Artificial gills are unproven conceptualised devices to allow a human to be able to take in oxygen from surrounding water. This is speculative technology that has not been demonstrated in a documented fashion. Natural gills work because nearly all animals with gills are thermoconformers (cold-blooded), so they need much less oxygen than a thermoregulator (warm-blood) of the same size.[1] As a practical matter, it is unclear that a usable artificial gill could be created because of the large amount of oxygen a human would need extracted from the water.
Methods
Several potential methods exist for the development of artificial gills. One proposed method is the use of liquid breathing with a membrane oxygenator to solve the problem of carbon dioxide retention, the major limiting factor in liquid breathing.[2][3][dubious – discuss] It is thought that a system such as this would allow for diving without risk of decompression sickness.[4]
They are generally thought to be unwieldy and bulky, because of the massive amount of water that would have to be processed to extract enough oxygen to supply an active diver, as an alternative to a scuba set.
An average diver with a fully closed-circuit rebreather needs 1.5 liters (0.40 U.S. gallons) of oxygen per minute while swimming or 0.64 L (0.17 US gal) per minute while resting.[5] At least 192 liters (50.7 U.S. gal) of sea water per minute would have to be passed through the system, and this system would not work in anoxic water. Seawater in tropical regions with abundant plant life contains 5–8 mg (0.077–0.123 gr) of oxygen per liter of water.[6] These calculations are based on the dissolved oxygen content of water.
Le Page, Michael (7 January 2006). "Breathing in oceans full of air". New Scientist (2533).(subscription required) History of attempts to develop artificial gills and the principles and problems involved.
Artificial gills in fiction (called a "hydrolung") in Tom Swift and the Electronic Hydrolung, by Victor Appleton. It is a rebreather, fitted with a device that extracts oxygen from surrounding water.