Water distribution on Earth

Most water in Earth's atmosphere and crust comes from saline seawater, while fresh water accounts for nearly 1% of the total. The vast bulk of the water on Earth is saline or salt water, with an average salinity of 35‰ (or 3.5%, roughly equivalent to 34 grams of salts in 1 kg of seawater), though this varies slightly according to the amount of runoff received from surrounding land. In all, water from oceans and marginal seas, saline groundwater and water from saline closed lakes amount to over 97% of the water on Earth, though no closed lake stores a globally significant amount of water. Saline groundwater is seldom considered except when evaluating water quality in arid regions.

A graphical distribution of the locations of water on Earth
Visualisation of the distribution (by volume) of water on Earth. Each tiny cube (such as the one representing biological water) corresponds to approximately 1,000 km3 of water, with a mass of about 1 trillion tonnes (200,000 times that of the Great Pyramid of Giza or five times that of Lake Kariba, arguably the heaviest man-made object). Comprising 1 million tiny cubes, the entire cube would measure about 1,102 km on each side.[1]

The remainder of Earth's water constitutes the planet's freshwater resource. Typically, fresh water is defined as water with a salinity of less than 1% that of the oceans – i.e. below around 0.35‰. Water with a salinity between this level and 1‰ is typically referred to as marginal water because it is marginal for many uses by humans and animals. The ratio of salt water to fresh water on Earth is around 50:1.

The planet's fresh water is also very unevenly distributed. Although in warm periods such as the Mesozoic and Paleogene when there were no glaciers anywhere on the planet all fresh water was found in rivers and streams, today most fresh water exists in the form of ice, snow, groundwater and soil moisture, with only 0.3% in liquid form on the surface. Of the liquid surface fresh water, 87% is contained in lakes, 11% in swamps, and only 2% in rivers. Small quantities of water also exist in the atmosphere and in living beings.

Although the total volume of groundwater is known to be much greater than that of river runoff, a large proportion of this groundwater is saline and should therefore be classified with the saline water above. There is also a lot of fossil groundwater in arid regions that have never been renewed for thousands of years; this must not be seen as renewable water.

Distribution of saline and fresh water

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The total volume of water on Earth is estimated at 1.386 billion km3 (333 million cubic miles), with 97.5% being salt water and 2.5% being freshwater. Of the freshwater, only 0.3% is in liquid form on the surface.[2][3][4]

Because the oceans that cover roughly 70.8% of the area of Earth reflect blue light, Earth appears blue from space, and is often referred to as the blue planet and the Pale Blue Dot. Liquid freshwater like lakes and rivers cover about 1% of Earth's surface[5] and altogether with Earth's ice cover, Earth's surface is 75% water by area.[6]

Source of water Volume of water
in km3 (cu mi)
% total
water
% salt
water
% fresh
water
% liquid surface
fresh water
Oceans 1,338,000,000 (321,000,000) 96.5 99.0
Pacific Ocean 669,880,000 (160,710,000) 48.3 49.6
Atlantic Ocean 310,410,900 (74,471,500) 22.4 23.0
Indian Ocean 264,000,000 (63,000,000) 19.0 19.5
Southern Ocean 71,800,000 (17,200,000) 5.18 5.31
Arctic Ocean 18,750,000 (4,500,000) 1.35 1.39
Ice and snow 24,364,000 (5,845,000) 1.76 69.6
Glaciers 24,064,000 (5,773,000) 1.74 68.7
Antarctic ice sheet 21,600,000 (5,200,000) 1.56 61.7
Greenland ice sheet 2,340,000 (560,000) 0.17 6.68
Arctic islands 83,500 (20,000) 0.006 0.24
Mountain ranges 40,600 (9,700) 0.003 0.12
Ground ice and permafrost 300,000 (72,000) 0.022 0.86
Groundwater 23,400,000 (5,600,000) 1.69
Saline groundwater 12,870,000 (3,090,000) 0.93 0.95
Fresh groundwater 10,530,000 (2,530,000) 0.76 30.1
Soil moisture 16,500 (4,000) 0.0012 0.047
Lakes 176,400 (42,300) 0.013
Saline lakes 85,400 (20,500) 0.0062 0.0063
Caspian Sea 78,200 (18,800) 0.0056 0.0058
Other saline lakes 7,200 (1,700) 0.00052 0.00053
Fresh water lakes 91,000 (22,000) 0.0066 0.26 87.0
African Great Lakes 30,070 (7,210) 0.0022 0.086 28.8
Lake Baikal 23,615 (5,666) 0.0017 0.067 22.6
North American Great Lakes 22,115 (5,306) 0.0016 0.063 21.1
Other fresh water lakes 15,200 (3,600) 0.0011 0.043 14.5
Atmosphere 12,900 (3,100) 0.00093 0.037
Swamps 11,470 (2,750) 0.00083 0.033 11.0
Rivers 2,120 (510) 0.00015 0.0061 2.03
Biological water 1,120 (270) 0.000081 0.0032
 
Logarithm graph of source of water in cubic miles
 
Logarithm graph of fresh water's source (including saline lakes and saline groundwater)

Lakes

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Collectively, Earth's lakes hold 199,000 km3 of water.[7] Most lakes are in the high northern latitudes, far from human population centers.[8][9] The North American Great Lakes, which contain 21% of the world's fresh water by volume,[10][11][12] are an exception. The Great Lakes Basin is home to more than 35 million people.[13] The Canadian cities of Thunder Bay, St. Catharines, Hamilton, Toronto, Oshawa, and Kingston, as well as the U.S. cities of Detroit, Duluth, Milwaukee, Chicago, Gary, Cleveland, Buffalo, and Rochester are all located on shores of the Great Lakes System.

Groundwater

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Fresh groundwater is of great value, especially in arid countries such as China. Its distribution is broadly similar to that of surface river water, but it is easier to store in hot and dry climates because groundwater storage are much more shielded from evaporation than are dams. In countries such as Yemen, groundwater from erratic rainfall during the rainy season is the major source of irrigation water.

Because groundwater recharge is much more difficult to accurately measure than surface runoff, groundwater is not generally used in areas where even fairly limited levels of surface water are available. Even today, estimates of total groundwater recharge vary greatly for the same region depending on what source is used, and cases where fossil groundwater is exploited beyond the recharge rate (including the Ogallala Aquifer[14]) are very frequent and almost always not seriously considered when they were first developed.

Distribution of river water

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The total volume of water in rivers is estimated at 2,120 km3 (510 cu mi), or 0.49% of the surface fresh water on Earth.[2] Rivers and basins are often compared not according to their static volume, but to their flow of water, or surface run off. The distribution of river runoff across the Earth's surface is very uneven.

Continent or region River runoff (km3/year) Percent of world total
Asia (excluding Middle East) 13,300 30.6
South America 12,000 27.6
North America 7,800 17.9
Oceania 6,500 14.9
Sub-Saharan Africa 4,000 9.2
Europe 2,900 6.7
Australia 440 1.0
Middle East and North Africa 140 0.3

There can be huge variations within these regions. For example, as much as a quarter of Australia's limited renewable fresh water supply is found in almost uninhabited Cape York Peninsula.[15] Also, even in well-watered continents, there are areas that are extremely short of water, such as Texas in North America, whose renewable water supply totals only 26 km3/year in an area of 695,622 km2, or South Africa, with only 44 km3/year in 1,221,037 km2.[15] The areas of greatest concentration of renewable water are:

Area, volume, and depth of oceans

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Body of Water Area (106 km2) Volume (106 km3) Mean Depth (m)
Pacific Ocean 165.2 707.6 4,282
Atlantic Ocean 82.4 323.6 3,926
Indian Ocean 73.4 291.0 3,963
All oceans and seas 361 1,370 3,796

The oceanic crust is young, thin and dense, with none of the rocks within it dating from any older than the breakup of Pangaea.[citation needed] Because water is much denser than any gas, this means that water will flow into the "depressions" formed as a result of the high density of oceanic crust (on a planet like Venus, with no water, the depressions appear to form a vast plain above which rise plateaux). Since the low density rocks of the continental crust contain large quantities of easily eroded salts of the alkali and alkaline earth metals, salt has, over billions of years, accumulated in the oceans as a result of evaporation returning the fresh water to land as rain and snow.[citation needed]

Variability of water availability

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Variability of water availability is important both for the functioning of aquatic species and also for the availability of water for human use: water that is only available in a few wet years must not be considered renewable. Because most global runoff comes from areas of very low climatic variability, the total global runoff is generally of low variability.

Indeed, even in most arid zones, there tends to be few problems with variability of runoff because most usable sources of water come from high mountain regions which provide highly reliable glacier melt as the chief source of water, which also comes in the summer peak period of high demand for water. This historically aided the development of many of the great civilizations of ancient history, and even today allows for agriculture in such productive areas as the San Joaquin Valley.

However, in Australia and Southern Africa, the story is different. Here, runoff variability is much higher than in other continental regions of the world with similar climates.[16] Typically temperate (Köppen climate classification C) and arid (Köppen climate classification B) climate rivers in Australia and Southern Africa have as much as three times the coefficient of variation of runoff of those in other continental regions.[17] The reason for this is that, whereas all other continents have had their soils largely shaped by Quaternary glaciation and mountain building, soils of Australia and Southern Africa have been largely unaltered since at least the early Cretaceous and generally since the previous ice age in the Carboniferous. Consequently, available nutrient levels in Australian and Southern African soils tend to be orders of magnitude lower than those of similar climates in other continents, and native flora compensate for this through much higher rooting densities (e.g. proteoid roots) to absorb minimal phosphorus and other nutrients. Because these roots absorb so much water, runoff in typical Australian and Southern African rivers does not occur until about 300 mm (12 in) or more of rainfall has occurred. In other continents, runoff will occur after quite light rainfall due to the low rooting densities.

Climate type (Köppen[18]) Mean annual rainfall Typical runoff ratio
for Australia and Southern Africa
Typical runoff ratio
for rest of the world
BWh 250 mm (10 in) 1 percent (2.5 mm) 10 percent (25 mm)
BSh (on Mediterranean fringe) 350 mm (14 in) 3 percent (12 mm) 20 percent (80 mm)
Csa 500 mm (20 in) 5 percent (25 mm) 35 percent (175 mm)
Caf 900 mm (35 in) 15 percent (150 mm) 45 percent (400 mm)
Cb 1,100 mm (43 in) 25 percent (275 mm) 70 percent (770 mm)

The consequence of this is that many rivers in Australia and Southern Africa (as compared to extremely few in other continents) are theoretically impossible to regulate because rates of evaporation from dams mean a storage sufficiently large to theoretically regulate the river to a given level would actually allow very little draft to be used. Examples of such rivers include those in the Lake Eyre Basin. Even for other Australian rivers, a storage three times as large is needed to provide a third the supply of a comparable climate in southeastern North America or southern China. It also affects aquatic life, favouring strongly those species able to reproduce rapidly after high floods so that some will survive the next drought.

Tropical (Köppen climate classification A) climate rivers in Australia and Southern Africa do not, in contrast, have markedly lower runoff ratios than those of similar climates in other regions of the world. Although soils in tropical Australia and southern Africa are even poorer than those of the arid and temperate parts of these continents, vegetation can use organic phosphorus or phosphate dissolved in rainwater as a source of the nutrient. In cooler and drier climates these two related sources tend to be virtually useless, which is why such specialized means are needed to extract the most minimal phosphorus.

There are other isolated areas of high runoff variability, though these are basically due to erratic rainfall rather than different hydrology. These include:[17]

Possible water reservoirs inside Earth

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It has been hypothesized that the water is present in the Earth's crust, mantle and even the core and interacts with the surface ocean through the "whole-Earth water cycle". However, the actual amount of water stored in the Earth's interior still remains under debate. An estimated 1.5 to 11 times the amount of water in the oceans may be found hundreds of kilometers deep within the Earth's interior, although not in liquid form.[citation needed]

Water in Earth's mantle

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Ringwoodite is the major phase at the Earth's mantle between ~520 and ~660 km depth, possibly containing several weight percent of water in its crystal structure.

The lower mantle of inner earth may hold as much as 5 times more water than all surface water combined (all oceans, all lakes, all rivers).[19]

The amount of water stored in the Earth's interior may equal or exceed that in all of the surface oceans.[20] Some researchers proposed the total mantle water budget may amount to tens of ocean masses.[21] The water in the Earth's mantle is primarily dissolved in nominally anhydrous minerals as hydroxyls (OH).[22] These OH impurities in rocks and minerals can lubricates tectonic plate, influence rock viscosity and melting processes, and slow down seismic waves.[20] The two mantle phases at the transition zone between Earth's upper and lower mantle, wadsleyite and ringwoodite, could potentially incorporate up to a few weight percent of water into their crystal structure.[23] Direct evidence of the presence of water in the Earth's mantle was found in 2014 based on a hydrous ringwoodite sample included in a diamond from Juína, Brazil.[24] Seismic observations suggest the presence of water in dehydration melt at the top of the lower mantle under the continental US.[25] Molecular water (H2O) is not the primary water-bearing phase(s) in the mantle, but its high-pressure form, ice-VII, also has been found in super-deep diamonds.

See also

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References

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  1. ^ "USGS - Earth's water distribution". Archived from the original on 2012-06-29. Retrieved 2011-11-26.
  2. ^ a b Where is Earth's water?, United States Geological Survey.
  3. ^ Eakins, B.W. and G.F. Sharman, Volumes of the World's Oceans from ETOPO1 Archived 2015-03-11 at the Wayback Machine, NOAA National Geophysical Data Center, Boulder, CO, 2010.
  4. ^ Water in Crisis: Chapter 2 Archived 2022-10-06 at the Wayback Machine, Peter H. Gleick, Oxford University Press, 1993.
  5. ^ Downing, J. A.; Prairie, Y. T.; Cole, J. J.; Duarte, C. M.; Tranvik, L. J.; Striegl, R. G.; McDowell, W. H.; Kortelainen, P.; Caraco, N. F.; Melack, J. M.; Middelburg, J. J. (2006). "The global abundance and size distribution of lakes, ponds, and impoundments". Limnology and Oceanography. 51 (5). Wiley: 2388–2397. Bibcode:2006LimOc..51.2388D. doi:10.4319/lo.2006.51.5.2388. ISSN 0024-3590. S2CID 10011358.
  6. ^ "Earth Observatory Water Cycle Overview". Precipitation Education. 2010-09-02. Archived from the original on 2023-06-23. Retrieved 2022-01-16.
  7. ^ Cael, B. B.; Heathcote, A. J.; Seekell, D. A. (2017). "The volume and mean depth of Earth's lakes". Geophysical Research Letters. 44 (1): 209–218. Bibcode:2017GeoRL..44..209C. doi:10.1002/2016GL071378. hdl:1912/8822. ISSN 1944-8007. S2CID 132520745. Archived from the original on 2021-08-24. Retrieved 2021-08-25.
  8. ^ Verpoorter, Charles; Kutser, Tiit; Seekell, David A.; Tranvik, Lars J. (2014). "A global inventory of lakes based on high-resolution satellite imagery". Geophysical Research Letters. 41 (18): 6396–6402. Bibcode:2014GeoRL..41.6396V. doi:10.1002/2014GL060641. hdl:20.500.12210/62355. ISSN 1944-8007. S2CID 129573857.
  9. ^ Kummu, Matti; Varis, Olli (2011-04-01). "The world by latitudes: A global analysis of human population, development level and environment across the north–south axis over the past half century". Applied Geography. 31 (2): 495–507. doi:10.1016/j.apgeog.2010.10.009. ISSN 0143-6228. Archived from the original on 2023-11-30. Retrieved 2021-08-25.
  10. ^ "Great Lakes – U.S. EPA". Epa.gov. 2006-06-28. Archived from the original on 2012-12-01. Retrieved 2011-02-19.
  11. ^ "LUHNA Chapter 6: Historical Landcover Changes in the Great Lakes Region". Biology.usgs.gov. 2003-11-20. Archived from the original on 2012-01-11. Retrieved 2011-02-19.
  12. ^ Ghassemi, Fereidoun (2007). Inter-basin water transfer. Cambridge, Cambridge University Press. ISBN 978-0-521-86969-0.
  13. ^ "Great Lakes Quickfacts - Water - Environment Canada". Archived from the original on 2015-11-01. Retrieved 2015-10-29.
  14. ^ Reisner, Marc; Cadillac Desert: The American West and its Disappearing Water; pp. 438-442. ISBN 0-14-017824-4
  15. ^ a b Brown, J. A. H.; Australia’s surface water resources. ISBN 978-0-644-02617-8.
  16. ^ McMahon, T.A. and Finlayson, B.L.; Global Runoff: Continental Comparisons of Annual Flows and Peak Discharges. ISBN 3-923381-27-1.
  17. ^ a b Peel, Murray C.; McMahon, Thomas A. & Finlayson, Brian L. (2004). "Continental differences in the variability of annual runoff: update and reassessment". Journal of Hydrology. 295 (1–4): 185–197. Bibcode:2004JHyd..295..185P. doi:10.1016/j.jhydrol.2004.03.004.
  18. ^ This section uses a slightly modified version of the Köppen system found in The Times Atlas of the World, 7th edition. ISBN 0-7230-0265-7
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  21. ^ Ohtani, Eiji (2020-12-18). "Hydration and Dehydration in Earth's Interior". Annual Review of Earth and Planetary Sciences. 49: 253–278. doi:10.1146/annurev-earth-080320-062509. ISSN 0084-6597. S2CID 232569436. Archived from the original on 2024-02-04. Retrieved 2021-01-12.
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  23. ^ Kohlstedt, D. L.; Keppler, H.; Rubie, D. C. (1996-05-20). "Solubility of water in the α, β and γ phases of (Mg,Fe) 2 SiO 4". Contributions to Mineralogy and Petrology. 123 (4): 345–357. Bibcode:1996CoMP..123..345K. doi:10.1007/s004100050161. ISSN 0010-7999. S2CID 96574743. Archived from the original on 2024-02-04. Retrieved 2021-01-12.
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  25. ^ Schmandt, B.; Jacobsen, S. D.; Becker, T. W.; Liu, Z.; Dueker, K. G. (2014-06-13). "Dehydration melting at the top of the lower mantle". Science. 344 (6189): 1265–1268. Bibcode:2014Sci...344.1265S. doi:10.1126/science.1253358. ISSN 0036-8075. PMID 24926016. S2CID 206556921. Archived from the original on 2023-06-21. Retrieved 2022-06-30.