Misplaced Pages

Hot spring

Article snapshot taken from Wikipedia with creative commons attribution-sharealike license. Give it a read and then ask your questions in the chat. We can research this topic together.
(Redirected from Hot-spring) Spring produced by the emergence of geothermally heated groundwater "Hot springs" redirects here. For other uses, see Hot Springs (disambiguation).
Grand Prismatic Spring and Midway Geyser Basin in Yellowstone National Park

A hot spring, hydrothermal spring, or geothermal spring is a spring produced by the emergence of geothermally heated groundwater onto the surface of the Earth. The groundwater is heated either by shallow bodies of magma (molten rock) or by circulation through faults to hot rock deep in the Earth's crust.

Hot spring water often contains large amounts of dissolved minerals. The chemistry of hot springs ranges from acid sulfate springs with a pH as low as 0.8, to alkaline chloride springs saturated with silica, to bicarbonate springs saturated with carbon dioxide and carbonate minerals. Some springs also contain abundant dissolved iron. The minerals brought to the surface in hot springs often feed communities of extremophiles, microorganisms adapted to extreme conditions, and it is possible that life on Earth had its origin in hot springs.

Humans have made use of hot springs for bathing, relaxation, or medical therapy for thousands of years. However, some are hot enough that immersion can be harmful, leading to scalding and, potentially, death.

Definitions

There is no universally accepted definition of a hot spring. For example, one can find the phrase hot spring defined as

Hot water springs in Rio Quente, Brazil
  • a natural spring of water whose temperature is greater than 21 °C (70 °F)
  • a type of thermal spring whose water temperature is usually 6 to 8 °C (11 to 14 °F) or more above mean air temperature.
  • a spring with water temperatures above 50 °C (122 °F)

The related term "warm spring" is defined as a spring with water temperature less than a hot spring by many sources, although Pentecost et al. (2003) suggest that the phrase "warm spring" is not useful and should be avoided. The US NOAA Geophysical Data Center defines a "warm spring" as a spring with water between 20 and 50 °C (68 and 122 °F).

Sources of heat

Water issuing from a hot spring is heated geothermally, that is, with heat produced from the Earth's mantle. This takes place in two ways. In areas of high volcanic activity, magma (molten rock) may be present at shallow depths in the Earth's crust. Groundwater is heated by these shallow magma bodies and rises to the surface to emerge at a hot spring. However, even in areas that do not experience volcanic activity, the temperature of rocks within the earth increases with depth. The rate of temperature increase with depth is known as the geothermal gradient. If water percolates deeply enough into the crust, it will be heated as it comes into contact with hot rock. This generally takes place along faults, where shattered rock beds provide easy paths for water to circulate to greater depths.

Much of the heat is created by decay of naturally radioactive elements. An estimated 45 to 90 percent of the heat escaping from the Earth originates from radioactive decay of elements mainly located in the mantle. The major heat-producing isotopes in the Earth are potassium-40, uranium-238, uranium-235, and thorium-232. In areas with no volcanic activity, this heat flows through the crust by a slow process of thermal conduction, but in volcanic areas, the heat is carried to the surface more rapidly by bodies of magma.

The radiogenic heat from the decay of U and Th are now the major contributors to the earth's internal heat budget.

A hot spring that periodically jets water and steam is called a geyser. In active volcanic zones such as Yellowstone National Park, magma may be present at shallow depths. If a hot spring is connected to a large natural cistern close to such a magma body, the magma may superheat the water in the cistern, raising its temperature above the normal boiling point. The water will not immediately boil, because the weight of the water column above the cistern pressurizes the cistern and suppresses boiling. However, as the superheated water expands, some of the water will emerge at the surface, reducing pressure in the cistern. This allows some of the water in the cistern to flash into steam, which forces more water out of the hot spring. This leads to a runaway condition in which a sizable amount of water and steam are forcibly ejected from the hot spring as the cistern is emptied. The cistern then refills with cooler water, and the cycle repeats.

Geysers require both a natural cistern and an abundant source of cooler water to refill the cistern after each eruption of the geyser. If the water supply is less abundant, so that the water is boiled as fast as it can accumulate and only reaches the surface in the form of steam, the result is a fumarole. If the water is mixed with mud and clay, the result is a mud pot.

An example of a non-volcanic warm spring is Warm Springs, Georgia (frequented for its therapeutic effects by paraplegic U.S. President Franklin D. Roosevelt, who built the Little White House there). Here the groundwater originates as rain and snow (meteoric water) falling on the nearby mountains, which penetrates a particular formation (Hollis Quartzite) to a depth of 3,000 feet (910 m) and is heated by the normal geothermal gradient.

Chemistry

Hammam Maskhoutine in Algeria, an example of a bicarbonate hot spring

Because heated water can hold more dissolved solids than cold water, the water that issues from hot springs often has a very high mineral content, containing everything from calcium to lithium and even radium. The overall chemistry of hot springs varies from alkaline chloride to acid sulfate to bicarbonate to iron-rich, each of which defines an end member of a range of possible hot spring chemistries.

Alkaline chloride hot springs are fed by hydrothermal fluids that form when groundwater containing dissolved chloride salts reacts with silicate rocks at high temperature. These springs have nearly neutral pH but are saturated with silica (SiO2). The solubility of silica depends strongly upon temperature, so upon cooling, the silica is deposited as geyserite, a form of opal (opal-A: SiO2·nH2O). This process is slow enough that geyserite is not all deposited immediately around the vent, but tends to build up a low, broad platform for some distance around the spring opening.

Acid sulfate hot springs are fed by hydrothermal fluids rich in hydrogen sulfide (H2S), which is oxidized to form sulfuric acid, H2SO4. The pH of the fluids is thereby lowered to values as low as 0.8. The acid reacts with rock to alter it to clay minerals, oxide minerals, and a residue of silica.

Bicarbonate hot springs are fed by hydrothermal fluids that form when carbon dioxide (CO2) and groundwater react with carbonate rocks. When the fluids reach the surface, CO2 is rapidly lost and carbonate minerals precipitate as travertine, so that bicarbonate hot springs tend to form high-relief structures around their openings.

Iron-rich springs are characterized by the presence of microbial communities that produce clumps of oxidized iron from iron in the hydrothermal fluids feeding the spring.

Some hot springs produce fluids that are intermediate in chemistry between these extremes. For example, mixed acid-sulfate-chloride hot springs are intermediate between acid sulfate and alkaline chloride springs and may form by mixing of acid sulfate and alkaline chloride fluids. They deposit geyserite, but in smaller quantities than alkaline chloride springs.

Flow rates

Deildartunguhver, Iceland: the highest flow hot spring in Europe

Hot springs range in flow rate from the tiniest "seeps" to veritable rivers of hot water. Sometimes there is enough pressure that the water shoots upward in a geyser, or fountain.

High-flow hot springs

There are many claims in the literature about the flow rates of hot springs. There are many more high flow non-thermal springs than geothermal springs. Springs with high flow rates include:

  • The Dalhousie Springs complex in Australia had a peak total flow of more than 23,000 liters/second in 1915, giving the average spring in the complex an output of more than 325 liters/second. This has been reduced now to a peak total flow of 17,370 liters/second so the average spring has a peak output of about 250 liters/second.
  • "Blood Pond" hot spring in Beppu, Japan
    The 2,850 hot springs of Beppu in Japan are the highest flow hot spring complex in Japan. Together the Beppu hot springs produce about 1,592 liters/second, or corresponding to an average hot spring flow of 0.56 liters/second.
  • The 303 hot springs of Kokonoe in Japan produce 1,028 liters/second, which gives the average hot spring a flow of 3.39 liters/second.
  • Ōita Prefecture has 4,762 hot springs, with a total flow of 4,437 liters/second, so the average hot spring flow is 0.93 liters/second.
  • The highest flow rate hot spring in Japan is the Tamagawa Hot Spring in Akita Prefecture, which has a flow rate of 150 liters/second. The Tamagawa Hot Spring feeds a 3 m (9.8 ft) wide stream with a temperature of 98 °C (208 °F).
  • The most famous hot springs of Brazil's Caldas Novas ("New Hot Springs" in Portuguese) are tapped by 86 wells, from which 333 liters/second are pumped for 14 hours per day. This corresponds to a peak average flow rate of 3.89 liters/second per well.
  • In Florida, there are 33 recognized "magnitude one springs" (having a flow in excess of 2,800 L/s (99 cu ft/s)). Silver Springs, Florida has a flow of more than 21,000 L/s (740 cu ft/s).
  • The Excelsior Geyser Crater in Yellowstone National Park yields about 4,000 U.S. gal/min (0.25 m/s).
  • Evans Plunge in Hot Springs, South Dakota has a flow rate of 5,000 U.S. gal/min (0.32 m/s) of 87 °F (31 °C) spring water. The Plunge, built in 1890, is the world's largest natural warm water indoor swimming pool.
  • The hot spring of Saturnia, Italy with around 500 liters a second
  • Lava Hot Springs in Idaho has a flow of 130 liters/second.
  • Glenwood Springs in Colorado has a flow of 143 liters/second.
  • Elizabeth Springs in western Queensland, Australia might have had a flow of 158 liters/second in the late 19th century, but now has a flow of about 5 liters/second.
  • Deildartunguhver in Iceland has a flow of 180 liters/second.
  • There are at least three hot springs in the Nage region 8 km (5.0 mi) south west of Bajawa in Indonesia that collectively produce more than 453.6 liters/second.
  • There are another three large hot springs (Mengeruda, Wae Bana and Piga) 18 km (11 mi) north east of Bajawa, Indonesia that together produce more than 450 liters/second of hot water.

Ecosystems

See also: Thermophile
Algal mats growing in the Map of Africa hot pool, Orakei Korako, New Zealand

Hot springs often host communities of microorganisms adapted to life in hot, mineral-laden water. These include thermophiles, which are a type of extremophile that thrives at high temperatures, between 45 and 80 °C (113 and 176 °F). Further from the vent, where the water has had time to cool and precipitate part of its mineral load, conditions favor organisms adapted to less extreme conditions. This produces a succession of microbial communities as one moves away from the vent, which in some respects resembles the successive stages in the evolution of early life.

For example, in a bicarbonate hot spring, the community of organisms immediately around the vent is dominated by filamentous thermophilic bacteria, such as Aquifex and other Aquificales, that oxidize sulfide and hydrogen to obtain energy for their life processes. Further from the vent, where water temperatures have dropped below 60 °C (140 °F), the surface is covered with microbial mats 1 centimetre (0.39 in) thick that are dominated by cyanobacteria, such as Spirulina, Oscillatoria, and Synechococcus, and green sulfur bacteria such as Chloroflexus. These organisms are all capable of photosynthesis, though green sulfur bacteria produce sulfur rather than oxygen during photosynthesis. Still further from the vent, where temperatures drop below 45 °C (113 °F), conditions are favorable for a complex community of microorganisms that includes Spirulina, Calothrix, diatoms and other single-celled eukaryotes, and grazing insects and protozoans. As temperatures drop close to those of the surroundings, higher plants appear.

Alkali chloride hot springs show a similar succession of communities of organisms, with various thermophilic bacteria and archaea in the hottest parts of the vent. Acid sulfate hot springs show a somewhat different succession of microorganisms, dominated by acid-tolerant algae (such as members of Cyanidiophyceae), fungi, and diatoms. Iron-rich hot springs contain communities of photosynthetic organisms that oxidize reduced (ferrous) iron to oxidized (ferric) iron.

Hot springs are a dependable source of water that provides a rich chemical environment. This includes reduced chemical species that microorganisms can oxidize as a source of energy.

Significance to abiogenesis

Main article: Abiogenesis § Hot springs

Hot spring hypothesis

In contrast with "black smokers" (hydrothermal vents on the ocean floor), hot springs similar to terrestrial hydrothermal fields at Kamchatka produce fluids having suitable pH and temperature for early cells and biochemical reactions. Dissolved organic compounds were found in hot springs at Kamchatka . Metal sulfides and silica minerals in these environments would act as photocatalysts. They experience cycles of wetting and drying which promote the formation of biopolymers which are then encapsulated in vesicles after rehydration. Solar UV exposure to the environment promotes synthesis to monomeric biomolecules. The ionic composition and concentration of hot springs (K, B, Zn, P, O, S, C, Mn, N, and H) are identical to the cytoplasm of modern cells and possibly to those of the LUCA or early cellular life according to phylogenomic analysis. For these reasons, it has been hypothesized that hot springs may be the place of origin of life on Earth. The evolutionary implications of the hypothesis imply a direct evolutionary pathway to land plants. Where continuous exposure to sunlight leads to the development of photosynthetic properties and later colonize on land and life at hydrothermal vents is suggested to be a later adaptation.

Recent experimental studies at hot springs support this hypothesis. They show that fatty acids self-assemble into membranous structures and encapsulate synthesized biomolecules during exposure to UV light and multiple wet-dry cycles at slightly alkaline or acidic hot springs, which would not happen at saltwater conditions as the high concentrations of ionic solutes there would inhibit the formation of membranous structures. David Deamer and Bruce Damer note that these hypothesized prebiotic environments resemble Charles Darwin's imagined "warm little pond". If life did not emerge at deep sea hydrothermal vents, rather at terrestrial pools, extraterrestrial quinones transported to the environment would generate redox reactions conducive to proton gradients. Without continuous wet-dry cycling to maintain stability of primitive proteins for membrane transport and other biological macromolecules, they would go through hydrolysis in an aquatic environment. Scientists discovered a 3.48 billion year old geyserite that seemingly preserved fossilized microbial life, stromatolites, and biosignatures. Researchers propose pyrophosphite to have been used by early cellular life for energy storage and it might have been a precursor to pyrophosphate. Phosphites, which are present at hot springs, would have bonded together into pyrophosphite within hot springs through wet-dry cycling. Like alkaline hydrothermal vents, the Hakuba Happo hot spring goes through serpentinization, suggesting methanogenic microbial life possibly originated in similar habitats.

Limitations

A problem with the hot spring hypothesis for an origin of life is that phosphate has low solubility in water. Pyrophosphite could have been present within protocells, however all modern life forms use pyrophosphate for energy storage. Kee suggests that pyrophosphate could have been utilized after the emergence of enzymes. Dehydrated conditions would favor phosphorylation of organic compounds and condensation of phosphate to polyphosphate. Another problem is that solar ultraviolet radiation and frequent impacts would have inhibited habitability of early cellular life at hot springs, although biological macromolecules might have undergone selection during exposure to solar ultraviolet radiation and would have been catalyzed by photocatalytic silica minerals and metal sulfides. Carbonaceous meteors during the Late Heavy Bombardment would not have caused cratering on Earth as they would produce fragments upon atmospheric entry. The meteors are estimated to have been 40 to 80 meters in diameter however larger impactors would produce larger craters. Metabolic pathways have not yet been demonstrated at these environments, but the development of proton gradients might have been generated by redox reactions coupled to meteoric quinones or protocell growth. Metabolic reactions in the Wood-Ljungdahl pathway and reverse Krebs cycle have been produced in acidic conditions and thermophilic temperatures in the presence of metals which is consistent with observations of RNA mostly stable at acidic pH.

Human uses

Macaques enjoying an open air hot spring or "onsen" in Nagano
Winter bathing at Tsuru-no-yu roten-buro in Nyūtō, Akita
Sai Ngam hot springs in Mae Hong Son province, Thailand

History

Hot springs have been enjoyed by humans for thousands of years. Even macaques are known to have extended their northern range into Japan by making use of hot springs to protect themselves from cold stress. Hot spring baths (onsen) have been in use in Japan for at least two thousand years, traditionally for cleanliness and relaxation, but increasingly for their therapeutic value. In the Homeric Age of Greece (ca. 1000 BCE), baths were primarily for hygiene, but by the time of Hippocrates (ca. 460 BCE), hot springs were credited with healing power. The popularity of hot springs has fluctuated over the centuries since, but they are now popular around the world.

Therapeutic uses

Because of both the folklore and the claimed medical value attributed to some hot springs, they are often popular tourist destinations, and locations for rehabilitation clinics for those with disabilities. However, the scientific basis for therapeutic bathing in hot springs is uncertain. Hot bath therapy for lead poisoning was common and reportedly highly successful in the 18th and 19th centuries, and may have been due to diuresis (increased production of urine) from sitting in hot water, which increased excretion of lead; better food and isolation from lead sources; and increased intake of calcium and iron. Significant improvement in patients with rheumatoid arthritis and ankylosing spondylitis have been reported in studies of spa therapy, but these studies have methodological problems, such as the obvious impracticality of placebo-controlled studies (in which a patient does not know if they are receiving the therapy). As a result, the therapeutic effectiveness of hot spring therapy remains uncertain.

Precautions

Hot springs in volcanic areas are often at or near the boiling point. People have been seriously scalded and even killed by accidentally or intentionally entering these springs.

Some hot springs microbiota are infectious to humans:

Etiquette

The customs and practices observed differ depending on the hot spring. It is common practice that bathers should wash before entering the water so as not to contaminate the water (with/without soap). In many countries, like Japan, it is required to enter the hot spring with no clothes on, including swimwear. Often there are different facilities or times for men and women, but mixed onsen do exist. In some countries, if it is a public hot spring, swimwear is required.

Examples

Distribution of geothermal springs in the US
Main article: List of hot springs

There are hot springs in many places and on all continents of the world. Countries that are renowned for their hot springs include China, Costa Rica, Hungary, Iceland, Iran, Japan, New Zealand, Brazil, Peru, Serbia, South Korea, Taiwan, Turkey, and the United States, but there are hot springs in many other places as well:

  • Widely renowned since a chemistry professor's report in 1918 classified them as one of the world's most electrolytic mineral waters, the Rio Hondo Hot Springs in northern Argentina have become among the most visited on earth. The Cacheuta Spa is another famous hot springs in Argentina.
  • The springs in Europe with the highest temperatures are located in France, in a small village named Chaudes-Aigues. Located at the heart of the French volcanic region Auvergne, the thirty natural hot springs of Chaudes-Aigues have temperatures ranging from 45 °C (113 °F) to more than 80 °C (176 °F). The hottest one, the "Source du Par", has a temperature of 82 °C (180 °F). The hot waters running under the village have provided heat for the houses and for the church since the 14th Century. Chaudes-Aigues (Cantal, France) is a spa town known since the Roman Empire for the treatment of rheumatism.
  • Carbonate aquifers in foreland tectonic settings can host important thermal springs although located in areas commonly not characterised by regional high heat flow values. In these cases, when thermal springs are located close or along the coastlines, the subaerial and/or submarine thermal springs constitute the outflow of marine groundwater, flowing through localised fractures and karstic rock-volumes. This is the case of springs occurring along the south-easternmost portion of the Apulia region (Southern Italy) where few sulphurous and warm waters (22–33 °C (72–91 °F)) outflow in partially submerged caves located along the Adriatic coast, thus supplying the historical spas of Santa Cesarea Terme. These springs are known from ancient times (Aristotele in III Century BC) and the physical-chemical features of their thermal waters resulted to be partly influenced by the sea level variations.
  • One of the potential geothermal energy reservoirs in India is the Tattapani thermal springs of Madhya Pradesh.
  • The silica-rich deposits found in Nili Patera, the volcanic caldera in Syrtis Major, Mars, are thought to be the remains of an extinct hot spring system.

See also

References

  1. Farmer, J.D. (2000). "Hydrothermal systems: doorways to early biosphere evolution" (PDF). GSA Today. 10 (7): 1–9. Retrieved 25 June 2021.
  2. Des Marais, David J.; Walter, Malcolm R. (2019-12-01). "Terrestrial Hot Spring Systems: Introduction". Astrobiology. 19 (12): 1419–1432. Bibcode:2019AsBio..19.1419D. doi:10.1089/ast.2018.1976. PMC 6918855. PMID 31424278.
  3. "Hot Springs/Geothermal Features - Geology (U.S. National Park Service)". www.nps.gov. Retrieved 2021-02-11.
  4. "MSN Encarta definition of hot spring". Archived from the original on 2009-01-22.
  5. Miriam-Webster Online dictionary definition of hot spring
  6. Columbia Encyclopedia, sixth edition, article on hot spring Archived 2007-02-11 at the Wayback Machine
  7. Wordsmyth definition of hot spring
  8. American Heritage dictionary, fourth edition (2000) definition of hot spring Archived 2007-03-10 at the Wayback Machine
  9. ^ Allan Pentecost; B. Jones; R.W. Renaut (2003). "What is a hot spring?". Can. J. Earth Sci. 40 (11): 1443–6. Bibcode:2003CaJES..40.1443P. doi:10.1139/e03-083. Archived from the original on 2007-03-11. provides a critical discussion of the definition of a hot spring.
  10. Infoplease definition of hot spring
  11. Random House Unabridged Dictionary, © Random House, Inc. 2006. definition of hot spring
  12. Wordnet 2.0 definition of hot spring
  13. Ultralingua Online Dictionary definition of hot spring
  14. Rhymezone definition of hot spring
  15. Lookwayup definition of hot spring
  16. Don L. Leet (1982). Physical Geology (6th ed.). Englewood Cliffs, NJ: Prentice-Hall. ISBN 978-0-13-669706-0. Archived from the original on 2010-10-02. Retrieved 2006-11-03. A thermal spring is defined as a spring that brings warm or hot water to the surface. Leet states that there are two types of thermal springs; hot springs and warm springs. Note that by this definition, "thermal spring" is not synonymous with the term "hot spring".
  17. US NOAA Geophysical Data Center definition
  18. Macdonald, Gordon A.; Abbott, Agatin T.; Peterson, Frank L. (1983). Volcanoes in the sea : the geology of Hawaii (2nd ed.). Honolulu: University of Hawaii Press. ISBN 0-8248-0832-0.
  19. Turcotte, DL; Schubert, G (2002). "4". Geodynamics (2nd ed.). Cambridge, England, UK: Cambridge University Press. pp. 136–7. ISBN 978-0-521-66624-4.
  20. Anuta, Joe (2006-03-30). "Probing Question: What heats the earth's core?". physorg.com. Retrieved 2007-09-19.
  21. Johnston, Hamish (19 July 2011). "Radioactive decay accounts for half of Earth's heat". PhysicsWorld.com. Institute of Physics. Retrieved 18 June 2013.
  22. Sanders, Robert (2003-12-10). "Radioactive potassium may be major heat source in Earth's core". UC Berkeley News. Retrieved 2007-02-28.
  23. Philpotts, Anthony R.; Ague, Jay J. (2009). Principles of igneous and metamorphic petrology (2nd ed.). Cambridge, UK: Cambridge University Press. pp. 6–13. ISBN 978-0-521-88006-0.
  24. ^ Macdonald, Abbott & Peterson 1983.
  25. "Hot Springs/Geothermal Features". Geology. National Park Service. 10 February 2020. Retrieved 25 June 2021.
  26. National Park Service 2020.
  27. Hewett, D.F.; Crickmay, G.W. (1937). "The warm springs of Georgia, their geologic relations and origin, a summary report". United States Geological Survey Water Supply Paper. 819. doi:10.3133/wsp819.
  28. Drake, Bryan D.; Campbell, Kathleen A.; Rowland, Julie V.; Guido, Diego M.; Browne, Patrick R.L.; Rae, Andrew (August 2014). "Evolution of a dynamic paleo-hydrothermal system at Mangatete, Taupo Volcanic Zone, New Zealand". Journal of Volcanology and Geothermal Research. 282: 19–35. Bibcode:2014JVGR..282...19D. doi:10.1016/j.jvolgeores.2014.06.010. hdl:11336/31453.
  29. ^ Des Marais & Walter 2019.
  30. White, Donald E.; Brannock, W.W.; Murata, K.J. (August 1956). "Silica in hot-spring waters". Geochimica et Cosmochimica Acta. 10 (1–2): 27–59. Bibcode:1956GeCoA..10...27W. doi:10.1016/0016-7037(56)90010-2.
  31. ^ Drake et al. 2014.
  32. White, D.E.; Thompson, G.A.; Sandberg, C.H. (1964). "Rocks, structure, and geologic history of Steamboat Springs thermal area, Washoe County, Nevada". U.S. Geological Survey Professional Paper. Professional Paper. 458-B. doi:10.3133/pp458B.
  33. Cox, Alysia; Shock, Everett L.; Havig, Jeff R. (January 2011). "The transition to microbial photosynthesis in hot spring ecosystems". Chemical Geology. 280 (3–4): 344–351. Bibcode:2011ChGeo.280..344C. doi:10.1016/j.chemgeo.2010.11.022.
  34. Parenteau, M. N.; Cady, S. L. (2010-02-01). "Microbial biosignatures in iron-mineralized phototrophic mats at Chocolate Pots Hot Springs, Yellowstone National Park, United States". PALAIOS. 25 (2): 97–111. Bibcode:2010Palai..25...97P. doi:10.2110/palo.2008.p08-133r. S2CID 128592574.
  35. W. F. Ponder (2002). "Desert Springs of Great Australian Arterial Basin". Conference Proceedings. Spring-fed Wetlands: Important Scientific and Cultural Resources of the Intermountain Region. Archived from the original on 2008-10-06. Retrieved 2013-04-06.
  36. Terme di Saturnia Archived 2013-04-17 at the Wayback Machine, website
  37. Madigan MT, Martino JM (2006). Brock Biology of Microorganisms (11th ed.). Pearson. p. 136. ISBN 978-0-13-196893-6.
  38. ^ Farmer 2000.
  39. Pentecost, Allan (2003-11-01). "Cyanobacteria associated with hot spring travertines". Canadian Journal of Earth Sciences. 40 (11): 1447–1457. Bibcode:2003CaJES..40.1447P. doi:10.1139/e03-075.
  40. Parenteau & Cady 2010.
  41. Kompanichenko, Vladimir N. (May 16, 2019). "Exploring the Kamchatka Geothermal Region in the Context of Life's Beginning". Life. 9 (2): 41. Bibcode:2019Life....9...41K. doi:10.3390/life9020041. ISSN 2075-1729. PMC 6616967. PMID 31100955.
  42. ^ Mulkidjanian, Armen Y.; Bychkov, Andrew Yu.; Dibrova, Daria V.; Galperin, Michael Y.; Koonin, Eugene V. (2012-04-03). "Origin of first cells at terrestrial, anoxic geothermal fields". Proceedings of the National Academy of Sciences. 109 (14): E821-30. doi:10.1073/pnas.1117774109. PMC 3325685. PMID 22331915.
  43. Damer, Bruce; Deamer, David (March 15, 2015). "Coupled Phases and Combinatorial Selection in Fluctuating Hydrothermal Pools: A Scenario to Guide Experimental Approaches to the Origin of Cellular Life". Life. 5 (1): 872–887. Bibcode:2015Life....5..872D. doi:10.3390/life5010872. PMC 4390883. PMID 25780958.
  44. Patel, Bhavesh H.; Percivalle, Claudia; Ritson, Dougal J.; Duffy, Colm D.; Sutherland, John D. (March 16, 2015). "Common origins of RNA, protein and lipid precursors in a cyanosulfidic protometabolism". Nature Chemistry. 7 (4): 301–307. Bibcode:2015NatCh...7..301P. doi:10.1038/nchem.2202. ISSN 1755-4349. PMC 4568310. PMID 25803468.
  45. Van Kranendonk, Martin J.; Baumgartner, Raphael; Djokic, Tara; Ota, Tsutomu; Steller, Luke; Garbe, Ulf; Nakamura, Eizo (2021-01-01). "Elements for the Origin of Life on Land: A Deep-Time Perspective from the Pilbara Craton of Western Australia". Astrobiology. 21 (1): 39–59. Bibcode:2021AsBio..21...39V. doi:10.1089/ast.2019.2107. PMID 33404294. S2CID 230783184.
  46. ^ Damer, Bruce; Deamer, David (2020-04-01). "The Hot Spring Hypothesis for an Origin of Life". Astrobiology. 20 (4): 429–452. Bibcode:2020AsBio..20..429D. doi:10.1089/ast.2019.2045. ISSN 1531-1074. PMC 7133448. PMID 31841362.
  47. Deamer, David (February 10, 2021). "Where Did Life Begin? Testing Ideas in Prebiotic Analogue Conditions". Life. 11 (2): 134. Bibcode:2021Life...11..134D. doi:10.3390/life11020134. ISSN 2075-1729. PMC 7916457. PMID 33578711.
  48. Milshteyn, Daniel; Damer, Bruce; Havig, Jeff; Deamer, David (May 10, 2018). "Amphiphilic Compounds Assemble into Membranous Vesicles in Hydrothermal Hot Spring Water but Not in Seawater". Life. 8 (2): 11. Bibcode:2018Life....8...11M. doi:10.3390/life8020011. PMC 6027054. PMID 29748464.
  49. Djokic, Tara; Van Kranendonk, Martin J.; Campbell, Kathleen A.; Walter, Malcolm R.; Ward, Colin R. (2017-05-09). "Earliest signs of life on land preserved in ca. 3.5 Ga hot spring deposits". Nature Communications. 8 (1): 15263. Bibcode:2017NatCo...815263D. doi:10.1038/ncomms15263. ISSN 2041-1723. PMC 5436104. PMID 28486437.
  50. ^ Marshall, Michael (April 2, 2013). "Meteorites could have been source of life's batteries". New Scientist. Retrieved 2022-11-01.
  51. Suda, Konomi; Ueno, Yuichiro; Yoshizaki, Motoko; Nakamura, Hitomi; Kurokawa, Ken; Nishiyama, Eri; Yoshino, Koji; Hongoh, Yuichi; Kawachi, Kenichi; Omori, Soichi; Yamada, Keita; Yoshida, Naohiro; Maruyama, Shigenori (2014-01-15). "Origin of methane in serpentinite-hosted hydrothermal systems: The CH4–H2–H2O hydrogen isotope systematics of the Hakuba Happo hot spring". Earth and Planetary Science Letters. 386: 112–125. Bibcode:2014E&PSL.386..112S. doi:10.1016/j.epsl.2013.11.001. ISSN 0012-821X.
  52. ^ Longo, Alex; Damer, Bruce (2020-04-27). "Factoring Origin of Life Hypotheses into the Search for Life in the Solar System and Beyond". Life. 10 (5): 52. Bibcode:2020Life...10...52L. doi:10.3390/life10050052. ISSN 2075-1729. PMC 7281141. PMID 32349245.
  53. Kitadai, Norio; Maruyama, Shigenori (2018-07-01). "Origins of building blocks of life: A review". Geoscience Frontiers. 9 (4): 1117–1153. Bibcode:2018GeoFr...9.1117K. doi:10.1016/j.gsf.2017.07.007. ISSN 1674-9871. S2CID 102659869.
  54. Pearce, Ben K. D.; Pudritz, Ralph E.; Semenov, Dmitry A.; Henning, Thomas K. (2017-10-24). "Origin of the RNA world: The fate of nucleobases in warm little ponds". Proceedings of the National Academy of Sciences. 114 (43): 11327–11332. arXiv:1710.00434. Bibcode:2017PNAS..11411327P. doi:10.1073/pnas.1710339114. ISSN 0027-8424. PMC 5664528. PMID 28973920.
  55. Chen, Irene A.; Szostak, Jack W. (2004-05-25). "Membrane growth can generate a transmembrane pH gradient in fatty acid vesicles". Proceedings of the National Academy of Sciences. 101 (21): 7965–7970. Bibcode:2004PNAS..101.7965C. doi:10.1073/pnas.0308045101. ISSN 0027-8424. PMC 419540. PMID 15148394.
  56. Milshteyn, Daniel; Cooper, George; Deamer, David (2019-08-28). "Chemiosmotic energy for primitive cellular life: Proton gradients are generated across lipid membranes by redox reactions coupled to meteoritic quinones". Scientific Reports. 9 (1): 12447. Bibcode:2019NatSR...912447M. doi:10.1038/s41598-019-48328-5. ISSN 2045-2322. PMC 6713726. PMID 31462644.
  57. Varma, Sreejith J.; Muchowska, Kamila B.; Chatelain, Paul; Moran, Joseph (April 23, 2018). "Native iron reduces CO2 to intermediates and end-products of the acetyl-CoA pathway". Nature Ecology & Evolution. 2 (6): 1019–1024. Bibcode:2018NatEE...2.1019V. doi:10.1038/s41559-018-0542-2. ISSN 2397-334X. PMC 5969571. PMID 29686234.
  58. Muchowska, Kamila B.; Varma, Sreejith J.; Chevallot-Beroux, Elodie; Lethuillier-Karl, Lucas; Li, Guang; Moran, Joseph (October 2, 2017). "Metals promote sequences of the reverse Krebs cycle". Nature Ecology & Evolution. 1 (11): 1716–1721. Bibcode:2017NatEE...1.1716M. doi:10.1038/s41559-017-0311-7. ISSN 2397-334X. PMC 5659384. PMID 28970480.
  59. van Tubergen, A (1 March 2002). "A brief history of spa therapy". Annals of the Rheumatic Diseases. 61 (3): 273–275. doi:10.1136/ard.61.3.273. PMC 1754027. PMID 11830439.
  60. Takeshita, Rafaela S. C.; Bercovitch, Fred B.; Kinoshita, Kodzue; Huffman, Michael A. (May 2018). "Beneficial effect of hot spring bathing on stress levels in Japanese macaques". Primates. 59 (3): 215–225. doi:10.1007/s10329-018-0655-x. PMID 29616368. S2CID 4568998.
  61. Serbulea, Mihaela; Payyappallimana, Unnikrishnan (November 2012). "Onsen (hot springs) in Japan—Transforming terrain into healing landscapes". Health & Place. 18 (6): 1366–1373. doi:10.1016/j.healthplace.2012.06.020. PMID 22878276.
  62. ^ van Tubergen 2002.
  63. "Safety". Yellowstone National Park. National Park Service. 8 June 2021. Retrieved 24 June 2021.
  64. Almasy, Steve (15 June 2017). "Man severely burned after falling into Yellowstone hot spring". CNN. Retrieved 24 June 2021.
  65. Andrews, Robin (30 December 2016). "This Is What Happens When You Fall Into One Of Yellowstone's Hot Springs". Forbes. Retrieved 24 June 2021.
  66. Naegleria at eMedicine
  67. Shinji Izumiyama; Kenji Yagita; Reiko Furushima-Shimogawara; Tokiko Asakura; Tatsuya Karasudani; Takuro Endo (July 2003). "Occurrence and Distribution of Naegleria Species in Thermal Waters in Japan". J Eukaryot Microbiol. 50: 514–5. doi:10.1111/j.1550-7408.2003.tb00614.x. PMID 14736147. S2CID 45052636.
  68. Yasuo Sugita; Teruhiko Fujii; Itsurou Hayashi; Takachika Aoki; Toshirou Yokoyama; Minoru Morimatsu; Toshihide Fukuma; Yoshiaki Takamiya (May 1999). "Primary amebic meningoencephalitis due to Naegleria fowleri: An autopsy case in Japan". Pathology International. 49 (5): 468–70. doi:10.1046/j.1440-1827.1999.00893.x. PMID 10417693. S2CID 21576553.
  69. CDC description of acanthamoeba
  70. Miyamoto H, Jitsurong S, Shiota R, Maruta K, Yoshida S, Yabuuchi E (1997). "Molecular determination of infection source of a sporadic Legionella pneumonia case associated with a hot spring bath". Microbiol. Immunol. 41 (3): 197–202. doi:10.1111/j.1348-0421.1997.tb01190.x. PMID 9130230. S2CID 25016946.
  71. Eiko Yabauuchi; Kunio Agata (2004). "An outbreak of legionellosis in a new facility of hot spring Bath in Hiuga City". Kansenshogaku Zasshi. 78 (2): 90–8. doi:10.11150/kansenshogakuzasshi1970.78.90. ISSN 0387-5911. PMID 15103899.
  72. Goodyear-Smith, Felicity; Schabetsberger, Robert (2021-09-17). "Gonococcus infection probably acquired from bathing in a natural thermal pool: a case report". Journal of Medical Case Reports. 15 (1): 458. doi:10.1186/s13256-021-03043-6. ISSN 1752-1947. PMC 8445652. PMID 34530901.
  73. Fahr-Becker, Gabriele (2001). Ryokan. Könemann. p. 24. ISBN 978-3-8290-4829-3.
  74. Cheung, Jeanne (16 February 2018). "A Guide to Japan's Onsen Etiquette for First Timers (Hint: You're Gonna be in the Buff)". Marriot Bonvoy Traveler. Marriot Internal Inc. Retrieved 2 July 2021.
  75. "Spa Etiquette & Information". One Spa. Retrieved 2 July 2021.
  76. "Nudity Spa Guide". Spa Finder. Blackhawk Network, Inc. 19 July 2016. Retrieved 2 July 2021.
  77. Welcome Argentina: Turismo en Argentina 2009
  78. Santaloia, F.; Zuffianò, L. E.; Palladino, G.; Limoni, P. P.; Liotta, D.; Minissale, A.; Brogi, A.; Polemio, M. (2016-11-01). "Coastal thermal springs in a foreland setting: The Santa Cesarea Terme system (Italy)". Geothermics. 64: 344–361. Bibcode:2016Geoth..64..344S. doi:10.1016/j.geothermics.2016.06.013. hdl:11586/167990. ISSN 0375-6505.
  79. Ravi Shanker; J.L. Thussu; J.M. Prasad (1987). "Geothermal studies at Tattapani hot spring area, Sarguja district, central India". Geothermics. 16 (1): 61–76. Bibcode:1987Geoth..16...61S. doi:10.1016/0375-6505(87)90079-4.
  80. D. Chandrasekharam; M.C. Antu (August 1995). "Geochemistry of Tattapani thermal springs, Himachal Pradesh, India—field and experimental investigations". Geothermics. 24 (4): 553–9. doi:10.1016/0375-6505(95)00005-B.
  81. Skok, J. R.; Mustard, J. F.; Ehlmann, B. L.; Milliken, R. E.; Murchie, S. L. (December 2010). "Silica deposits in the Nili Patera caldera on the Syrtis Major volcanic complex on Mars". Nature Geoscience. 3 (12): 838–841. Bibcode:2010NatGe...3..838S. doi:10.1038/ngeo990. ISSN 1752-0894.

Further reading

External links

Rivers, streams and springs
Rivers
(lists)
Streams
Springs
(list)
Sedimentary processes
and erosion
Fluvial landforms
Fluvial flow
Surface runoff
Floods and stormwater
Point source pollution
River measurement
and modelling
River engineering
River sports
Related
Categories: