15]

Klaphake’s collectors

Klaphake was a successful chemist working in Berlin during the 1920s and 30s. During that time, he tested several forms of air wells in Yugoslavia and on Vis Island in the Adriatic Sea. Klaphake's work was inspired by the works of Maimonides, a known Jewish scholar who wrote in Arabic about 1,000 years ago and who mentioned the use of water condensers in Palestine.

Klaphake experimented with a very simple design: an area of mountain slope was cleared and smoothed with a watertight surface with a simple canopy supported by pillars or ridges. The sides of the structure were closed, but the top and bottom edges were left open. At nights, the mountain slope would cool and in the day moisture would collect on and run down the smoothed surface. Although the system apparently worked, it was expensive and Klaphake finally adopted a more compact design based on a masonry structure. This design was a sugarloaf-shaped building, about 15 metres (49 ft) high, with walls at least 2 metres (6 ft 7 in) thick, with holes on the top and at the bottom. The outer wall is made of concrete to give a high thermal capacity and the inner surface was made of a porous material such as sandstone.^[16] According to Klaphake:

“

The building produces water during the day and cools itself during the night; when the sun rises, the warm air is drawn through the upper holes into the building by the out-flowing cooler air, becomes cooled on the cold surface, deposits its water, which then oozes down and is collected somewhere underneath. It is wrong to think that this process works only on days with dew, as the inner surface becomes much cooler than one should expect. In Dalmatia, that day was a rare exception which failed to produce water.[17]

”

Traces of Klaphake's condensers have been tentatively identified.^[18]

In 1935, Wolf Klaphake and his wife Maria emigrated to Australia. The Klaphakes' decision to emigrate was probably primarily the result of Maria's encounters with Nazi authorities;^[19][20] their decision to settle in Australia (rather than, say, in Britain) was influenced by Wolf's desire to develop a dew condenser.^[20] As a dry continent, Australia was likely to need alternative sources of fresh water and the Premier of South Australia, whom he had met in London, had expressed an interest. Klaphake made a specific proposal for a condenser at the small town of Cook where there was no supply of potable water. At Cook, the railway company had previously installed a large coal-powered active condenser,^[21] but it was prohibitively expensive to run, and it was cheaper to simply transport water. However, the Australian government turned down Klaphake's proposal and he lost interest in the project.^[22][23]

Knapen’s ariel well

Achille Knapen air well (exterior)

Achille Knapen air well (interior)

Knapen, who had previously worked on systems for removing damp from buildings,^[24][25][26] was in turn inspired by Chaptal's work and he set about building an ambitiously large puits aerien (aerial well) on a 180 metres (590 ft) high hill at Trans-en-Provence in France.^[2][27] Beginning in 1930, Knapen's dew tower took 18 months to build; it still stands today, albeit in dilapidated condition. At the time of its construction, the condenser excited some public interest.

The tower is 14 metres (46 ft) high and has massive masonry walls about 3 metres (9.8 ft) thick with a number of apertures to let in air. Inside there is a massive column made of concrete. At night, the whole structure is allowed to cool, and during the day warm moist air enters the structure via the high apertures, cools, descends, and leaves the building by the lower apertures.^[28] Knapen’s intention was that water should condense on the cool inner column. In keeping with Chaptal’s finding that the condensing surface must be rough and the surface tension must be sufficiently low that the condensed water can drip, the central column's outer surface was studded with projecting plates of slate. The slates were placed nearly vertically to encourage dripping down to a collecting basin at the bottom of the structure.^[13] Unfortunately, the aerial well never achieved anything like its hoped-for performance and produced no more than a few litres of water each day.

Conclusions

None of the high-mass collectors performed well, and Knapen's aerial well was a particularly conspicuous failure. Although ancient air wells are frequently mentioned in sources, there is scant evidence for them and persistent belief in their existence has the character of a modern myth.^[15]

Zibold's collector apparently performed reasonably well, but in fact his exact results are not at all clear and it is possible that the collector was intecepting fog which added significantly to the yield.^[10] Furthermore, it is now apparent that the mounds that Zibold identified as dew condensers were ancient burial mounds (a part of the necropolis of antic Theodosia) and that the pipes were medieval in origin and not associated with the mounds. If Zibold's condenser worked at all this was probably due to fact that a few stones near the surface of the mound were able to lose heat at night while being thermally isolated from the ground; however, it could never have produced the yield that Zibold envisaged.^[15][29]

The problem with the high-mass collectors was that they could not get rid of sufficient heat during the night – despite design features intended to ensure that this would happen.^[13] While some thinkers have occasionally been persuaded that Zibold might have been on the right track after all,^[30][31] the reasoning of an article in Journal of Arid Environments makes it clear that high-mass condenser designs of this type are doomed to failure:

“

We would like to stress the following point. To obtain condensation, the condenser temperature of the stones must be lower than the dew point temperature. When there is no fog, the dew point temperature is always lower than the air temperature. Meteorological data shows that the dew point temperature (an indicator of the water content of the air) does not change appreciably when the weather is stable. Thus wind, which ultimately imposes air temperature to the condenser, cannot cool the condenser to ensure its functioning. Another cooling phenomenon—radiative cooling—must operate. It is therefore at night-time, when the condenser cools by radiation, that liquid water can be extracted from air. It is very rare that the dew point temperature would increase significantly so as to exceed the stone temperature inside the stone heap. Occasionally, when this does happen, dew can be abundant during a short period of time. This is why subsequent attempts by L. Chaptal and A. Knapen to build massive dew condensers only rarely resulted in significant yields. [Emphasis as in original][15]

”

In retrospect, it may be seen as unfortunate that Zibold's pioneering work inspired so much fruitless effort. However, Zibold's legacy would inspire one more group of people, a party of academics who would go on to form the International Organization For Dew Utilization and, taking a quite different approach, they designed successful condensers.

Radiative collectors

Diagram of a radiative condenser, a device designed to collect dew. (a) radiating/condensing surface, (b) collecting gutter, (c) backing insulation, (d) stand.

Structures with metal roofing, such as this one, can be used to harvest dew water simply by adding gutters and, for increased output, a layer of insulation underside. Without the insulation the output is nearly half of that from plastic condensers.

By the end of the twentieth century, the details of how dew condenses was much better understood, the key insight being that low-mass collectors that rapidly lose heat by radiation performed best. A number of researchers worked on this method.^[32] In the 1960s, simple dew condensers made from sheets of polyethylene were used in Israel to irrigate plants, and in 1986 in New Mexico condensers made of a special foil produced sufficient water to supply young saplings.^[5]

International Organization for Dew Utilization

A radiative dew condenser test site at village Kothar in the north-west India near Arabian sea coast.

File:OPUR-Dew-Condenser1.jpg

Big OPUR Dew Condenser in Corsica

In 1992 a party of French academics attended a condensed matter conference in the Ukraine where physicist Daniel Beysens introduced them to the story of how ancient Theodosia was supplied with water from dew condensers. They were sufficiently intrigued that in 1993 they went to see for themselves. The supposed dew condensers turned out to be burial mounds, but they also found the remains of Zibold's condenser which they tidied up and examined closely. Fired with enthusiasm, the party returned to France and set up the International Organisation for Dew Utilization (OPUR) with the specific objective of making dew available as an alternative source of water.^[33][34]

OPUR began a study of dew condensation under laboratory conditions, they developed a special hydrophilic film and experimented with trial installations, including a 30 square metres (320 sq ft) collector in Corsica.^[35] Vital insights included the idea that the mass of the condensing surface should be as low as possible so that it cannot easily retain heat, that it should be protected from unwanted thermal radiation by a layer of insulation, and that it should be hydrophilic so as to shed condensed moisture readily.^[36]

By the time they were ready for their first practical installation, they heard that one of their members, Girja Sharan had obtained a grant to construct a dew condenser in Kothara, India. In April 2001, he had incidentally noticed substantial condensation on the roof of a cottage at Toran Beach Resort in the arid coastal region of Kutch, where he was briefly staying. The following year, he investigated the phenomenon more closely and interviewed local people. Financed by the Gujarat Energy Development Agency and the World Bank, Sharan and his team went on to develop passive, radiative condensers for use in the arid coastal region of Kutch.^[37] Active commercialisation began in 2006.^[38]

Sharan tested a wide range of materials and got good results from galvanised iron and aluminium sheets, but found that sheets of a special plastic developed by the OPUR just 400 micrometres (0.016 in) thick generally worked even better than the metal sheets and were less expensive.^[39] The plastic film, known as OPUR foil, is hydrophilic and is made from polyethylene mixed with titanium oxide and barium sulphate.

An example of a condenser-on-roof installation, condenser made of plastic film with special properties, with insulation layer between film and concrete roof surface. This installation is on school buildings at Sayara (Kutch, India). Unlike metal roofs, concrete roofs do not attract condensation without any treatment, hence the need for an external condenser. The output from such condensers is nearly two times higher than from a bare metal roof, all else remaining constant.

A typical radiative collector presents a condensing surface at an angle of 30° from the horizontal. The condensing surface is backed by a thick layer of insulating material such as polystyrene foam and supported 2–3 metres (7–10 ft) above ground level. Such condensers may be conveniently installed on the ridge roofs of low buildings or supported by a simple frame.^[40] Although other heights do not typically work quite so well, it may be less expensive or more convenient to mount a collector near to ground level on a two-storey building.^[41]

A radiative collector should be thermally isolated from any mass, including the ground. The condensing surface should be left open to radiate heat into space and should be well away from any source of heat or anything that can reflect heat radiation into it. Ideally, the condensing surface should be well wetted to reduce the nucleation barrier.^[42]

The 600 square metres (6,500 sq ft) radiative condenser illustrated near the start of this article is built near the ground. In the area of north-west India where it is installed dew occurs for 8 months a year, and the installation collects about 15 millimetres (0.59 in) of dew water over the season with nearly 100 dew-nights. In a year it provides a total of about 9,000 litres (2,000 imp gal; 2,400 US gal) of potable water for the school which owns and operates the site.^[1]

Although flat designs have the benefit of simplicity, other designs such as inverted pyramids and cones can be significantly more effective. This is probably because the designs shield the condensing surfaces from unwanted heat radiated by the lower atmosphere and being symmetrical they are not sensitive to wind direction.^[43]

New materials may make even better collectors.^[44] One such material is inspired by the Namib Desert beetle, which survives only on the moisture it extracts from the atmosphere. It has been found that its back is coated with microscopic projections: the peaks are hydrophilic and the troughs are hydrophobic.^[45][46] Researchers at the Massachusetts Institute of Technology have emulated this capability by creating a textured surface that combines alternating hydrophobic and hydrophilic materials.

Active collectors

Main article: Atmospheric water generator

Active atmospheric water collectors have been in use since the commercialisation of mechanical refrigeration. Essentially, all that is required is to cool a heat exchanger below the dew point and water will be produced. Such water production may take place as a by-product, possibly unwanted, of dehumidification.^[13]

Because mechanical refrigeration is energy intensive, such active systems are typically restricted to places where there is no supply of water that can be desalinated or purified at a lower cost and that are sufficiently far from a supply of fresh water to make transport uneconomical. Such circumstances are uncommon, and even then large installations such as that tried in the 1930s at Cook in South Australia failed because of the cost of running the installation – it was cheaper to transport water over large distances.^[22]

In the case of small installations, convenience may outweigh cost. There is a wide range of small machines designed to be used in offices that produce a few litres of drinking water from the atmosphere. However, there are circumstances where there really is no source of water other than the atmosphere. For example, in the 1930s, American designers added condenser systems to airships – in this case the air was that emitted by the exhaust of the engines and so it contained additional water as a product of combustion. The moisture was collected and used as additional ballast to compensate for the loss of weight as fuel was consumed. By collecting ballast in this way, the airship's buoyancy could be kept relatively constant without having to release helium gas which was both expensive and in limited supply.^[47]

More recently, on the International Space Station, the Zvezda module includes a humidity control system, the water it collects is usually used to supply the Elektron system that electrolyses water into hydrogen and oxygen, but it can be used for drinking in an emergency.^[48]

There are a number of designs that minimise the energy requirements of active condensers:

• One method is to use the ground as a heat sink by drawing air through underground pipes.^[49] This is often done to provide a source of cool air for a building by means of a ground-coupled heat exchanger (also known as Earth tubes) wherein condensation is typically regarded as a significant problem.^[50] A major problem with such designs is that the underground tubes are subject to contamination and difficult to keep clean. Designs of this type require air to be drawn through the pipes by a fan, but the power required may be provided (or supplemented) by a wind turbine.^[51]

• Cold seawater is used in the Seawater Greenhouse to both cool and humidify the interior of greenhouse-like structure. The cooling can be so effective that not only do the plants inside benefit from reduced transpiration, but dew collects on the outside of the structure and can easily be collected by gutters.^[5]

• Another type of atmospheric water collector makes use of desiccants which adsorb atmospheric water at ambient temperature, this makes it possible to extract moisture even when the relative humidity is as low as 14%.^[52] Systems of this sort have proved to be very useful as emergency supplies of safe drinking water.^[53] For regeneration, the desiccant needs to be heated, but in some designs this energy is supplied by the sun: air is ventilated at night over a bed of desiccants that adsorb the water vapour. During the day, the premises are closed, the greenhouse effect increases the temperature and, as in solar desalination pools, the water vapour is partially desorbed, condenses on a cold part and is collected.^[5]

See also

• Rainwater harvesting

References

Notes

1. Sharan, Girja (2007). "Harvesting dew to supplement drinking water supply in arid coastal villages of Gujarat" (pdf). Indian Institute of Management. http://www.iimahd.ernet.in/publications/data/2007-08-05Gsharan.pdf. Retrieved 17 March 2009. 
2. "Air Well Waters Parched Farms". Popular Science (Bonnier Corporation) 122 (3). March 1933. ISSN 0161-7370. http://books.google.com/books?id=oygDAAAAMBAJ&printsec=frontcover&source=gbs_summary_r&cad=0_0#PPA45,M1. 
3. Oxford English Dictionary: "dew-pond"
4. Pugsley, 1939
5. D. Beysens and I. Milimouk (December 2000). "The Case For Alternative Fresh Water Sources" (PDF). International Organization For Dew Utilization. http://www.opur.u-bordeaux.fr/angl/Secheresse-angl.pdf. Retrieved 10 March 2009. 
6. Naval Meteorology and Oceanography Command (2007). Atmospheric Moisture. United States Navy. Retrieved on 2008-12-27.
7. Nikolayev et al, 1996. p.23-26
8. Pearce, Fred (9 September 2006). "The Miracle of the Stones". New Scientist: 50–51. 
9. Alton, 2003. p. 1014.
10. D. Beysens et al. "Comment on "The moisture from the air as water resource in arid region: Hopes, doubt and facts" by Kogan and Trahtman" (PDF). Journal of Arid Environments. http://u.cs.biu.ac.il/~trakht/JAE06.pdf. Retrieved 11 August 2009. 
11. Based on diagram by Nikolayev et all, 1996
12. Nikolayev et al, 1996. p. 20-23
13. Nelson, 2003
14. Hills, 1966. p. 232.
15. Beysens et al 2006
16. Sharan, 2006. p. 72.
17. Klaphake quoted by Nelson, 2003
18. "In Croatia". OPUR. http://www.opur.u-bordeaux.fr/angl/events_ang.htm#croatia. Retrieved 17 March 2009. 
19. "Fifth Columnists? German and Austrian Refugees in Australian Internment Camps" (pdf). National Archives of Australia. p. 7. http://www.sisr.net/publications/0204neumann.pdf. Retrieved 3 August 2009. 
20. "Wolf Klaphake - Immigrant or refugee". Uncommon Lives (National Archives of Australia). http://uncommonlives.naa.gov.au/contents.asp?cID=2. Retrieved 5 August 2009. 
21. "Trans-Australian Railway photograph of a condenser cooler at Cook, 10 December 1917". Uncommon Lives (National Archives of Australia). http://uncommonlives.naa.gov.au/detail.asp?iID=197&lID=1&cID=3. Retrieved 5 August 2009. 
22. "Wolf Klaphake - A rainmaker?". Uncommon Lives (National Archives of Australia). http://uncommonlives.naa.gov.au/contents.asp?cID=3&lID=1. Retrieved 5 August 2009. 
23. Wolf Klaphake (1936). "Practical Methods for Condensation of Water from the Atmosphere". Proceeding of the Society of Chemical Industry of Victoria (Australia). http://www.sharingsustainablesolutions.org/air-wells/. Retrieved 27 July 2009. 
24. "British Knapen – The Early Years" (pdf). ProTen Services. http://www.protenservices.co.uk/pdf/name/28/ProTen_Services_History_in_Pictures.pdf. Retrieved 11 March 2009. 
25. Prevention Of Damp In Buildings. The Manchester Guardian, 27 February 1930 p. 6 column F.
26. "ProTen Services Celebrates 80 Years of Service" (PDF). ProTen Services. http://www.protenservices.co.uk/pdf/name/27/ProTen_Services_celebrates_80_Years_of_Service.pdf. Retrieved 11 March 2009. 
27. "Well Like Gigantic Ant Hill Gathers Water from Air". Popular Mechanics (Hearst Magazines) 58 (6): 868. December 1932. ISSN 0032-4558. http://books.google.com/books?id=fvEDAAAAMBAJ&printsec=frontcover#PPA868,M1. 
28. Achile Knappen. "Improved means for collecting moisture from the atmosphere". European Patent Office. http://v3.espacenet.com/publicationDetails/biblio?adjacent=true&KC=A&date=19300522&NR=319778A&DB=EPODOC&locale=en_V3&CC=GB&FT=D. Retrieved 28 April 2009. 
29. Nikolayev et al, 1996
30. "Pyramid Power". Popular Science (Bonnier Corporation) 241 (4): 30–31. October 1992. ISSN 0161-7370. http://books.google.com/books?id=nAEAAAAAMBAJ&lpg=PP1&pg=PA30#v=onepage&q=&f=false. 
31. Pearce, Fred (16 April 2005). "Pyramids of dew". New Scientist (2495). 
32. Sharan, 2006. p. 22.
33. OPUR Ou la Conquete de la Rosee – The Conquest of Dew (in French with English subtitles). at YouTube
34. "International Organization For Dew Utilization" (PDF). http://www.opur.u-bordeaux.fr/angl/page_accuei_angl.htm. Retrieved 27 April 2009. 
35. Muselli1, M.; D. Beysens, I. Milimouk. "Comparative Dew Yields From Two Large Planar Dew Condensers" (PDF). http://www.up.ac.za/academic/geog/meteo/EVENTS/fogdew2003/PAPERS/C70.pdf. Retrieved 10 August 2009. 
36. Sharan, 2006. pp. 20-28.
37. Sharan, 2006. Acknowledgement
38. Mukund, Dixit; Sharan, Girha (1 April 2007). "Leveraged Innovation Management: Key Themes from the Journey of Dewrain Harvest Systems" (pdf). Indian Institute of Management Ahmedabad, India. http://www.iimahd.ernet.in/publications/data/2007-01-04_mrdixit.pdf. Retrieved 30 March 2009. 
39. Sharan, 2006. p. 27.
40. Sharan, 2006. pp. 20-39.
41. Sharan, 2006. pp. 40-59.
42. Sharan, Girja. "Dew Yield From Passive Condensers in a Coastal Arid Area – Kutch" (pdf). p. 2. http://www.iimahd.ernet.in/publications/data/2005-01-05gsharan.pdf. Retrieved 30 March 2009. 
43. Clus, et al.
44. Sharan, 2006. p. 20.
45. Parker, A. R. & C. R. Lawrence (2001). "Water capture by a desert beetle". Nature 414 (6859): 33–34. doi:10.1038/35102108. PMID 11689930. 
46. Harries-Rees, Karen (August 31, 2005). "Desert beetle provides model for fog-free nanocoating". Chemistry World News (Royal Society of Chemistry). http://www.rsc.org/chemistryworld/News/2005/August/31080502.asp. 
47. Allen, 1931. p. 37.
48. "Zvezda". The ISS: Continued Assembly and Performance. NASA. http://www.shuttlepresskit.com/ISS_OVR/assembly2_overview.htm. Retrieved 18 May 2009. 
49. Lindsley, E.F. (January 1984). "Airwell extracts Pure Water From the Air". Popular Science (Bonnier Corporation) 224 (1). http://books.google.com/books?id=eAAAAAAAMBAJ&printsec=frontcover&source=gbs_summary_r&cad=0_0#PPA146,M1. 
50. David Darling. "Earth Cooling Tube". The Encyclopedia of Alternative Energy and Sustainable Living. http://www.daviddarling.info/encyclopedia/E/AE_earth_cooling_tube.html. Retrieved 15 May 2009. 
51. US4,351,651 (1980-12-06) Courneya, Calice, G., Apparatus for extracting potable water. 
52. Audrey Hudson. "Making Water From Thin Air". Wired. http://www.wired.com/science/discoveries/news/2006/10/71898. Retrieved 18 May 2009. 
53. "Aqua Sciences". http://www.aquasciences.com. Retrieved 29 April. 

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• Allen, Hugh (1931). The Story of the Airship. Goodyear Tire and Rubber Company. 
• Alton Stewart, Bobby; Terry A. Howell (2003). Encyclopedia of water science. Marcel Dekker. ISBN 9780824709488. 
• Beysens, D.; I. Milimouk; V.S. Nikolayev; S. Berkowicz; M. Muselli; B. Heusinkveld; A.F.G. Jacobs (2006). "Comment on "The moisture from the air as water resource in arid region: Hopes, doubt and facts" by Kogan and Trahtman" (PDF). Journal of Arid Environments (Elsevier) 67: 343. doi:10.1016/j.jaridenv.2006.01.011. http://u.cs.biu.ac.il/~trakht/JAE06.pdf. 
• Clus, Owen; Ouazzani, Jalil; Muselli, Marc; Nikolayev, Vadim; Sharan, Girja; Beysens Daniel. "Radiation-cooled Dew Water Condensers Studied by Computational Fluid Dynamic (CFD)" (pdf). http://arxiv.org/ftp/arxiv/papers/0707/0707.2514.pdf. Retrieved 30 March 2009. 
• Hills, Edwin Sherbon (1966). Arid Lands: A Geographical Appraisal. Methuen. 
• Nelson, Robert A. (2003). "Air Wells, Fog Fences & Dew Ponds – Methods for Recovery of Atmospheric Humidity". Rex Research. http://www.rexresearch.com/airwells/airwells.htm. Retrieved 10 March 2009. "This article has been widely reproduced, including extracts in Sharan, 2006." 
• Nikolayev, V.S.; D. Beysens, A. Gioda, I. Milimouk, E. Katiushin, J. P. Morel (1996). "Water Recovery from Dew". Journal of Hydrology (Elsevier) (182). 
• Pugsley, Alfred J (1939). Dewponds in Fable and Fact. London: Country Life Ltd. 
• Sharan, Girja (2006). Dew Harvest. Foundation Books. ISBN 81-7596-326-3. 

External links

Wikimedia Commons has media related to Air wells that may be added

• OPUR (International Organisation for Dew Utilization)
• OPUR in India (visually self-explanatory, in English and other languages with French subtitles). at YouTube
• "Fog Quest Official Site". http://www.fogquest.org/. Retrieved 19 March 2009. 
• "Dew Harvesting". Rainwater Harvesting Guide. http://www.rain-barrel.net/dew-harvesting.html. Retrieved 19 March 2009. 
• Pure water ... from thin Air! at YouTube – KBTV: Aqua Sciences Emergency Water Station, that produces pure water out of the humidity-saturated air in the wake of a hurricane.