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8.2 kiloyear event


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Central Greenland reconstructed temperature.

The *8.2 kiloyear event* is the term that climatologists have adopted for
a sudden decrease in global temperatures that occurred approximately 8,200
years before the present, or c. 6200 BC , and which lasted for the next
two to four centuries. Milder than the Younger Dryas cold spell that
preceded it, but more severe than the Little Ice Age that would follow,
the 8.2 kiloyear cooling was a significant exception to general trends of
the Holocene climatic optimum .

A rapid cooling around 6200 BC was first identified by Swiss botanist
Heinrich Zoller in 1960, who named the event /Misox oscillation/ (for the
Val Mesolcina ).^[1] It is also known as /Finse event/ in Norway.^[2] Bond
/et al./ argued that the origin of the 8.2 kiloyear event is linked to a
1,500-year climate cycle ; it correlates with Bond event 5.^[3]

The strongest evidence for the event comes from the North Atlantic region;
the disruption in climate shows clearly in Greenland ice cores and in
sedimentary and other records of the temporal and tropical North
Atlantic.^[4] ^[5] ^[6] It is less evident in ice cores from Antarctica
and in South American indices.^[7] ^[8] The effects of the cold snap were
global, however, most notably in changes in sea level during the relevant
era.

The 8.2 Ka cooling event may have been caused by a large meltwater pulse
from the final collapse of the Laurentide ice sheet of northeastern North
America—most likely when the glacial Lake Ojibway & glacial Lake Agassiz
suddenly drained into the North Atlantic Ocean.^[9] ^[10] ^[11] (The same
type of action produced the Missoula floods that created the Channeled
scablands of the Columbia River basin.) The meltwater pulse may have
affected the North Atlantic thermohaline circulation , reducing northward
heat transport in the Atlantic and causing significant circum-North
Atlantic cooling. Estimates of the cooling vary and depend somewhat on the
interpretation of the proxy data, but drops of around 1 to 5 °C (1 to 11
°F )^[/clarification needed Not equivalent/] have been reported. Further
afield, some tropical records report a 3 °C (5 °F) from cores drilled
into an ancient coral reef in Indonesia .^[12] The event also caused a
global CO_2 decline of ~ 25 ppm by volume over ~ 300 years.^[13] However,
the dating and interpretation of this and other tropical sites are more
ambiguous than the North Atlantic sites.

Cooler and drier conditions prevailed, as in the Younger Dryas though less
extreme. Yet the changes may have been severe enough to impact one of the
earliest settled human communities: the first phase of Catal Huyuk ended
during the 8.2 kiloyear event. The site was abandoned and not re-occupied
until about 5 centuries later, when climate conditions had improved
markedly. This also saw increased aridity in the Middle East. Juris Zarins
has suggested the development of a Circum-Arabian Nomadic Pastoral Complex
of cultures in the period of the 6,200 BC climatic crisis, stretching from
Southern Palestine down the Red Sea shoreline and northeastward into Syria
and Iraq, which spread Proto-Semitic languages through the region^[14] .
This complex may have developed from the fusion of Harifian and
Pre-Pottery Neolithic B cultures in Southern Palestine.

As Harifian used the Outacha retouch point technique found earlier in the
Fayyum , it has been suggested that Proto-Semitic may have come from Egypt
across the Sinai.^[15] Given the fact that Semitic is most closely related
to the Ancient Egyptian language of all the Afro-Asiatic languages,^[16]
this origin is also distinctly possible.

Drier conditions were notable in North Africa , while East Africa suffered
five centuries of general drought . In West Asia and especially
Mesopotamia , the 8.2ky event was a three-hundred year aridification and
cooling episode, which provided the natural force for Mesopotamian
irrigation agriculture and surplus production that were essential for the
earliest class-formation and urban life. However multi-centennial changes
around the same period are difficult to link specifically to the
approximately 100-year abrupt event as recorded most clearly in the
Greenland ice cores.

The initial meltwater pulse has caused between 0.5 and 4 meters of
sea-level rise . Based on estimates of lake volume and decaying ice cap
size, values of 0.4 - 1.2 meters (1-4 ft) circulate. Based on sea-level
data from below modern deltas 2 - 4 (6-12 ft) meters of near-instantaneous
rise is estimated, recorded superimposed on background 'normal'
post-glacial sea-level rise. ^[17] Meltwater pulse sea level rise was
experienced fully at great distance from the release area. Gravity and
rebound effects associated to the shifting of watermasses make that the
sea-level fingerprint is smaller in areas closer to the Hudson Bay. The
Mississippi delta records ~20%, NW Europe records ~70% and Asia records
~105% of the global averaged amount.^[18] . The cooling of the 8200 event
was a temporary feature, the sea-level rise of the meltwater pulse was
permanent.

In 2003, the Office of Net Assessment at the United States Department of
Defense was commissioned to produce a study on the likely and potential
effects of a modern climate change.^[19] The study, conducted under ONA
head Andrew Marshall , modelled its prospective climate change on the 8.2
kiloyear event, precisely because it was the middle alternative between
the Younger Dryas and the Little Ice Age. The study caused a controversy
when it was made public in 2004.^[20]


[edit ] See also

* 1500-year climate cycle 
* Antarctic Cold Reversal 
* Little Ice Age 
* Older Peron 
* Piora Oscillation 
* Sahara pump theory 
* Younger Dryas 
* sea-level rise 


[edit ]
References

1. *^ * Zoller, Heinrich (1960).
"Pollenanalytische Untersuchungen zur Vegetationsgeschichte der
insubrischen Schweiz" (in German). /Denkschriften der
Schweizerischen Naturforschenden Gesellschaft/ *83*: 45–156. ISSN
0366-970X
. 
2. *^ * Nesje, Atle; Dahl, Svein Olaf
(2001). "The Greenland 8200 cal. yr BP event detected in
loss-on-ignition profiles in Norwegian lacustrine sediment
sequences". /Journal of Quaternary Science/ *16* (2): 155–166. doi
:10.1002/jqs.567
. 
3. *^ * Bond, G.; /et al./ (1997). "A
Pervasive Millennial-Scale Cycle in North Atlantic Holocene and
Glacial Climates"
.
/Science / *278* (5341): 1257–1266. doi
:10.1126/science.278.5341.1257
.
http://rivernet.ncsu.edu/courselocker/PaleoClimate/Bond%20et%20al.,%201997%20Millenial%20Scale%20Holocene%20Change.pdf. 
4. *^ * Alley, R. B.; /et al./ (1997). "Holocene
climatic instability; a prominent, widespread event 8,200 yr ago"
.
/Geology/ *25* (6): 483–486. doi
:10.1130/0091-7613(1997)0252.3.CO;2
.
http://geology.geoscienceworld.org/cgi/content/abstract/25/6/483. 
5. *^ * Alley, Richard B.; Ágústsdóttir, Anna Maria
(2005). "The 8k event: cause and consequences of a major Holocene
abrupt climate change". /Quaternary Science Reviews/ *24* (10-11):
1123–1149. doi
:10.1016/j.quascirev.2004.12.004
. 
6. *^ * Sarmaja-Korjonen, Kaarina; Seppa, H. (2007).
"Abrupt and consistent responses of aquatic and terrestrial
ecosystems to the 8200 cal. yr cold event: a lacustrine record
from Lake Arapisto, Finland". /The Holocene/ *17* (4): 457–467.
doi :10.1177/0959683607077020
. 
7. *^ * Burroughs, William J. [ed.] (2003). /Climate:
Into the 21st Century/. Cambridge: Cambridge University Press.
ISBN  0521792029
. 
8. *^ * Ljung, K.; /et al./ (2007). "South Atlantic
island record reveals a South Atlantic response to the 8.2kyr
event" .
/Climate of the Past/ *4*: 35–45.
http://www.clim-past.net/4/35/2008/cp-4-35-2008.html. 
9. *^ * Ehlers, Jürgen; Gibbard, Philip L. (2004).
/Quaternary Glaciations – Extent and Chronology. Part II: North
America/. Amsterdam: Elsevier. pp. 257–262. ISBN
0444515925
. 
10. *^ * Barber, D. C.; /et al./ (1999). "Forcing of the
cold event 8,200 years ago by catastrophic drainage of Laurentide
Lakes". /Nature / *400*: 344–348. doi
:10.1038/22504
. 
11. *^ * Ellison, Christopher R. W.; Chapman, Mark R.;
Hall, Ian R. (2006). "Surface and Deep Ocean Interactions During
the Cold Climate Event 8200 Years Ago". /Science
/ *312* (5782): 1929–1932. doi
:10.1126/science.1127213
. 
12. *^ * Fagan, Brian (2004). /The Long Summer: How
Climate Changed Civilization/. New York: Basic Books. pp. 107–108.
ISBN  0465022812
. 
13. *^ * Wagner, Friederike; /et al./ (2002). "Rapid
atmospheric CO_2 changes associated with the 8,200-years-B.P.
cooling event". /PNAS
/ *99* (19):
12011–12014. doi
:10.1073/pnas.182420699
. 
14. *^ * Zarins, Juris (1990), "Early Pastoral Nomadism
and the Settlement of Lower Mesopotamia" (/Bulletin of the
American Schools of Oriental Research/), No. 280 (Nov., 1990), pp.
31-65
15. *^ * Midant-Reynes, Beatrix (2000), /The Prehistory
of Egypt: From the First Egyptians to the First Pharaohs/
(Wiley-Blackwell)
16. *^ * Ehret, Christopher, op cit.
17. *^ * Hijma, Marc P.; Cohen, Kim M.
(March 2010). "Timing and magnitude of the sea-level jump
preluding the 8.2 kiloyear event"
. /Geology/
*38* (3): 275–278.
http://geology.gsapubs.org/content/38/3/275.abstract. 
18. *^ * Kendall, Roblyn A.; Mitrovica,
J.X., Milne, G.A., Törnqvist, T.E., Li, Y., (May 2008). "The
sea-level fingerprint of the 8.2 ka climate event"
. /Geology/
*36* (5): 423–426.
http://geology.gsapubs.org/content/36/5/423.abstract. 
19. *^ * Schwartz, Peter; Randall, Doug
(October 2003). /An Abrupt Climate Change Scenario and Its
Implications for United States National Security/
.
http://www.grist.org/pdf/AbruptClimateChange2003.pdf. 
20. *^ * Stripp, David (February 9, 2004). "The
Pentagon's Weather Nightmare"
.
/Fortune /.
http://money.cnn.com/magazines/fortune/fortune_archive/2004/02/09/360120/index.htm.