Younger Dryas 

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Three temperature proxies showing the Younger Dryas event at around 11.0 ka BP. 
The NGRIP sequence (red - mislabled as GRIP) uses the water molecule isotopic 
composition - δ18O. The Vostok and EPICA Dome C series show delta-deuterium. All 
3 proxies use the same vertical axis. 

The Younger Dryas stadial, also referred to as the Big Freeze,[1] was a 
geologically brief (1,300 ± 70 years) period of cold climatic conditions and 
drought which occurred between approximately 12,800 and 11,500 years BP (Before 
Present).[2] The Younger Dryas stadial is thought to have been caused by the 
collapse of the North American ice sheets, although rival theories have been 
proposed. 

It followed the Bølling-Allerød interstadial (warm period) at the end of the 
Pleistocene and preceded the Preboreal of the early Holocene. It is named after 
an indicator genus, the alpine-tundra wildflower Dryas octopetala. In Ireland, 
the period has been known as the Nahanagan Stadial, while in the United Kingdom 
it has been called the Loch Lomond Stadial and most recently Greenland Stadial 1 
(GS1).[3][4] The Younger Dryas (GS1) is also a Blytt-Sernander climate period 
detected from layers in north European bog peat. 

The Dryas stadials were cold periods which interrupted the warming trend since 
the Last Glacial Maximum 20,000 years ago. The Older Dryas occurred 
approximately 1,000 years before the Younger Dryas and lasted about 300 years.[5] 
The Oldest Dryas is dated between approximately 18,000 and 15,000 BP. 
Contents 
[hide] 

1 Abrupt climate change 

2 Global effects 

3 Causes 

4 End of the climate period 

5 Effect on agriculture 

6 Cultural references 

7 See also 

8 References 

9 External links  

[edit] Abrupt climate change 

The Younger Dryas saw a rapid return to glacial conditions in the higher 
latitudes of the Northern Hemisphere between 12.9–11.5 ka BP[6] in sharp 
contrast to the warming of the preceding interstadial deglaciation. It has been 
believed that the transitions each occurred over a period of a decade or so,[7] 
but the onset may have been faster.[8] Thermally fractionated nitrogen and argon 
isotope data from Greenland ice core GISP2 indicate that the summit of Greenland 
was approximately 15 °C (27.0 °F) colder during the Younger Dryas[7] than today. 
In the UK, coleopteran fossil evidence (from beetles) suggests that mean annual 
temperature dropped to approximately 5 °C (41 °F),[9] and periglacial conditions 
prevailed in lowland areas, while icefields and glaciers formed in upland areas.[10] 
Nothing of the size, extent, or rapidity of this period of abrupt climate change 
has been experienced since.[6] 

[edit] Global effects 

In western Europe and Greenland, the Younger Dryas is a well-defined synchronous 
cool period.[11] But cooling in the tropical North Atlantic may have preceded 
this by a few hundred years; South America shows a less well defined initiation 
but a sharp termination. The Antarctic Cold Reversal appears to have started a 
thousand years before the Younger Dryas, and has no clearly defined start or end; 
Huybers has argued that there is fair confidence in the absence of the Younger 
Dryas in Antarctica, New Zealand and parts of Oceania.[12] Timing of the 
tropical counterpart to the Younger Dryas – the Deglaciation Climate Reversal (DCR) 
– is difficult to establish as low latitude ice core records generally lack 
independent dating over this interval. An example of this is the Sajama ice core 
(Bolivia), for which the timing of the DCR has been pinned to that of the GISP2 
ice core record (central Greenland). Climatic change in the central Andes during 
the DCR, however, was significant and characterized by a shift to much wetter, 
and likely colder, conditions.[13] The magnitude and abruptness of these changes 
would suggest that low latitude climate did not respond passively during the YD/DCR. 

In western North America it is likely that the effects of the Younger Dryas were 
less intense than in Europe; however, evidence of glacial re-advance[14] 
indicates Younger Dryas cooling occurred in the Pacific Northwest. 

Other features seen include: 

Replacement of forest in Scandinavia with glacial tundra (which is the habitat 
of the plant Dryas octopetala). 

Glaciation or increased snow in mountain ranges around the world. 

Formation of solifluction layers and loess deposits in Northern Europe. 

More dust in the atmosphere, originating from deserts in Asia. 

Drought in the Levant, perhaps motivating the Natufian culture to develop 
agriculture. 

The Huelmo/Mascardi Cold Reversal in the Southern Hemisphere ended at the same 
time. 

Decline of the Clovis Culture and extinction of animal species in North America. 

[edit] Causes 

The prevailing theory holds that the Younger Dryas was caused by a significant 
reduction or shutdown of the North Atlantic "Conveyor", which circulates warm 
tropical waters northward, in response to a sudden influx of fresh water from 
Lake Agassiz and deglaciation in North America; however, geological evidence for 
such an event is thus far lacking.[15] The global climate would then have become 
locked into the new state until freezing removed the fresh water "lid" from the 
north Atlantic Ocean. A recent alternative theory suggests instead that the jet 
stream shifted northward in response to the changing topographic forcing of the 
melting North American ice sheet, bringing more rain to the North Atlantic which 
freshened the ocean surface enough to slow the thermohaline circulation.[16] 

Previous glacial terminations probably did not have Younger Dryas-like events, 
suggesting that its cause has a random component. Nevertheless, there is 
evidence that some previous glacial terminations had post glacial cooling 
periods somewhat similar to the Younger Dryas.[17] 

A hypothesized Younger Dryas impact event, presumed to have occurred in North 
America around 12.9 ka BP, has been proposed as the mechanism to have initiated 
the Younger Dryas cooling, but reviews of the evidence for an impact event has 
shown that none of the original impact signatures that were attributed to the YD 
have been corroborated by independent tests[18]; although, a report in 2012[19] 
supported the theory. 

[edit] End of the climate period 

Measurements of oxygen isotopes from the GISP2 ice core suggest the ending of 
the Younger Dryas took place over just 40 – 50 years in three discrete steps, 
each lasting five years. Other proxy data, such as dust concentration, and snow 
accumulation, suggest an even more rapid transition, requiring about a 7 °C (12.60 
°F) warming in just a few years.[6][7][20][21] Total warming was 10 ± 4 °C (18 ± 
7 °F).[22] 

The end of the Younger Dryas has been dated to around 11.55 ka BP, occurring at 
10 ka BP (radiocarbon year), a "radiocarbon plateau") by a variety of methods, 
with mostly consistent results: 

11.50 ± 0.05  ka BP — GRIP ice core, Greenland [23] 
11.53 + 0.04
− 0.06  ka BP — Kråkenes Lake, western Norway.[24] 
11.57  ka BP — Cariaco Basin core, Venezuela [25] 
11.57  ka BP — German oak/pine dendrochronology [26] 
11.64 ± 0.28  ka BP — GISP2 ice core, Greenland [20] 

[edit] Effect on agriculture 

The Younger Dryas is often linked to the adoption of agriculture in the Levant.[27][28] 
It is argued that the cold and dry Younger Dryas lowered the carrying capacity 
of the area and forced the sedentary Early Natufian population into a more 
mobile subsistence pattern. Further climatic deterioration is thought to have 
brought about cereal cultivation. While there exists relative consensus 
regarding the role of the Younger Dryas in the changing subsistence patterns 
during the Natufian, its connection to the beginning of agriculture at the end 
of the period is still being debated.[29][30] See the Neolithic Revolution, when 
hunter gatherers turned to farming. 

[edit] Cultural references 

The failure of North Atlantic thermohaline circulation is used to explain rapid 
climate change in some science fiction writings as early as Stanley G. Weinbaum's 
1937 short story "Shifting Seas" where the author described the freezing of 
Europe after the Gulf Stream was disrupted, and more recently in Kim Stanley 
Robinson's novels, particularly Fifty Degrees Below. It also underpinned the 
1999 book, The Coming Global Superstorm. Likewise, the idea of rapid climate 
change caused by disruption of North Atlantic ocean currents creates the setting 
for 2004 apocalyptic science-fiction film The Day After Tomorrow. Similar sudden 
cooling events have featured in other novels, such as John Christopher's The 
World in Winter, though not always with the same explicit links to the Younger 
Dryas event as is the case of Robinson's work. 

[edit] See also 

Shutdown of thermohaline circulation 

Heinrich event 

1500-year climate cycle 

Timeline of glaciation 

Timeline of environmental events 

Neoglaciation 

Older Dryas 

Oldest Dryas 

8.2 kiloyear climate event 

Little Ice Age 

Medieval Warm Period 

[edit] References 

^ Berger, W. H. (1990). "The Younger Dryas cold spell — a quest for causes". 
Global and Planetary Change 3 (3): 219–237. Bibcode 1990GPC.....3..219B. doi:10.1016/0921-8181(90)90018-8. 

^ Muscheler, Raimund et al (2008). "Tree rings and ice cores reveal 14C 
calibration uncertainties during the Younger Dryas". Nature Geoscience 1 (4): 
263–267. Bibcode 2008NatGe...1..263M. doi:10.1038/ngeo128. 

^ Seppä, H.; Birks, H. H.; Birks, H. J. B. (2002). "Rapid climatic changes 
during the Greenland stadial 1 (Younger Dryas) to early Holocene transition on 
the Norwegian Barents Sea coast". Boreas 31 (3): 215–225. doi:10.1111/j.1502-3885.2002.tb01068.x. 
edit 

^ Walker, M. J. C. (2004). "A Lateglacial pollen record from Hallsenna Moor, 
near Seascale, Cumbria, NW England, with evidence for arid conditions during the 
Loch Lomond (Younger Dryas) Stadial and early Holocene". Proceedings of the 
Yorkshire Geological Society 55: 33–42. doi:10.1144/pygs.55.1.33. 

^ Mangerud, J.; Andersen, S. T.; Berglund, B. E.; Donner, J. J. (2008). "Quaternary 
stratigraphy of Norden, a proposal for terminology and classification". Boreas 3 
(3): 109–126. doi:10.1111/j.1502-3885.1974.tb00669.x. edit 

^ a b c Alley, Richard B. (2000). "The Younger Dryas cold interval as viewed 
from central Greenland". Quaternary Science Reviews 19 (1): 213–226. Bibcode 
2000QSRv...19..213A. doi:10.1016/S0277-3791(99)00062-1. 

^ a b c Alley, Richard B. et al (1993). "Abrupt accumulation increase at the 
Younger Dryas termination in the GISP2 ice core". Nature 362 (6420): 527–529. 
Bibcode 1993Natur.362..527A. doi:10.1038/362527a0. 

^ Choi, Charles Q. (2 December 2009). Big Freeze: Earth Could Plunge into Sudden 
Ice Age. http://www.livescience.com/environment/091202-fast-ice-age.html. 
Retrieved December 2, 2009. 

^ Severinghaus, Jeffrey P. et al (1998). "Timing of abrupt climate change at the 
end of the Younger Dryas interval from thermally fractionated gases in polar ice". 
Nature 391 (6663): 141–146. Bibcode 1998Natur.391..141S. doi:10.1038/34346. 

^ Atkinson, T. C. et al (1987). "Seasonal temperatures in Britain during the 
past 22,000 years, reconstructed using beetle remains". Nature 325 (6105): 587–592. 
Bibcode 1987Natur.325..587A. doi:10.1038/325587a0. 

^ How Stable was the Holocene Climate? 

^ http://www.sciencedaily.com/releases/2010/09/100908132214.htm 

^ Thompson, L. G. et al (2000). "Ice-core palaeoclimate records in tropical 
South America since the Last Glacial Maximum". Journal of Quaternary Science 15 
(4): 377–394. Bibcode 2000JQS....15..377T. doi:10.1002/1099-1417(200005)15:4<377::AID-JQS542>3.0.CO;2-L. 

^ Friele, P. A.; Clague, J. J. (2002). "Younger Dryas readvance in Squamish 
river valley, southern Coast mountains, British Columbia". Quaternary Science 
Reviews 21 (18–19): 1925–1933. Bibcode 2002QSRv...21.1925F. doi:10.1016/S0277-3791(02)00081-1. 

^ Broecker, Wallace S. (2006). "Was the Younger Dryas Triggered by a Flood?". 
Science 312 (5777): 1146–1148. doi:10.1126/science.1123253. PMID 16728622. 

^ Eisenman, I.; Bitz, C. M.; Tziperman, E. (2009). "Rain driven by receding ice 
sheets as a cause of past climate change". Paleoceanography 24 (4): PA4209. 
Bibcode 2009PalOc..24.4209E. doi:10.1029/2009PA001778. edit 

^ Carlson, A. (2008). "Why there was not a Younger Dryas-like event during the 
Penultimate Deglaciation". Quaternary Science Reviews 27 (9–10): 882–887. 
Bibcode 2008QSRv...27..882C. doi:10.1016/j.quascirev.2008.02.004. edit 

^ Pinter, N.; Scott, A. C.; Daulton, T. L.; Podoll, A.; Koeberl, C.; Anderson, R. 
S.; Ishman, S. E. (2011). "The Younger Dryas impact hypothesis: A requiem". 
Earth-Science Reviews 106 (3–4): 247. doi:10.1016/j.earscirev.2011.02.005. edit 

^ Study Jointly Led by UCSB Researcher Supports Theory of Extraterrestrial 
Impact, UC Santa Barbara, nedia release, 5 March 2012, accessed 6 March 2012 

^ a b Sissons, J. B. (1979). "The Loch Lomond stadial in the British Isles". 
Nature 280 (5719): 199–203. Bibcode 1979Natur.280..199S. doi:10.1038/280199a0. 

^ Dansgaard, W. et al (1989). "The abrupt termination of the Younger Dryas 
climate event". Nature 339 (6225): 532–534. Bibcode 1989Natur.339..532D. doi:10.1038/339532a0. 

^ Kobashia, Takuro et al (2008). "4 ± 1.5 °C abrupt warming 11,270 years ago 
identified from trapped air in Greenland ice". Earth and Planetary Science 
Letters 268 (3–4): 397–407. Bibcode 2008E&PSL.268..397K. doi:10.1016/j.epsl.2008.01.032. 

^ Taylor, K. C. (1997). "The Holocene-Younger Dryas transition recorded at 
Summit, Greenland". Science 278 (5339): 825–827. Bibcode 1997Sci...278..825T. 
doi:10.1126/science.278.5339.825. 

^ Spurk, M. (1998). "Revisions and extension of the Hohenheim oak and pine 
chronologies: New evidence about the timing of the Younger Dryas/Preboreal 
transition". Radiocarbon 40 (3): 1107–1116. http://www.radiocarbon.org/Journal/v40n3/Abstracts/4.html. 

^ Gulliksen, Steinar et al (1998). "A calendar age estimate of the Younger Dryas-Holocene 
boundary at Krakenes, western Norway". Holocene 8 (3): 249–259. doi:10.1191/095968398672301347. 

^ Hughen, Konrad A. et al (2000). "Synchronous Radiocarbon and Climate Shifts 
During the Last Deglaciation". Science 290 (5498): 1951–1954. Bibcode 2000Sci...290.1951H. 
doi:10.1126/science.290.5498.1951. PMID 11110659. 

^ Bar-Yosef, O. and A. Belfer-Cohen: "Facing environmental crisis. Societal and 
cultural changes at the transition from the Younger Dryas to the Holocene in the 
Levant." In: The Dawn of Farming in the Near East. Edited by R.T.J. Cappers and 
S. Bottema, pp. 55–66. Studies in Early Near Eastern Production, Subsistence and 
Environment 6. Berlin: Ex oriente. 

^ Mithen, Steven J.: After The Ice: A Global Human History, 20,000–5000 BC, 
pages 46–55. Harvard University Press paperback edition, 2003. 

^ Munro, N. D. (2003). "Small game, the younger dryas, and the transition to 
agriculture in the southern levant". Mitteilungen der Gesellschaft für 
Urgeschichte 12: 47–64. http://www.anth.uconn.edu/faculty/munro/assets/Mitteilungen.pdf. 

^ Balter, Michael (2010). "Archaeology: The Tangled Roots of Agriculture". 
Science 327 (5964): 404–406. doi:10.1126/science.327.5964.404. PMID 20093449. 
http://scienceonline.org/cgi/content/summary/sci;327/5964/404. Retrieved 4 
February 2010. 

[edit] External links 

"Study Confirms Mechanism for Current Shutdowns, European Cooling". Oregon State 
University. 2007. http://oregonstate.edu/dept/ncs/newsarch/2007/Apr07/currents.html. 
Retrieved 2011-04-11. 

Broecker WS (1999). "What If the Conveyor Were to Shut Down?". GSA Today 9 (1): 
1–7. http://faculty.washington.edu/wcalvin/teaching/Broecker99.html. Retrieved 
2011-04-11. 

Calvin WH (January 1998). "The Great Climate Flip-flop". The Atlantic Monthly 
281: 47–64. http://williamcalvin.com/1990s/1998AtlanticClimate.htm. Retrieved 
2011-04-11. 

Tarasov L, Peltier WR (June 2005). "Arctic freshwater forcing of the Younger 
Dryas cold reversal". Nature 435 (7042): 662–665. Bibcode 2005Natur.435..662T. 
doi:10.1038/nature03617. PMID 15931219. 
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Geologic history of Earth  
[show] Precambrian (4.57 Gya – 542 Mya)  
In left column are eons; right column: bold are eras; not bold are periods:  
Hadean
(4.57 – 4 Gya) (informal)  
Archean
(4 – 2.5 Gya) Eoarchean (4 – 3.6 Gya)
Paleoarchean (3.6 – 3.2 Gya)
Mesoarchean (3.2 – 2.8 Gya)
Neoarchean (2.8 – 2.5 Gya)  
Proterozoic
(2.5 Gya – 542 Mya) Paleoproterozoic (2.5 – 1.6 Gya): Siderian (2.5 – 2.3 Gya) · 
Rhyacian (2.3 – 2.05 Gya) · Orosirian (2.05 – 1.8 Gya) · Statherian (1.8 – 1.6 
Gya)
Mesoproterozoic (1.6 – 1 Gya): Calymmian (1.6 – 1.4 Gya) · Ectasian (1.4 – 1.2 
Gya) · Stenian (1.2 – 1 Gya)
Neoproterozoic (1 Gya – 542 Mya): Tonian (1 Gya – 850 Mya) · Cryogenian (850 – 
635 Mya) · Ediacaran (635 – 542 Mya)  
Mya = millions years ago. Gya = billions years ago.  
[hide] Phanerozoic (542 – 0 Mya)  
In horizontal bars are eras; in left column are periods; right column: bold are 
epochs; not bold not italic are ages; italic are chrons:  
[show] Paleozoic (542 – 251 Mya)  
Cambrian
(542 – 488.3 Mya)  
Terreneuvian (542 – 521 Mya) (de): Fortunian (542 – 528 Mya) (de) · Age 2* (528 
– 521 Mya)
Epoch 2* (521 – 510 Mya): Age 3* (521 – 515 Mya) · Age 4* (515 – 510 Mya)
Epoch 3* (510 – 499 Mya): Age 5* (510 – 506.5 Mya) · Drumian (506.5 – 503 Mya) (de) 
· Guzhangian (503 – 499 Mya) (de)
Furongian (499 – 488.3 Mya): Paibian (499 – 496 Mya) · Jiangshanian (496 – 492 
Mya) (de) · Age 10* (492 – 488.3 Mya)  
Ordovician
(488.3 – 443.7 Mya)  
Early Ordovician (488.3 – 471.8 Mya): Tremadocian (488.3 – 478.6 Mya) · Floian (478.6 
– 471.8 Mya)
Middle Ordovician (471.8 – 460.9 Mya): Dapingian (471.8 – 468.1 Mya) · 
Darriwilian (468.1 – 460.9 Mya)
Late Ordovician (460.9 – 443.7 Mya): Sandbian (460.9 – 455.8 Mya) · Katian (455.8 
– 445.6 Mya) · Hirnantian (445.6 – 443.7 Mya)  
Silurian
(443.7 – 416 Mya)  
Llandovery (443.7 – 428.2 Mya): Rhuddanian (443.7 – 439 Mya) · Aeronian (439 – 
436 Mya) · Telychian (436 – 428.2 Mya)
Wenlock (428.2 – 422.9 Mya): Sheinwoodian (428.2 – 426.2 Mya) · Homerian (426.2 
– 422.9 Mya)
Ludlow (422.9 – 418.7 Mya): Gorstian (422.9 – 421.3 Mya) · Ludfordian (421.3 – 
418.7 Mya)
Pridoli (418.7 – 416 Mya)  
Devonian
(416 – 359.2 Mya)  
Early Devonian (416 – 397.5 Mya): Lochkovian (416 – 411.2 Mya) · Pragian (411.2 
– 407 Mya) · Emsian (407 – 397.5 Mya)
Middle Devonian (397.5 – 385.3 Mya): Eifelian (397.5 – 391.8 Mya) · Givetian (391.8 
– 385.3 Mya)
Late Devonian (385.3 – 359.2 Mya): Frasnian (385.3 – 374.5 Mya) · Famennian (374.5 
– 359.2 Mya)  
Carboniferous
(359.2 – 299 Mya)  
Mississippian (359.2 – 318.1 Mya): Tournaisian / Early Mississippian (359.2 – 
345.3 Mya) · Viséan / Middle Mississippian (345.3 – 328.3 Mya) · Serpukhovian / 
Late Mississippian (328.3 – 318.1 Mya)
Pennsylvanian (318.1 – 299 Mya): Bashkirian / Early Pennsylvanian (318.1 – 311.7 
Mya) · Moscovian / Middle Pennsylvanian (311.7 – 307.2 Mya) · Late Pennsylvanian 
(307.2 – 299 Mya): Kasimovian (307.2 – 303.4 Mya) · Gzhelian (303.4 – 299 Mya)  
Permian
(299 – 251 Mya)  
Cisuralian (299 – 270.6 Mya): Asselian (299 – 294.6 Mya) · Sakmarian (294.6 – 
284.4 Mya) · Artinskian (284.4 – 275.6 Mya) · Kungurian (275.6 – 270.6 Mya)
Guadalupian (270.6 – 260.4 Mya): Roadian (270.6 – 268 Mya) · Wordian (268 – 265.8 
Mya) · Capitanian (265.8 – 260.4 Mya)
Lopingian (260.4 – 251 Mya): Wuchiapingian (260.4 – 253.8 Mya) · Changhsingian (253.8 
– 251 Mya)  
[show] Mesozoic (251 – 65.5 Mya)  
Triassic
(251 – 199.6 Mya)  
Early Triassic (251 – 245.9 Mya): Induan (251 – 249.5 Mya) · Olenekian (249.5 – 
245.9 Mya)
Middle Triassic (245.9 – 228.7 Mya): Anisian (245.9 – 237 Mya) · Ladinian (237 – 
228.7 Mya)
Late Triassic (228.7 – 199.6 Mya): Carnian (228.7 – 216.5 Mya) · Norian (216.5 – 
203.6 Mya) · Rhaetian (203.6 – 199.6 Mya)  
Jurassic
(199.6 – 145.5 Mya)  
Early Jurassic (199.6 – 175.6 Mya): Hettangian (199.6 – 196.5 Mya) · Sinemurian 
(196.5 – 189.6 Mya) · Pliensbachian (189.6 – 183 Mya) · Toarcian (183 – 175.6 
Mya)
Middle Jurassic (175.6 – 161.2 Mya): Aalenian (175.6 – 171.6 Mya) · Bajocian (171.6 
– 167.7 Mya) · Bathonian (167.7 – 164.7 Mya) · Callovian (164.7 – 161.2 Mya)
Late Jurassic (161.2 – 145.5 Mya): Oxfordian (161.2 – 155.6 Mya) · Kimmeridgian 
(155.6 – 150.8 Mya) · Tithonian (150.8 – 145.5 Mya)  
Cretaceous
(145.5 – 65.5 Mya)  
Early Cretaceous (145.5 – 99.6 Mya): Berriasian (145.5 – 140.2 Mya) · 
Valanginian (140.2 – 133.9 Mya) · Hauterivian (133.9 – 130 Mya) · Barremian (130 
– 125 Mya) · Aptian (125 – 112 Mya) · Albian (112 – 99.6 Mya)
Late Cretaceous (99.6 – 65.5 Mya): Cenomanian (99.6 – 93.6 Mya) · Turonian (93.6 
– 88.6 Mya) · Coniacian (88.6 – 85.8 Mya) · Santonian (85.8 – 83.5 Mya) · 
Campanian (83.5 – 70.6 Mya) · Maastrichtian (70.6 – 65.5 Mya)  
[hide] Cenozoic (65.5 – 0 Mya)  
Paleogene, Neogene and early Pleistocene comprise former Tertiary* (65.5 – 1.8 
Mya) period. Gelasian and Calabrian comprise Early Pleistocene (2.588 Mya – 781 
kya) subepoch.  
Paleogene
(65.5 – 23.03 Mya)  
Paleocene (65.5 – 55.8 Mya): Danian (65.5 – 61.1 Mya) · Selandian (61.1 – 58.7 
Mya) · Thanetian (58.7 – 55.8 Mya)
Eocene (55.8 – 33.9 Mya): Ypresian (55.8 – 48.6 Mya) · Lutetian (48.6 – 40.4 Mya) 
· Bartonian (40.4 – 37.2 Mya) · Priabonian (37.2 – 33.9 Mya)
Oligocene (33.9 – 23.03 Mya): Rupelian (33.9 – 28.4 Mya) · Chattian (28.4 – 23.03 
Mya)  
Neogene
(23.03 – 2.588 Mya)  
Miocene (23.03 – 5.332 Mya): Aquitanian (23.03 – 20.43 Mya) · Burdigalian (20.43 
– 15.97 Mya) · Langhian (15.97 – 13.82 Mya) · Serravallian (13.82 – 11.608 Mya) 
· Tortonian (11.608 – 7.246 Mya) · Messinian (7.246 – 5.332 Mya)
Pliocene (5.332 – 2.588 Mya): Piacenzian (5.332 – 3.6 Mya) · Zanclean (3.6 – 2.588 
Mya)  
Quaternary
(2.588 – 0 Mya)  
Pleistocene (2.588 Mya – 11.4 kya): Gelasian (2.588 – 1.806 Mya) · Calabrian (1.806 
Mya – 781 kya) · Middle Pleistocene / Ionian (781 – 126 kya) · Late Pleistocene 
/ Tarantian (126 – 11.4 kya): Oldest Dryas* (18 – 14.67 kya) · Bølling* (14.67 – 
14 kya) · Older Dryas* (14 – 13.7 kya) · Allerød* (13.7 – 12.8 kya) · Younger 
Dryas* (12.8 – 11.4 kya)
Holocene (11.4 – 0 kya): Preboreal* (11.4 – 9 kya) · Boreal* (9 – 8 kya) · 
Atlantic* (8 – 5 kya) · Subboreal* (5 – 2.5 kya) · Subatlantic* (2.5 – 0 kya)  
kya = thousands years ago. Mya = millions years ago. * Not officially recognized 
by the I.C.S.  
Source: International Stratigraphic Chart. International Commission on 
Stratigraphy. Retrieved 8 February 2008.  

Retrieved from "http://en.wikipedia.org/w/index.php?title=Younger_Dryas&oldid=481627228" 

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This page was last modified on 13 March 2012 at 03:58.

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