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Toba catastrophe theory

January 01, 1970

The Toba eruption (sometimes called the Toba supereruption or the Youngest Toba eruption) was a supervolcano eruption that occurred about 74,000 years ago during the Late Pleistocene[1] at the site of present-day Lake Toba in Sumatra, Indonesia. It is one of the largest known explosive eruptions in the Earth's history. The Toba catastrophe theory is that this event caused a severe global volcanic winter of six to ten years and contributed to a 1,000-year-long cooling episode, resulting in a genetic bottleneck in humans.[2][3] However, some physical evidence disputes the association with the millennium-long cold event and genetic bottleneck, and some consider the theory disproven.[4][5][6][7][8]

Toba eruption theory
Artist's impression of the eruption from about 42 km (26 mi) above northern Sumatra
VolcanoToba Caldera Complex
Datec. 74,000 years BP
LocationSumatra, Indonesia
2°41′04″N 98°52′32″E / 2.6845°N 98.8756°E / 2.6845; 98.8756
VEI8
ImpactImpact disputed
Deaths(Potentially) almost all of humanity, leaving around 3,000–10,000 humans left on the planet
Lake Toba is the resulting crater lake

History edit

In 1972, an analysis of human hemoglobins found very few variants, and to account for the low frequency of variation human population must had been as low as a few thousand until very recently.[9] More genetic studies confirmed an effective population on the order of 10,000 for much of human history.[10][11] Subsequent research on the differences in human mitochondrial DNA sequences dated a rapid growth from a small effective population size of 1,000 to 10,000, sometime between 35,000 and 65,000 years ago.[12][13][14]

The large magnitude of the Toba eruption has been known since 1939, and various techniques dated the timing of the event to 73,000 to 75,000 years ago.[15] A study published in 1993 suggested that the eruption accelerated climate and environmental transition from the last interglacial period MIS-5 to the last glacial period MIS-4.[16]

In 1993, science journalist Ann Gibbons posited that population growth was suppressed by the cold climate of the last Pleistocene Ice Age, possibly exacerbated by the Toba eruption. The subsequent explosive human expansion was believed to be the result of the end of the ice age.[17] Geologist Michael R. Rampino of New York University and volcanologist Stephen Self of the University of Hawaiʻi at Mānoa supported her theory.[18] In 1998, anthropologist Stanley H. Ambrose of the University of Illinois Urbana-Champaign hypothesized that the Toba eruption caused a human population crash, and the low population size was sustained by the global glacial condition of MIS-4 until the climate eventually transitioned to the warmer condition of MIS-3 about 60,000 years ago, during which rapid human population expansion occurred.[2]

Toba eruption edit

See also: List of large volcanic eruptions

The most recent estimate of eruptive volume is 3,800 km3 (910 cu mi) dense-rock equivalent (DRE), of which 1,800 km3 (430 cu mi) was deposited as ash fall and 2,000 km3 (480 cu mi) as ignimbrite, making this eruption the largest during the Quaternary period.[19] Previous volume estimates have ranged from 2,000 km3 (480 cu mi)[15] to 6,000 km3 (1,400 cu mi).[20] Inside the caldera, the maximum thickness of pyroclastic flows is over 600 m (2,000 ft).[21] The outflow sheet originally covered an area of 20,000–30,000 km2 (7,700–11,600 sq mi) with thickness nearly 100 m (330 ft), likely reaching into the Indian Ocean and the Straits of Malacca.[22] The air-fall of this eruption blanketed Indian subcontinent in a layer of 5 cm (2.0 in) ash,[23] Arabian Sea in 1 mm (0.039 in),[24] South China Sea in 3.5 cm (1.4 in),[25] and Central Indian Ocean Basin in 10 cm (3.9 in).[26] Its horizon of ashfall covered an area of more than 38,000,000 km2 (15,000,000 sq mi) in 1 cm (0.39 in) or more thickness.[19] In Sub-Saharan Africa, microscopic glass shards from this eruption are also discovered on the south coast of South Africa,[27] in the lowlands of northwest Ethiopia,[28] in Lake Malawi,[29] and in Lake Chala.[30]

The most recent two high-precision argon–argon datings dated the eruption to 73,880 ± 320[31] and 73,700 ± 300 years ago.[32] Five distinct magma bodies were activated within a few centuries before the eruption.[33][34] The implied prevailing wind from the ash distribution is consistent with the eruption occurred during summer.[25] The eruption commenced with small and limited air-fall and was directly followed by the main phase of ignimbrite flows.[22] The ignimbrite phase is characterized by low eruption fountain,[35] but co-ignimbrite column developed on top of pyroclastic flows reached a height of 32 km (20 mi).[36] The entire eruption was likely continuous without major break and may have only lasted 9 to 14 days.[15] Petrological constrains on sulfur emission yielded a wide range from 1013 to 1015 g, depending on the existence of excess gas in the Toba magma chamber.[37][38]

Climatic effects edit

By analyzing climate proxies and simulating climate forcing, researchers can gain insights into the immediate climatic effects of the Toba eruption. However, there are limitations to both methods. In sedimentary records where the Toba tuff does not serve as a marker horizon, it cannot indicate the exact section that records the environmental conditions immediately after the eruption. Meanwhile, in sedimentary records that do have the Toba tuff as a marker horizon, the sedimentation rate may be too low to capture the short-term climatic effects of the eruption.[39][40] On the other hand, results of climate models entirely depend on the volatile budget of erupted magma, hence varies accordingly to the assumed volatile budget.

Climate proxy edit

The Toba tephra layer in marine sediments coincides with the δ18O MIS 5a to 4 boundary, marking a climatic transition from warm to cold caused by a change in ocean circulation and a drop in atmospheric CO2 concentration, also known as the Dansgaard-Oeschger event. Geologist Michael R. Rampino and volcanologist Stephen Self hypothesized that Toba eruption accelerated this shift.[16][41] Testing this hypothesis required higher resolution sedimentary records.

Two marine sediment cores Toba marker horizon retrieved[clarification needed] from the Northern Indian Ocean and the South China Sea either showed no pronounced cooling or a 0.8–1.0 °C (1.4–1.8 °F) cooling in the centuries following eruption.[42][43] The core resolution[clarification needed] was insufficient to ascertain that the cooling was caused by the Toba eruption since the two events could be decades or centuries apart in the core.[39] However, a severe cooling of only a few years is not expected to appear in these sediment records of centennial resolution.[43] Nonetheless, the marine sedimentary records indicate that Toba had only a minor effect on the time scales longer than a century.[43][39]

In Greenland ice cores, a large sulfate spike that appeared between Dansgaard–Oeschger event 19 and 20 was possibly related to Toba eruption. The δ18O values of the ice cores indicate a 1,000-year cooling event immediately following the sulfate signal.[44] However, high-resolution δ18O excluded the possibility of a more-than-a-century-long cooling impact of the eruption and ruled out that Toba triggered the cooling as it was already underway.[45][46]

Insufficient resolution in marine sediments bearing the Toba tuff has hindered the assessment of any short-term effects that may have lasted for less than a century.[47]

In 2013, a microscopic layer of Toba ash was reported in sediments of Lake Malawi. Together with the high sedimentation rate of the lake and Toba marker horizon, several team have reconstructed the local environment after Toba eruption at subdecadal resolution of ~6–9 years. The sediments in core display no clear evidence of cooling and no unusual deviations in concentrations of climate-sensitive ecological indicators. These results imply that the duration of the Toba cooling must have been either briefer than the sampling resolution of ~6–9 years or too small in magnitude in East Africa.[5][47][48][49]

Climate modeling edit

The mass of sulfurous gases emitted during Toba eruption is a crucial parameter when modeling its climatic effects.

Assuming an emission of 1.7 billion tonnes (1.9 billion short tons) of sulphur dioxide, which is 100 times the 1991 Pinatubo sulphur, the modeled volcanic winter has maximum global mean cooling of −3.5 °C (−6.3 °F) and returns gradually within the range of natural variability 5 years after the eruption. An initiation of 1,000-year cold period or ice age is not indicated by the model.[50][51]

In a 2021 study, two other emission scenarios, 0.2 billion tonnes (0.22 billion short tons) and 2 billion tonnes (2.2 billion short tons) of sulphur dioxide which are 10 and 100 times of Pinatubo respectively, are investigated using state-of-art simulations provided by the Community Earth System Model. Maximum global mean cooling is −2.3 °C (−4.1 °F) for a 0.2 billion tonnes SO2 release and −4.1 °C (−7.4 °F) for a 2 billion tonnes SO2 release. Negative temperature anomalies return to less than −1 °C (−1.8 °F) within 3 and 6 years for each emission scenario after the eruption.[52]

Petrological studies of Toba magma constrained that the mass of sulfuric acid aerosols from Toba eruption represents about 2–5 times the sulfuric acid aerosols generated during 1991 Pinatubo eruption.[37][53] The studies suggest that previous modelings of global temperature perturbations after the Toba eruption were excessive.[37] Ice core records of atmospheric sulfur injection during the period during which the Toba eruption occurred contain three large injections that are 10–30 times the Pinatubo sulfur.[46]

Genetic bottleneck hypothesis edit

Genetic bottleneck in humans edit

The Toba eruption has been associated with a genetic bottleneck in human evolution about 70,000 years ago;[54][55] it is hypothesized that the eruption resulted in a severe reduction in the size of the total human population due to the effects of the eruption on the global climate.[56] According to the genetic bottleneck theory, between 50,000 and 100,000 years ago, human populations decreased to 3,000–10,000 surviving individuals.[57][58] It is supported by some genetic evidence suggesting that modern humans are descended from a very small population of between 1,000 and 10,000 breeding pairs that existed about 70,000 years ago.[59][60]

Proponents of the genetic bottleneck theory (including Robock) suggest that the Toba eruption resulted in a global ecological disaster, including destruction of vegetation along with severe drought in the tropical rainforest belt and in monsoonal regions. A 10-year volcanic winter triggered by the eruption could have largely destroyed the food sources of humans and caused a severe reduction in population sizes.[61] These environmental changes may have generated population bottlenecks in many species, including hominids;[62] this in turn may have accelerated differentiation from within the smaller human population. Therefore, the genetic differences among modern humans may represent changes within the last 70,000 years, rather than gradual differentiation over hundreds of thousands of years.[63]

Other research has cast doubt on an association between the Toba Caldera Complex and a genetic bottleneck. For example, ancient stone tools at the Jurreru Valley in southern India were found above and below a thick layer of ash from the Toba eruption and were very similar across these layers, suggesting that the dust clouds from the eruption did not wipe out this local population.[64][65][66] However, another site in India, the Middle Son Valley, exhibits evidence of a major population decline and it has been suggested that the abundant springs of the Jurreru Valley may have offered its inhabitants unique protection.[67] Additional archaeological evidence from southern and northern India also suggests a lack of evidence for effects of the eruption on local populations, causing the authors of the study to conclude, "many forms of life survived the supereruption, contrary to other research which has suggested significant animal extinctions and genetic bottlenecks".[68] However, some researchers have questioned the techniques utilized to date artifacts to the period subsequent to the Toba supervolcano.[69] The Toba Catastrophe also coincides with the disappearance of the Skhul and Qafzeh hominins.[70] Evidence from pollen analysis has suggested prolonged deforestation in South Asia, and some researchers have suggested that the Toba eruption may have forced humans to adopt new adaptive strategies, which may have permitted them to replace Neanderthals and "other archaic human species".[71][72]

Additional caveats include difficulties in estimating the global and regional climatic effects of the eruption and lack of conclusive evidence for the eruption preceding the crash.[73] Furthermore, genetic analysis of Alu sequences across the entire human genome has shown that the effective human population size was less than 26,000 at 1.2 million years ago; possible explanations for the low population size of human ancestors may include repeated population crashes or periodic replacement events from competing Homo subspecies. (If these results are accurate, then, even before the emergence of Homo sapiens in Africa, Homo erectus population was unusually small when the species was spreading around the world.)[74]

Genetic bottlenecks in other mammals edit

Some evidence indicates population crashes of other animals after the Toba eruption. The populations of the Eastern African chimpanzee,[75] Bornean orangutan,[76] central Indian macaque,[77] cheetah and tiger,[78] all recovered from very small populations around 70,000–55,000 years ago.

Migration after Toba edit

The exact geographic distribution of anatomically modern human populations at the time of the eruption is not known, and surviving populations may have lived in Africa and subsequently migrated to other parts of the world. Analyses of mitochondrial DNA have estimated that the major migration from Africa occurred 60,000–70,000 years ago,[79] consistent with dating of the Toba eruption to about 75,000 years ago.[citation needed]

See also edit

Citations and notes edit

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  54. ^ Gibbons 1993, p. 27
  55. ^ Rampino & Self 1993a
  56. ^ Ambrose 1998, passim; Gibbons 1993, p. 27; McGuire 2007, pp. 127–128; Rampino & Ambrose 2000, pp. 78–80; Rampino & Self 1993b, pp. 1955.
  57. ^ Ambrose 1998; Rampino & Ambrose 2000, pp. 71, 80.
  58. ^ "Science & Nature – Horizon – Supervolcanoes". BBC.co.uk. Retrieved 2015-03-28.
  59. ^ "When humans faced extinction". BBC. 2003-06-09. Retrieved 2007-01-05.
  60. ^ M.R Rampino and S.Self, Nature 359, 50 (1992)
  61. ^ Robock & others 2009.
  62. ^ Rampino & Ambrose 2000, p. 80.
  63. ^ Ambrose 1998, pp. 623–651.
  64. ^ . Anthropology.net. 6 July 2007. Archived from the original on 2008-01-11. Retrieved 2008-04-20.
  65. ^ Sanderson, Katherine (July 2007). "Super-eruption: no problem?". Nature: news070702–15. doi:10.1038/news070702-15. S2CID 177216526. from the original on December 7, 2008.
  66. ^ John Hawks (5 July 2007). "At last, the death of the Toba bottleneck". john hawks weblog.
  67. ^ Jones, Sacha. (2012). Local- and Regional-scale Impacts of the ~74 ka Toba Supervolcanic Eruption on Hominin Population and Habitats in India. Quaternary International 258: 100-118.
  68. ^ See also . Anthropology.net. 25 February 2010. Archived from the original on 22 July 2011. Retrieved 28 February 2010.
  69. ^ National Geographic- Did early humans in India survive a supervolcano?
  70. ^ Shea, John. (2008). Transitions or Turnovers? Climatically-forced Extinctions of Homo sapiens and Neanderthals in the East Mediterranean Levant. Quaternary Science Reviews 27: 2253-2270.
  71. ^ "Supervolcano Eruption In Sumatra Deforested India 73,000 Years ago". ScienceDaily. 24 November 2009.
  72. ^ Williams & others 2009.
  73. ^ Oppenheimer 2002, pp. 1605, 1606.
  74. ^ See Huff & others 2010, p.6; Gibbons 2010.
  75. ^ Goldberg 1996
  76. ^ Steiper 2006
  77. ^ Hernandez & others 2007
  78. ^ Luo & others 2004
  79. ^ "New 'Molecular Clock' Aids Dating Of Human Migration History". ScienceDaily. 22 June 2009. Retrieved 2009-06-30.

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Further reading edit

External links edit

  • Population Bottlenecks and Volcanic Winter
  • . Archived from the original on April 22, 2011. Retrieved June 1, 2006.
  • "The proper study of mankind" – Article in The Economist
  • Homepage of Professor Stanley H. Ambrose, including bibliographic information on the two papers he has published on the Toba catastrophe theory
  • Mount Toba: Late Pleistocene human population bottlenecks, volcanic winter, and differentiation of modern humans by Professor Stanley H. Ambrose, Department of Anthropology, University Of Illinois, Urbana, USA; Extract from "Journal of Human Evolution" [1998] 34, 623–651
  • Journey of Mankind by The Bradshaw Foundation – includes discussion on Toba eruption, DNA and human migrations
  • Geography Predicts Human Genetic Diversity ScienceDaily (Mar. 17, 2005) – By analyzing the relationship between the geographic location of current human populations in relation to East Africa and the genetic variability within these populations, researchers have found new evidence for an African origin of modern humans.
  • Out of Africa – Bacteria, As Well: Homo Sapiens And H. Pylori Jointly Spread Across The Globe ScienceDaily (Feb. 16, 2007) – When man made his way out of Africa some 60,000 years ago to populate the world, he was not alone: He was accompanied by the bacterium Helicobacter pylori...; illus. migration map.
  • Magma 'Pancakes' May Have Fueled Toba Supervolcano
  • Youtube video "Stone Age Apocalypse"

January 01, 1970
toba, catastrophe, theory, toba, eruption, sometimes, called, toba, supereruption, youngest, toba, eruption, supervolcano, eruption, that, occurred, about, years, during, late, pleistocene, site, present, lake, toba, sumatra, indonesia, largest, known, explosi. The Toba eruption sometimes called the Toba supereruption or the Youngest Toba eruption was a supervolcano eruption that occurred about 74 000 years ago during the Late Pleistocene 1 at the site of present day Lake Toba in Sumatra Indonesia It is one of the largest known explosive eruptions in the Earth s history The Toba catastrophe theory is that this event caused a severe global volcanic winter of six to ten years and contributed to a 1 000 year long cooling episode resulting in a genetic bottleneck in humans 2 3 However some physical evidence disputes the association with the millennium long cold event and genetic bottleneck and some consider the theory disproven 4 5 6 7 8 Toba eruption theoryArtist s impression of the eruption from about 42 km 26 mi above northern SumatraVolcanoToba Caldera ComplexDatec 74 000 years BPLocationSumatra Indonesia2 41 04 N 98 52 32 E 2 6845 N 98 8756 E 2 6845 98 8756VEI8ImpactImpact disputedDeaths Potentially almost all of humanity leaving around 3 000 10 000 humans left on the planetLake Toba is the resulting crater lake Contents 1 History 2 Toba eruption 3 Climatic effects 3 1 Climate proxy 3 2 Climate modeling 4 Genetic bottleneck hypothesis 4 1 Genetic bottleneck in humans 4 2 Genetic bottlenecks in other mammals 5 Migration after Toba 6 See also 7 Citations and notes 8 References 9 Further reading 10 External linksHistory editIn 1972 an analysis of human hemoglobins found very few variants and to account for the low frequency of variation human population must had been as low as a few thousand until very recently 9 More genetic studies confirmed an effective population on the order of 10 000 for much of human history 10 11 Subsequent research on the differences in human mitochondrial DNA sequences dated a rapid growth from a small effective population size of 1 000 to 10 000 sometime between 35 000 and 65 000 years ago 12 13 14 The large magnitude of the Toba eruption has been known since 1939 and various techniques dated the timing of the event to 73 000 to 75 000 years ago 15 A study published in 1993 suggested that the eruption accelerated climate and environmental transition from the last interglacial period MIS 5 to the last glacial period MIS 4 16 In 1993 science journalist Ann Gibbons posited that population growth was suppressed by the cold climate of the last Pleistocene Ice Age possibly exacerbated by the Toba eruption The subsequent explosive human expansion was believed to be the result of the end of the ice age 17 Geologist Michael R Rampino of New York University and volcanologist Stephen Self of the University of Hawaiʻi at Manoa supported her theory 18 In 1998 anthropologist Stanley H Ambrose of the University of Illinois Urbana Champaign hypothesized that the Toba eruption caused a human population crash and the low population size was sustained by the global glacial condition of MIS 4 until the climate eventually transitioned to the warmer condition of MIS 3 about 60 000 years ago during which rapid human population expansion occurred 2 Toba eruption editSee also List of large volcanic eruptions The most recent estimate of eruptive volume is 3 800 km3 910 cu mi dense rock equivalent DRE of which 1 800 km3 430 cu mi was deposited as ash fall and 2 000 km3 480 cu mi as ignimbrite making this eruption the largest during the Quaternary period 19 Previous volume estimates have ranged from 2 000 km3 480 cu mi 15 to 6 000 km3 1 400 cu mi 20 Inside the caldera the maximum thickness of pyroclastic flows is over 600 m 2 000 ft 21 The outflow sheet originally covered an area of 20 000 30 000 km2 7 700 11 600 sq mi with thickness nearly 100 m 330 ft likely reaching into the Indian Ocean and the Straits of Malacca 22 The air fall of this eruption blanketed Indian subcontinent in a layer of 5 cm 2 0 in ash 23 Arabian Sea in 1 mm 0 039 in 24 South China Sea in 3 5 cm 1 4 in 25 and Central Indian Ocean Basin in 10 cm 3 9 in 26 Its horizon of ashfall covered an area of more than 38 000 000 km2 15 000 000 sq mi in 1 cm 0 39 in or more thickness 19 In Sub Saharan Africa microscopic glass shards from this eruption are also discovered on the south coast of South Africa 27 in the lowlands of northwest Ethiopia 28 in Lake Malawi 29 and in Lake Chala 30 The most recent two high precision argon argon datings dated the eruption to 73 880 320 31 and 73 700 300 years ago 32 Five distinct magma bodies were activated within a few centuries before the eruption 33 34 The implied prevailing wind from the ash distribution is consistent with the eruption occurred during summer 25 The eruption commenced with small and limited air fall and was directly followed by the main phase of ignimbrite flows 22 The ignimbrite phase is characterized by low eruption fountain 35 but co ignimbrite column developed on top of pyroclastic flows reached a height of 32 km 20 mi 36 The entire eruption was likely continuous without major break and may have only lasted 9 to 14 days 15 Petrological constrains on sulfur emission yielded a wide range from 1013 to 1015 g depending on the existence of excess gas in the Toba magma chamber 37 38 Climatic effects editBy analyzing climate proxies and simulating climate forcing researchers can gain insights into the immediate climatic effects of the Toba eruption However there are limitations to both methods In sedimentary records where the Toba tuff does not serve as a marker horizon it cannot indicate the exact section that records the environmental conditions immediately after the eruption Meanwhile in sedimentary records that do have the Toba tuff as a marker horizon the sedimentation rate may be too low to capture the short term climatic effects of the eruption 39 40 On the other hand results of climate models entirely depend on the volatile budget of erupted magma hence varies accordingly to the assumed volatile budget Climate proxy edit The Toba tephra layer in marine sediments coincides with the d18O MIS 5a to 4 boundary marking a climatic transition from warm to cold caused by a change in ocean circulation and a drop in atmospheric CO2 concentration also known as the Dansgaard Oeschger event Geologist Michael R Rampino and volcanologist Stephen Self hypothesized that Toba eruption accelerated this shift 16 41 Testing this hypothesis required higher resolution sedimentary records Two marine sediment cores Toba marker horizon retrieved clarification needed from the Northern Indian Ocean and the South China Sea either showed no pronounced cooling or a 0 8 1 0 C 1 4 1 8 F cooling in the centuries following eruption 42 43 The core resolution clarification needed was insufficient to ascertain that the cooling was caused by the Toba eruption since the two events could be decades or centuries apart in the core 39 However a severe cooling of only a few years is not expected to appear in these sediment records of centennial resolution 43 Nonetheless the marine sedimentary records indicate that Toba had only a minor effect on the time scales longer than a century 43 39 In Greenland ice cores a large sulfate spike that appeared between Dansgaard Oeschger event 19 and 20 was possibly related to Toba eruption The d18O values of the ice cores indicate a 1 000 year cooling event immediately following the sulfate signal 44 However high resolution d18O excluded the possibility of a more than a century long cooling impact of the eruption and ruled out that Toba triggered the cooling as it was already underway 45 46 Insufficient resolution in marine sediments bearing the Toba tuff has hindered the assessment of any short term effects that may have lasted for less than a century 47 In 2013 a microscopic layer of Toba ash was reported in sediments of Lake Malawi Together with the high sedimentation rate of the lake and Toba marker horizon several team have reconstructed the local environment after Toba eruption at subdecadal resolution of 6 9 years The sediments in core display no clear evidence of cooling and no unusual deviations in concentrations of climate sensitive ecological indicators These results imply that the duration of the Toba cooling must have been either briefer than the sampling resolution of 6 9 years or too small in magnitude in East Africa 5 47 48 49 Climate modeling edit The mass of sulfurous gases emitted during Toba eruption is a crucial parameter when modeling its climatic effects Assuming an emission of 1 7 billion tonnes 1 9 billion short tons of sulphur dioxide which is 100 times the 1991 Pinatubo sulphur the modeled volcanic winter has maximum global mean cooling of 3 5 C 6 3 F and returns gradually within the range of natural variability 5 years after the eruption An initiation of 1 000 year cold period or ice age is not indicated by the model 50 51 In a 2021 study two other emission scenarios 0 2 billion tonnes 0 22 billion short tons and 2 billion tonnes 2 2 billion short tons of sulphur dioxide which are 10 and 100 times of Pinatubo respectively are investigated using state of art simulations provided by the Community Earth System Model Maximum global mean cooling is 2 3 C 4 1 F for a 0 2 billion tonnes SO2 release and 4 1 C 7 4 F for a 2 billion tonnes SO2 release Negative temperature anomalies return to less than 1 C 1 8 F within 3 and 6 years for each emission scenario after the eruption 52 Petrological studies of Toba magma constrained that the mass of sulfuric acid aerosols from Toba eruption represents about 2 5 times the sulfuric acid aerosols generated during 1991 Pinatubo eruption 37 53 The studies suggest that previous modelings of global temperature perturbations after the Toba eruption were excessive 37 Ice core records of atmospheric sulfur injection during the period during which the Toba eruption occurred contain three large injections that are 10 30 times the Pinatubo sulfur 46 Genetic bottleneck hypothesis editGenetic bottleneck in humans edit The Toba eruption has been associated with a genetic bottleneck in human evolution about 70 000 years ago 54 55 it is hypothesized that the eruption resulted in a severe reduction in the size of the total human population due to the effects of the eruption on the global climate 56 According to the genetic bottleneck theory between 50 000 and 100 000 years ago human populations decreased to 3 000 10 000 surviving individuals 57 58 It is supported by some genetic evidence suggesting that modern humans are descended from a very small population of between 1 000 and 10 000 breeding pairs that existed about 70 000 years ago 59 60 Proponents of the genetic bottleneck theory including Robock suggest that the Toba eruption resulted in a global ecological disaster including destruction of vegetation along with severe drought in the tropical rainforest belt and in monsoonal regions A 10 year volcanic winter triggered by the eruption could have largely destroyed the food sources of humans and caused a severe reduction in population sizes 61 These environmental changes may have generated population bottlenecks in many species including hominids 62 this in turn may have accelerated differentiation from within the smaller human population Therefore the genetic differences among modern humans may represent changes within the last 70 000 years rather than gradual differentiation over hundreds of thousands of years 63 Other research has cast doubt on an association between the Toba Caldera Complex and a genetic bottleneck For example ancient stone tools at the Jurreru Valley in southern India were found above and below a thick layer of ash from the Toba eruption and were very similar across these layers suggesting that the dust clouds from the eruption did not wipe out this local population 64 65 66 However another site in India the Middle Son Valley exhibits evidence of a major population decline and it has been suggested that the abundant springs of the Jurreru Valley may have offered its inhabitants unique protection 67 Additional archaeological evidence from southern and northern India also suggests a lack of evidence for effects of the eruption on local populations causing the authors of the study to conclude many forms of life survived the supereruption contrary to other research which has suggested significant animal extinctions and genetic bottlenecks 68 However some researchers have questioned the techniques utilized to date artifacts to the period subsequent to the Toba supervolcano 69 The Toba Catastrophe also coincides with the disappearance of the Skhul and Qafzeh hominins 70 Evidence from pollen analysis has suggested prolonged deforestation in South Asia and some researchers have suggested that the Toba eruption may have forced humans to adopt new adaptive strategies which may have permitted them to replace Neanderthals and other archaic human species 71 72 Additional caveats include difficulties in estimating the global and regional climatic effects of the eruption and lack of conclusive evidence for the eruption preceding the crash 73 Furthermore genetic analysis of Alu sequences across the entire human genome has shown that the effective human population size was less than 26 000 at 1 2 million years ago possible explanations for the low population size of human ancestors may include repeated population crashes or periodic replacement events from competing Homo subspecies If these results are accurate then even before the emergence of Homo sapiens in Africa Homo erectus population was unusually small when the species was spreading around the world 74 Genetic bottlenecks in other mammals edit Some evidence indicates population crashes of other animals after the Toba eruption The populations of the Eastern African chimpanzee 75 Bornean orangutan 76 central Indian macaque 77 cheetah and tiger 78 all recovered from very small populations around 70 000 55 000 years ago Migration after Toba editThe exact geographic distribution of anatomically modern human populations at the time of the eruption is not known and surviving populations may have lived in Africa and subsequently migrated to other parts of the world Analyses of mitochondrial DNA have estimated that the major migration from Africa occurred 60 000 70 000 years ago 79 consistent with dating of the Toba eruption to about 75 000 years ago citation needed See also edit nbsp Volcanoes portal nbsp Evolutionary biology portal Early human migrations Spread of humans from Africa through the world Most recent common ancestor Most recent individual from which all organisms in a group are directly descended Quaternary extinction event Extinctions of large mammals in the Late PleistocenePages displaying short descriptions of redirect targets Recent African origin of modern humans Out of Africa theory of the early migration of humans Timeline of volcanism on Earth Wallace Line Line separating Asian and Australian faunaCitations and notes edit Surprisingly Humanity Survived the Super volcano 74 000 Years Ago Haaretz a b Ambrose 1998 Michael R Rampino Stanley H Ambrose 2000 Volcanic winter in the Garden of Eden The Toba supereruption and the late Pleistocene human population crash Volcanic Hazards and Disasters in Human Antiquity Floyd W McCoy Grant Heiken Toba super volcano catastrophe idea dismissed BBC News 30 April 2013 Retrieved 2017 01 08 Choi Charles Q 2013 04 29 Toba Supervolcano Not to Blame for Humanity s Near Extinction Livescience com Retrieved 2017 01 08 a b Yost Chad et al March 2018 Subdecadal phytolith and charcoal records from Lake Malawi East Africa imply minimal effects on human evolution from the 74 ka Toba supereruption Journal of Human Evolution 116 Elsevier 75 94 doi 10 1016 j jhevol 2017 11 005 PMID 29477183 Ge Yong Gao Xing 2020 09 10 Understanding the overestimated impact of the Toba volcanic super eruption on global environments and ancient hominins Quaternary International Current Research on Prehistoric Central Asia 559 24 33 Bibcode 2020QuInt 559 24G doi 10 1016 j 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supereruption in Lake Malawi shows no volcanic winter in East Africa at 75 ka Proceedings of the National Academy of Sciences 110 20 8025 8029 Bibcode 2013PNAS 110 8025L doi 10 1073 pnas 1301474110 PMC 3657767 PMID 23630269 Baxter A J Verschuren D Peterse F Miralles D G Martin Jones C M Maitituerdi A Van der Meeren T Van Daele M Lane C S Haug G H Olago D O Sinninghe Damste J S 2023 Reversed Holocene temperature moisture relationship in the Horn of Africa Nature 620 7973 336 343 doi 10 1038 s41586 023 06272 5 hdl 1854 LU 01HF6GN7WZQ65R3C82NK0HC57E ISSN 1476 4687 Storey Michael Roberts Richard G Saidin Mokhtar 2012 11 13 Astronomically calibrated 40 Ar 39 Ar age for the Toba supereruption and global synchronization of late Quaternary records Proceedings of the National Academy of Sciences 109 46 18684 18688 Bibcode 2012PNAS 10918684S doi 10 1073 pnas 1208178109 ISSN 0027 8424 PMC 3503200 PMID 23112159 Channell J E T Hodell D A 2017 High precision 40Ar 39Ar dating of Pleistocene tuffs and 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71 80 Science amp Nature Horizon Supervolcanoes BBC co uk Retrieved 2015 03 28 When humans faced extinction BBC 2003 06 09 Retrieved 2007 01 05 M R Rampino and S Self Nature 359 50 1992 Robock amp others 2009 Rampino amp Ambrose 2000 p 80 Ambrose 1998 pp 623 651 Mount Toba Eruption Ancient Humans Unscathed Study Claims Anthropology net 6 July 2007 Archived from the original on 2008 01 11 Retrieved 2008 04 20 Sanderson Katherine July 2007 Super eruption no problem Nature news070702 15 doi 10 1038 news070702 15 S2CID 177216526 Archived from the original on December 7 2008 John Hawks 5 July 2007 At last the death of the Toba bottleneck john hawks weblog Jones Sacha 2012 Local and Regional scale Impacts of the 74 ka Toba Supervolcanic Eruption on Hominin Population and Habitats in India Quaternary International 258 100 118 See also Newly Discovered Archaeological Sites in India Reveals Ancient Life before Toba Anthropology net 25 February 2010 Archived from the original on 22 July 2011 Retrieved 28 February 2010 National Geographic Did early humans in India survive a supervolcano Shea John 2008 Transitions or Turnovers Climatically forced Extinctions of Homo sapiens and Neanderthals in the East Mediterranean Levant Quaternary Science Reviews 27 2253 2270 Supervolcano Eruption In Sumatra Deforested India 73 000 Years ago ScienceDaily 24 November 2009 Williams amp others 2009 Oppenheimer 2002 pp 1605 1606 See Huff amp others 2010 p 6 Gibbons 2010 Goldberg 1996 Steiper 2006 Hernandez amp others 2007 Luo amp others 2004 New Molecular Clock Aids Dating Of Human Migration History ScienceDaily 22 June 2009 Retrieved 2009 06 30 References editAmbrose Stanley H 1998 Late Pleistocene human population bottlenecks volcanic winter and differentiation of modern humans Journal of Human Evolution 34 6 623 651 doi 10 1006 jhev 1998 0219 PMID 9650103 Chesner C A Westgate J A Rose W I Drake R Deino A March 1991 Eruptive History of Earth s Largest Quaternary caldera Toba Indonesia Clarified PDF Geology 19 3 200 203 Bibcode 1991Geo 19 200C doi 10 1130 0091 7613 1991 019 lt 0200 EHOESL gt 2 3 CO 2 Gibbons Ann 1 October 1993 Pleistocene Population Explosions Science 262 5130 27 28 Bibcode 1993Sci 262 27G doi 10 1126 science 262 5130 27 PMID 17742951 Gibbons Ann 19 January 2010 Human Ancestors Were an Endangered Species ScienceNow Goldberg T L 1996 Genetics and biogeography of East African chimpanzees Pan troglodytes schweinfurthii PhD Harvard University unpublished Hernandez R D Hubisz M J Wheeler D A Smith D G Ferguson B et al 2007 Demographic histories and patterns of linkage disequilibrium in Chinese and Indian Rhesus macaques Science 316 5822 240 243 Bibcode 2007Sci 316 240H doi 10 1126 science 1140462 PMID 17431170 Huff Chad D Xing Jinchuan Rogers Alan R Witherspoon David Jorde Lynn B 19 January 2010 Mobile Elements Reveal Small Population Size in the Ancient Ancestors of Homo Sapiens Proceedings of the National Academy of Sciences 107 5 2147 2152 Bibcode 2010PNAS 107 2147H doi 10 1073 pnas 0909000107 PMC 2836654 PMID 20133859 Jones S C 2007 The Toba Supervolcanic Eruption Tephra Fall Deposits in India and Paleoanthropological Implications In Petraglia M D Allchin B eds The Evolution and History of Human Populations in South Asia Springer pp 173 200 ISBN 978 1 4020 5561 4 Luo S J Kim J H Johnson W E Van der Walt J Martenson J et al 2004 Phylogeography and genetic ancestry of tigers Panthera tigris PLOS Biology 2 12 2275 2293 doi 10 1371 journal pbio 0020442 PMC 534810 PMID 15583716 Luo Shu Jin Zhang Yue Johnson Warren E Miao Lin Martelli Paolo et al 2014 Sympatric Asian felid phylogeography reveals a major Indochinese Sundaic divergence Molecular Ecology 23 8 2072 2092 Bibcode 2014MolEc 23 2072L doi 10 1111 mec 12716 ISSN 0962 1083 PMID 24629132 S2CID 40030155 McGuire W J 2007 The GGE Threat Facing and Coping with Global Geophysical Events In Bobrowsky Peter T Rickman Hans eds Comet Asteroid Impacts and Human Society an Interdisciplinary Approach Springer pp 123 141 Bibcode 2007caih book B ISBN 978 3 540 32709 7 Ninkovich D N J Shackleton A A Abdel Monem J D Obradovich G Izett 7 December 1978 K Ar age of the late Pleistocene eruption of Toba north Sumatra Nature 276 5688 574 577 Bibcode 1978Natur 276 574N doi 10 1038 276574a0 S2CID 4364788 Oppenheimer Clive August 2002 Limited global change due to largest known Quaternary eruption Toba 74 kyr BP Quaternary Science Reviews 21 14 15 1593 1609 Bibcode 2002QSRv 21 1593O doi 10 1016 S0277 3791 01 00154 8 Petraglia M Korisettar R Boivin N Clarkson C Ditchfield P et al 6 July 2007 Middle Paleolithic Assemblages from the Indian Subcontinent Before and After the Toba Super eruption PDF Science 317 5834 114 116 Bibcode 2007Sci 317 114P doi 10 1126 science 1141564 PMID 17615356 S2CID 20380351 Rampino M R Ambrose S H 2000 Volcanic winter in the Garden of Eden The Toba supereruption and the late Pleistocene human population crash In McCoy F W Heiken G eds Volcanic Hazards and Disasters in Human Antiquity Boulder Colorado Geological Society of America Special Paper 345 doi 10 1130 0 8137 2345 0 71 ISBN 0 8137 2345 0 Rampino Michael R Self Stephen 2 September 1992 Volcanic Winter and Accelerated Glaciation following the Toba Super eruption PDF Nature 359 6390 50 52 Bibcode 1992Natur 359 50R doi 10 1038 359050a0 S2CID 4322781 Archived from the original PDF on 20 October 2011 Rampino Michael R Self Stephen 1993 Climate Volcanism Feedback and the Toba Eruption of 74 000 Years ago PDF Quaternary Research 40 3 269 280 Bibcode 1993QuRes 40 269R doi 10 1006 qres 1993 1081 S2CID 129546088 Archived from the original PDF on 2011 10 21 Rampino Michael R Self Stephen 24 December 1993 Bottleneck in the Human Evolution and the Toba Eruption Science 262 5142 1955 Bibcode 1993Sci 262 1955R doi 10 1126 science 8266085 PMID 8266085 Robock A Ammann C M Oman L Shindell D Levis S Stenchikov G 2009 Did the Toba Volcanic Eruption of 74k BP Produce Widespread Glaciation Journal of Geophysical Research 114 D10 D10107 Bibcode 2009JGRD 11410107R doi 10 1029 2008JD011652 Rose W I Chesner C A October 1987 Dispersal of Ash in the Great Toba Eruption 75 ka PDF Geology 15 10 913 917 Bibcode 1987Geo 15 913R doi 10 1130 0091 7613 1987 15 lt 913 DOAITG gt 2 0 CO 2 Self Stephen Blake Stephen February 2008 Consequences of Explosive Supereruptions Elements 4 1 41 46 Bibcode 2008Eleme 4 41S doi 10 2113 GSELEMENTS 4 1 41 Steiper M E 2006 Population history biogeography and taxonomy of orangutans Genus Pongo based on a population genetic meta analysis of multiple loci Journal of Human Evolution 50 5 509 522 doi 10 1016 j jhevol 2005 12 005 PMID 16472840 Thalman O Fisher A Lankester F Paabo S Vigilant L 2007 The complex history of gorillas insights from genomic data Molecular Biology and Evolution 24 146 158 doi 10 1093 molbev msl160 PMID 17065595 Williams Martin A J Stanley H Ambrose Sander van der Kaars Carsten Ruehlemann Umesh Chattopadhyaya Jagannath Pal Parth R Chauhan 30 December 2009 Environmental impact of the 73 ka Toba super eruption in South Asia Palaeogeography Palaeoclimatology Palaeoecology 284 3 4 Elsevier 295 314 Bibcode 2009PPP 284 295W doi 10 1016 j palaeo 2009 10 009 Zielinski G A Mayewski P A Meeker L D Whitlow S Twickler M S Taylor K 1996 Potential Atmospheric Impact of the Toba Mega Eruption 71 000 years ago PDF Geophysical Research Letters 23 8 837 840 Bibcode 1996GeoRL 23 837Z doi 10 1029 96GL00706 Archived from the original PDF on July 18 2011 Further reading editProthero Donald R 2018 When Humans Nearly Vanished The Catastrophic Explosion of the Toba Volcano Washington Smithsonian Books ISBN 978 1588346353 OCLC 1020313538 External links editPopulation Bottlenecks and Volcanic Winter Toba Volcano by George Weber Archived from the original on April 22 2011 Retrieved June 1 2006 The proper study of mankind Article in The Economist Homepage of Professor Stanley H Ambrose including bibliographic information on the two papers he has published on the Toba catastrophe theory Mount Toba Late Pleistocene human population bottlenecks volcanic winter and differentiation of modern humans by Professor Stanley H Ambrose Department of Anthropology University Of Illinois Urbana USA Extract from Journal of Human Evolution 1998 34 623 651 Journey of Mankind by The Bradshaw Foundation includes discussion on Toba eruption DNA and human migrations Geography Predicts Human Genetic Diversity ScienceDaily Mar 17 2005 By analyzing the relationship between the geographic location of current human populations in relation to East Africa and the genetic variability within these populations researchers have found new evidence for an African origin of modern humans Out of Africa Bacteria As Well Homo Sapiens And H Pylori Jointly Spread Across The Globe ScienceDaily Feb 16 2007 When man made his way out of Africa some 60 000 years ago to populate the world he was not alone He was accompanied by the bacterium Helicobacter pylori illus migration map Magma Pancakes May Have Fueled Toba Supervolcano Youtube video Stone Age Apocalypse Retrieved from https en wikipedia org w index php title Toba catastrophe theory amp oldid 1221323550, wikipedia, wiki, book, books, library,

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