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Eemian

February 16, 2024

The Eemian (also called the last interglacial,[1] Sangamonian Stage, Ipswichian, Mikulin, Kaydaky, penultimate interglacial,[2] Valdivia or Riss-Würm) was the interglacial period which began about 130,000 years ago at the end of the Penultimate Glacial Period and ended about 115,000 years ago at the beginning of the Last Glacial Period.[3] It corresponds to Marine Isotope Stage 5e.[4] Although sometimes referred to as the "last interglacial" (in the "most recent previous" sense of "last"), it was the second-to-latest interglacial period of the current Ice Age, the most recent being the Holocene which extends to the present day (having followed the last glacial period). The prevailing Eemian climate was, on average, around 1 to 2 degrees Celsius (1.8 to 3.6 Fahrenheit) warmer than that of the Holocene.[5] During the Eemian, the proportion of CO2 in the atmosphere was about 280 parts per million.[6]

Two ice core temperature records; the Eemian is at a depth of about 1500–1800 meters in the lower graph
CO2 concentrations over the last 400,000 years.

The Eemian is known as the Ipswichian in the UK, the Mikulin interglacial in Russia, the Valdivia interglacial in Chile and the Riss-Würm interglacial in the Alps. Depending on how a specific publication defines the Sangamonian Stage of North America, the Eemian is equivalent to either all or part of it.

The period falls into the Middle Paleolithic and is of some interest for the evolution of anatomically modern humans, who were present in Western Asia (Skhul and Qafzeh hominins) as well as in Southern Africa by this time, representing the earliest split of modern human populations that persists to the present time (associated with mitochondrial haplogroup L0).[7]

Climate edit

 
View of the Eemian-aged coastal terraces of Niebla near Valdivia, Chile.

Global temperatures edit

The Eemian climate is believed to have been warmer than the current Holocene.[8][9] Changes in the Earth's orbital parameters from today (greater obliquity and eccentricity, and perihelion), known as Milankovitch cycles, probably led to greater seasonal temperature variations in the Northern Hemisphere.[citation needed] As the Eemian cooled, pCO2 remained stable.[10]

During the northern summer, temperatures in the Arctic region were about 2–4 °C higher than in 2011.[11] The Arctic Eemian climate was highly unstable, with pronounced temperature swings revealed by δ18O fluctuations in Greenlandic ice cores,[12] though some of the instability inferred from Greenland ice core project records may be a result of mixing of Eemian ice with ice from the preceding or succeeding glacial intervals.[13]

The warmest peak of the Eemian was around 125,000 years ago, when forests reached as far north as North Cape, Norway (which is now tundra) well above the Arctic Circle at 71°10′21″N 25°47′40″E / 71.17250°N 25.79444°E / 71.17250; 25.79444. Hardwood trees such as hazel and oak grew as far north as Oulu, Finland. At the peak of the Eemian, the Northern Hemisphere winters were generally warmer and wetter than now, though some areas were actually slightly cooler than today. The hippopotamus was distributed as far north as the rivers Rhine and Thames.[14] A 2018 study based on soil samples from Sokli in northern Finland identified abrupt cold spells ca. 120,000 years ago caused by shifts in the North Atlantic Current, lasting hundreds of years and causing temperature drops of a few degrees and vegetation changes in these regions. In Northern Europe, winter temperatures rose over the course of the Eemian while summer temperatures fell.[15] During an insolation maximum from 133,000 to 130,000 BP, meltwater from the Dnieper and Volga caused the Black and Caspian Seas to connect.[16] During the mid-Eemian, a weakened Atlantic Meridional Overturning Circulation (AMOC) began to cool the eastern Mediterranean region.[17] The period closed as temperatures steadily fell to conditions cooler and drier than the present, with a 468-year-long aridity pulse in central Europe at about 116,000 BC,[18] and by 112,000 BC, ice caps began to form in southern Norway, marking the start of a new glacial period.[19] Kaspar et al. (GRL, 2005) performed a comparison of a coupled general circulation model (GCM) with reconstructed Eemian temperatures for Europe. Central Europe (north of the Alps) was found to be 1–2 °C (1.8–3.6 °F) warmer than present; south of the Alps, conditions were 1–2 °C cooler than today. The model (generated using observed greenhouse gas concentrations and Eemian orbital parameters) generally reproduces these observations, leading them to conclude that these factors are enough to explain the Eemian temperatures.[20]

Meltwater pulse 2B, approximately 133,000 BP, substantially weakened the Indian Summer Monsoon (ISM).[21]

Trees grew as far north as southern Baffin Island in the Canadian Arctic Archipelago: currently, the northern limit is further south at Kuujjuaq in northern Quebec. Coastal Alaska was warm enough during the summer due to reduced sea ice in the Arctic Ocean to allow Saint Lawrence Island (now tundra) to have boreal forest, although inadequate precipitation caused a reduction in the forest cover in interior Alaska and Yukon Territory despite warmer conditions.[22] The prairie-forest boundary in the Great Plains of the United States lay further west near Lubbock, Texas, whereas the current boundary is near Dallas.

Interglacial conditions ended on Antarctica while the Northern Hemisphere was still experiencing warmth.[23]

 

Sea level edit

 
Eemian erosion surface in a fossil coral reef on Great Inagua, The Bahamas. Foreground shows corals truncated by erosion; behind the geologist is a post-erosion coral pillar which grew on the surface after sea level rose again.[24]

Sea level at peak was probably 6 to 9 metres (20 to 30 feet) higher than today,[25][26] with Greenland contributing 0.6 to 3.5 m (2.0 to 11.5 ft),[27] thermal expansion and mountain glaciers contributing up to 1 m (3.3 ft),[28] and an uncertain contribution from Antarctica.[29] A 2007 study found evidence that the Greenland ice core site Dye 3 was glaciated during the Eemian,[30] which implies that Greenland could have contributed at most 2 m (6.6 ft) to sea level rise.[31][32] Recent research on marine sediment cores offshore of the West Antarctic Ice Sheet suggest that the sheet melted during the Eemian, and that ocean waters rose as fast as 2.5 meters per century.[33] Global mean sea surface temperatures are thought to have been higher than in the Holocene, but not by enough to explain the rise in sea level through thermal expansion alone, and so melting of polar ice caps must also have occurred.

Because of the sea level drop since the Eemian, exposed fossil coral reefs are common in the tropics, especially in the Caribbean and along the Red Sea coastlines. These reefs often contain internal erosion surfaces showing significant sea level instability during the Eemian.[34]

Along the Central Mediterranean Spanish coast, sea levels were comparable to those of the present.[35] Scandinavia was an island. Vast areas of northwestern Europe and the West Siberian Plain were inundated.[36]

Definition of the Eemian edit

 
Bittium reticulatum Picture from Pieter Harting (1886) assigned by him as 'Index fossil' for the Eemian.

The Eemian Stage was first recognized from boreholes in the area of the city of Amersfoort, Netherlands, by Pieter Harting (1875). He named the beds "Système Eémien", after the river Eem on which Amersfoort is located. Harting noticed the marine molluscan assemblages to be very different from the modern fauna of the North Sea. Many species from the Eemian layers nowadays show a much more southern distribution, ranging from South of the Strait of Dover to Portugal (Lusitanian faunal province) and even into the Mediterranean (Mediterranean faunal province). More information on the molluscan assemblages is given by Lorié (1887), and Spaink (1958). Since their discovery, Eemian beds in the Netherlands have mainly been recognized by their marine molluscan content combined with their stratigraphical position and other palaeontology. The marine beds there are often underlain by tills that are considered to date from the Saalian, and overlain by local fresh water or wind-blown deposits from the Weichselian. In contrast to e.g. the deposits in Denmark, the Eemian deposits in the type area have never been found overlain by tills, nor in ice-pushed positions.

Van Voorthuysen (1958) described the foraminifera from the type site, whereas Zagwijn (1961) published the palynology, providing a subdivision of this stage into pollen stages. At the end of the 20th century, the type site was re-investigated using old and new data in a multi-disciplinary approach (Cleveringa et al., 2000). At the same time a parastratotype was selected in the Amsterdam glacial basin in the Amsterdam-Terminal borehole and was the subject of a multidisciplinary investigation (Van Leeuwen, et al., 2000). These authors also published a U/Th age for late Eemian deposits from this borehole of 118,200 ± 6,300 years ago. A historical review of Dutch Eemian research is provided by Bosch, Cleveringa and Meijer, 2000.

See also edit

References edit

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Further reading edit

  • Bosch, J. H. A.; Cleveringa, P.; Meijer, T. (2000). "The Eemian stage in the Netherlands: history, character and new research". Netherlands Journal of Geosciences. 79 (2/3): 135–145. doi:10.1017/S0016774600021673.
  • Cleveringa, P., Meijer, T., van Leeuwen, R.J.W., de Wolf, H., Pouwer, R., Lissenberg T. and Burger, A.W., 2000. The Eemian stratotype locality at Amersfoort in the central Netherlands: a re-evaluation of old and new data. Geologie & Mijnbouw / Netherlands Journal of Geosciences, 79(2/3): 197–216.
  • Harting, P., 1875. Le système Éemien Archives Néerlandaises Sciences Exactes et Naturelles de la Société Hollandaise des Sciences (Harlem), 10: 443–454.
  • Harting, P., 1886. Het Eemdal en het Eemstelsel Album der Natuur, 1886: 95–100.
  • Overpeck, Jonathan T.; et al. (2006). "Paleoclimatic Evidence for Future Ice-Sheet Instability and Rapid Sea-Level Rise". Science. 311 (5768): 1747–1750. Bibcode:2006Sci...311.1747O. doi:10.1126/science.1115159. PMID 16556837. S2CID 36048003.
  • Lorié, J., 1887. Contributions a la géologie des Pays Bas III. Le Diluvium plus récent ou sableux et le système Eémien Archives Teyler, Ser. II, Vol. III: 104–160.
  • Müller, Ulrich C.; et al. (2005). "Cyclic climate fluctuations during the last interglacial in central Europe". Geology. 33 (6): 449–452. Bibcode:2005Geo....33..449M. doi:10.1130/G21321.1.
  • Spaink, G., 1958. De Nederlandse Eemlagen, I: Algemeen overzicht. Wetenschappelijke Mededelingen Koninklijke Nederlandse Natuurhistorische Vereniging 29, 44 pp.
  • Van Leeuwen, R.J., Beets, D., Bosch, J.H.A., Burger, A.W., Cleveringa, P., van Harten, D., Herngreen, G.F.W., Langereis, C.G., Meijer, T., Pouwer, R., de Wolf, H., 2000. Stratigraphy and integrated facies analysis of the Saalian and Eemian sediments in the Amsterdam-Terminal borehole, the Netherlands. Geologie en Mijnbouw / Netherlands Journal of Geosciences 79, 161–196.
  • Van Voorthuysen, J.H., 1958. Foraminiferen aus dem Eemien (Riss-Würm-Interglazial) in der Bohrung Amersfoort I (Locus Typicus). Mededelingen Geologische Stichting NS 11(1957), 27–39.
  • Zagwijn, W.H., 1961. Vegetation, climate and radiocarbon datings in the Late Pleistocene of the Netherlands. Part 1: Eemian and Early Weichselian. Mededelingen Geologische Stichting NS 14, 15–45.

External links edit

  • www.foraminifera.eu Foraminifera (Microfossils) of the Eemian Interglacial

February 16, 2024
eemian, also, called, last, interglacial, sangamonian, stage, ipswichian, mikulin, kaydaky, penultimate, interglacial, valdivia, riss, würm, interglacial, period, which, began, about, years, penultimate, glacial, period, ended, about, years, beginning, last, g. The Eemian also called the last interglacial 1 Sangamonian Stage Ipswichian Mikulin Kaydaky penultimate interglacial 2 Valdivia or Riss Wurm was the interglacial period which began about 130 000 years ago at the end of the Penultimate Glacial Period and ended about 115 000 years ago at the beginning of the Last Glacial Period 3 It corresponds to Marine Isotope Stage 5e 4 Although sometimes referred to as the last interglacial in the most recent previous sense of last it was the second to latest interglacial period of the current Ice Age the most recent being the Holocene which extends to the present day having followed the last glacial period The prevailing Eemian climate was on average around 1 to 2 degrees Celsius 1 8 to 3 6 Fahrenheit warmer than that of the Holocene 5 During the Eemian the proportion of CO2 in the atmosphere was about 280 parts per million 6 Two ice core temperature records the Eemian is at a depth of about 1500 1800 meters in the lower graphCO2 concentrations over the last 400 000 years The Eemian is known as the Ipswichian in the UK the Mikulin interglacial in Russia the Valdivia interglacial in Chile and the Riss Wurm interglacial in the Alps Depending on how a specific publication defines the Sangamonian Stage of North America the Eemian is equivalent to either all or part of it The period falls into the Middle Paleolithic and is of some interest for the evolution of anatomically modern humans who were present in Western Asia Skhul and Qafzeh hominins as well as in Southern Africa by this time representing the earliest split of modern human populations that persists to the present time associated with mitochondrial haplogroup L0 7 Contents 1 Climate 1 1 Global temperatures 2 Sea level 3 Definition of the Eemian 4 See also 5 References 6 Further reading 7 External linksClimate edit nbsp View of the Eemian aged coastal terraces of Niebla near Valdivia Chile Global temperatures edit The Eemian climate is believed to have been warmer than the current Holocene 8 9 Changes in the Earth s orbital parameters from today greater obliquity and eccentricity and perihelion known as Milankovitch cycles probably led to greater seasonal temperature variations in the Northern Hemisphere citation needed As the Eemian cooled pCO2 remained stable 10 During the northern summer temperatures in the Arctic region were about 2 4 C higher than in 2011 11 The Arctic Eemian climate was highly unstable with pronounced temperature swings revealed by d18O fluctuations in Greenlandic ice cores 12 though some of the instability inferred from Greenland ice core project records may be a result of mixing of Eemian ice with ice from the preceding or succeeding glacial intervals 13 The warmest peak of the Eemian was around 125 000 years ago when forests reached as far north as North Cape Norway which is now tundra well above the Arctic Circle at 71 10 21 N 25 47 40 E 71 17250 N 25 79444 E 71 17250 25 79444 Hardwood trees such as hazel and oak grew as far north as Oulu Finland At the peak of the Eemian the Northern Hemisphere winters were generally warmer and wetter than now though some areas were actually slightly cooler than today The hippopotamus was distributed as far north as the rivers Rhine and Thames 14 A 2018 study based on soil samples from Sokli in northern Finland identified abrupt cold spells ca 120 000 years ago caused by shifts in the North Atlantic Current lasting hundreds of years and causing temperature drops of a few degrees and vegetation changes in these regions In Northern Europe winter temperatures rose over the course of the Eemian while summer temperatures fell 15 During an insolation maximum from 133 000 to 130 000 BP meltwater from the Dnieper and Volga caused the Black and Caspian Seas to connect 16 During the mid Eemian a weakened Atlantic Meridional Overturning Circulation AMOC began to cool the eastern Mediterranean region 17 The period closed as temperatures steadily fell to conditions cooler and drier than the present with a 468 year long aridity pulse in central Europe at about 116 000 BC 18 and by 112 000 BC ice caps began to form in southern Norway marking the start of a new glacial period 19 Kaspar et al GRL 2005 performed a comparison of a coupled general circulation model GCM with reconstructed Eemian temperatures for Europe Central Europe north of the Alps was found to be 1 2 C 1 8 3 6 F warmer than present south of the Alps conditions were 1 2 C cooler than today The model generated using observed greenhouse gas concentrations and Eemian orbital parameters generally reproduces these observations leading them to conclude that these factors are enough to explain the Eemian temperatures 20 Meltwater pulse 2B approximately 133 000 BP substantially weakened the Indian Summer Monsoon ISM 21 Trees grew as far north as southern Baffin Island in the Canadian Arctic Archipelago currently the northern limit is further south at Kuujjuaq in northern Quebec Coastal Alaska was warm enough during the summer due to reduced sea ice in the Arctic Ocean to allow Saint Lawrence Island now tundra to have boreal forest although inadequate precipitation caused a reduction in the forest cover in interior Alaska and Yukon Territory despite warmer conditions 22 The prairie forest boundary in the Great Plains of the United States lay further west near Lubbock Texas whereas the current boundary is near Dallas Interglacial conditions ended on Antarctica while the Northern Hemisphere was still experiencing warmth 23 nbsp Sea level edit nbsp Eemian erosion surface in a fossil coral reef on Great Inagua The Bahamas Foreground shows corals truncated by erosion behind the geologist is a post erosion coral pillar which grew on the surface after sea level rose again 24 Sea level at peak was probably 6 to 9 metres 20 to 30 feet higher than today 25 26 with Greenland contributing 0 6 to 3 5 m 2 0 to 11 5 ft 27 thermal expansion and mountain glaciers contributing up to 1 m 3 3 ft 28 and an uncertain contribution from Antarctica 29 A 2007 study found evidence that the Greenland ice core site Dye 3 was glaciated during the Eemian 30 which implies that Greenland could have contributed at most 2 m 6 6 ft to sea level rise 31 32 Recent research on marine sediment cores offshore of the West Antarctic Ice Sheet suggest that the sheet melted during the Eemian and that ocean waters rose as fast as 2 5 meters per century 33 Global mean sea surface temperatures are thought to have been higher than in the Holocene but not by enough to explain the rise in sea level through thermal expansion alone and so melting of polar ice caps must also have occurred Because of the sea level drop since the Eemian exposed fossil coral reefs are common in the tropics especially in the Caribbean and along the Red Sea coastlines These reefs often contain internal erosion surfaces showing significant sea level instability during the Eemian 34 Along the Central Mediterranean Spanish coast sea levels were comparable to those of the present 35 Scandinavia was an island Vast areas of northwestern Europe and the West Siberian Plain were inundated 36 Definition of the Eemian edit nbsp Bittium reticulatum Picture from Pieter Harting 1886 assigned by him as Index fossil for the Eemian The Eemian Stage was first recognized from boreholes in the area of the city of Amersfoort Netherlands by Pieter Harting 1875 He named the beds Systeme Eemien after the river Eem on which Amersfoort is located Harting noticed the marine molluscan assemblages to be very different from the modern fauna of the North Sea Many species from the Eemian layers nowadays show a much more southern distribution ranging from South of the Strait of Dover to Portugal Lusitanian faunal province and even into the Mediterranean Mediterranean faunal province More information on the molluscan assemblages is given by Lorie 1887 and Spaink 1958 Since their discovery Eemian beds in the Netherlands have mainly been recognized by their marine molluscan content combined with their stratigraphical position and other palaeontology The marine beds there are often underlain by tills that are considered to date from the Saalian and overlain by local fresh water or wind blown deposits from the Weichselian In contrast to e g the deposits in Denmark the Eemian deposits in the type area have never been found overlain by tills nor in ice pushed positions Van Voorthuysen 1958 described the foraminifera from the type site whereas Zagwijn 1961 published the palynology providing a subdivision of this stage into pollen stages At the end of the 20th century the type site was re investigated using old and new data in a multi disciplinary approach Cleveringa et al 2000 At the same time a parastratotype was selected in the Amsterdam glacial basin in the Amsterdam Terminal borehole and was the subject of a multidisciplinary investigation Van Leeuwen et al 2000 These authors also published a U Th age for late Eemian deposits from this borehole of 118 200 6 300 years ago A historical review of Dutch Eemian research is provided by Bosch Cleveringa and Meijer 2000 See also editMarine Isotope Stage 5 Paleoclimatology Timeline of glaciationReferences edit Adams Jonathan Maslin Mark Thomas Ellen Sudden climate transitions during the Quaternary Oak Ridge National Laboratory Archived from the original on 2016 05 18 Retrieved 2017 01 24 NOAA Penultimate Interglacial Period http www ncdc noaa gov global warming penultimate interglacial period Dahl Jensen D Albert M R Aldahan A Azuma N Balslev Clausen D Baumgartner M Berggren A M Bigler M Binder T Blunier T Bourgeois J C Brook E J Buchardt S L Buizert C Capron E Chappellaz J Chung J Clausen H B Cvijanovic I Davies S M Ditlevsen P Eicher O Fischer H Fisher D A Fleet L G Gfeller G Gkinis V Gogineni S Goto Azuma K et al 2013 Eemian interglacial reconstructed from a Greenland folded ice core PDF Nature 493 7433 489 94 Bibcode 2013Natur 493 489N doi 10 1038 nature11789 PMID 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11 011 ISSN 1464 343X Retrieved 1 January 2024 via Elsevier Science Direct Vinals Maria Jose Fumanal Maria Pilar January 1995 Quaternary development and evolution of the sedimentary environments in the Central Mediterranean Spanish coast Quaternary International 29 30 119 128 doi 10 1016 1040 6182 95 00014 A Retrieved 17 September 2023 Gornitz Vivien 2013 Rising Seas Past Present Future New York Columbia University Press p 101 ISBN 978 0 231 14739 2 Retrieved August 9 2021 Further reading editBosch J H A Cleveringa P Meijer T 2000 The Eemian stage in the Netherlands history character and new research Netherlands Journal of Geosciences 79 2 3 135 145 doi 10 1017 S0016774600021673 Cleveringa P Meijer T van Leeuwen R J W de Wolf H Pouwer R Lissenberg T and Burger A W 2000 The Eemian stratotype locality at Amersfoort in the central Netherlands a re evaluation of old and new data Geologie amp Mijnbouw Netherlands Journal of Geosciences 79 2 3 197 216 Harting P 1875 Le systeme Eemien Archives Neerlandaises Sciences Exactes et Naturelles de la Societe Hollandaise des Sciences Harlem 10 443 454 Harting P 1886 Het Eemdal en het Eemstelsel Album der Natuur 1886 95 100 Overpeck Jonathan T et al 2006 Paleoclimatic Evidence for Future Ice Sheet Instability and Rapid Sea Level Rise Science 311 5768 1747 1750 Bibcode 2006Sci 311 1747O doi 10 1126 science 1115159 PMID 16556837 S2CID 36048003 Lorie J 1887 Contributions a la geologie des Pays Bas III Le Diluvium plus recent ou sableux et le systeme Eemien Archives Teyler Ser II Vol III 104 160 Muller Ulrich C et al 2005 Cyclic climate fluctuations during the last interglacial in central Europe Geology 33 6 449 452 Bibcode 2005Geo 33 449M doi 10 1130 G21321 1 Spaink G 1958 De Nederlandse Eemlagen I Algemeen overzicht Wetenschappelijke Mededelingen Koninklijke Nederlandse Natuurhistorische Vereniging 29 44 pp Van Leeuwen R J Beets D Bosch J H A Burger A W Cleveringa P van Harten D Herngreen G F W Langereis C G Meijer T Pouwer R de Wolf H 2000 Stratigraphy and integrated facies analysis of the Saalian and Eemian sediments in the Amsterdam Terminal borehole the Netherlands Geologie en Mijnbouw Netherlands Journal of Geosciences 79 161 196 Van Voorthuysen J H 1958 Foraminiferen aus dem Eemien Riss Wurm Interglazial in der Bohrung Amersfoort I Locus Typicus Mededelingen Geologische Stichting NS 11 1957 27 39 Zagwijn W H 1961 Vegetation climate and radiocarbon datings in the Late Pleistocene of the Netherlands Part 1 Eemian and Early Weichselian Mededelingen Geologische Stichting NS 14 15 45 External links editwww foraminifera eu Foraminifera Microfossils of the Eemian Interglacial Retrieved from https en wikipedia org w index php title Eemian amp oldid 1193735787, wikipedia, wiki, book, books, library,

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