Older Dryas

The Older Dryas was a stadial period between the Bølling and Allerød oscillations during the Pleistocene glacial period of ~11,700—12,000 uncalibrated years ago.^[1] It is named after an indicator genus, the alpine/tundra plant Dryas, which flourished during that period of time.

It was a variable cold, dry Blytt-Sernander period, observed in climatological evidence in only some regions, depending on latitude (in regions where it is not observed, the Bølling-Allerød is considered a single interstadial period). Evidence of the Older Dryas is strongest in northern Eurasia, particularly part of North Europe roughly equivalent to Pollen zone Ic.

1 Dates
2 Description
3 Flora
4 Fauna
5 Humans
6 See also
7 External links
8 References

Dates

In the Greenland oxygen isotope record, the Older Dryas appears as a downward peak establishing a small, low-intensity gap between the Bølling and the Allerød. This configuration presents a difficulty in estimating its time, as it is more of a point than a segment. But which point, and how long a segment should be assigned? The segment is small enough to escape the resolution of most C-14 series; i.e., the points are not close enough together to find it.^[2]

One approach to the problem assigns a point and then picks an arbitrary segment. You might read that the Older Dryas is "centered" near 14,100 BP or is 100 to 150 years in duration "at" 14,250 BP.

A second approach finds C-14 or other dates as close to the end of the Bølling and the beginning of the Allerød as possible and selects end points based on them. This type of date is of the form, for example, 12,000-11,800 C-14 BP uncalibrated, 14,000-13,700 BP cal.

The best approach attempts to include the Older Dryas in a sequence of points as close together as possible (high resolution), or within a known event. For example, pollen from the island of Hokkaidō in Japan records a Larix pollen peak and matching sphagnum decline at 12,400-11,800 uncal., 14,600-13700 BP cal. In the White Sea a cooling occurred at 14,700-13,400/13,000, which resulted in a readvance of the glacier in the initial Allerød. In Canada, the Shulie Lake phase (a readvance) is dated to 14,000-13,500 BP. On the other hand, varve chronology in southern Sweden indicates a range of 14,050-13,900 there.^[3]

Capturing the Older Dryas through high resolution dating continues to be of concern to researchers in climatology.

Description

Northern Europe offered an alternation of steppe and tundra environments depending on the permafrost line and the latitude. In moister regions around lakes and streams were thickets of dwarf birch, willow, sea buckthorn, and juniper. In the river valleys and uplands to the south were open birch forests.

The first trees, birch and pine, had spread into north Europe 500 years previously. During the Older Dryas, the glacier advanced again and the trees retreated southward, to be replaced by a mixture of grassland and cool-weather alpine species. This type of biome has been called “Park Tundra”, “Arctic tundra”, “Arctic pioneer vegetation” or “birch woodlands.” It exists today in the transition between taiga and tundra in Siberia. Then it stretched from Siberia to Britain in a more or less unbroken expanse.

To the northwest was the Baltic ice lake, which was truncated by the edge of the glacier. Species had access to Denmark and southern Sweden. Most of Finland and the Baltic countries were under the ice or the lake for most of the period. Northern Scandinavia was glaciated. Between Britain and the mainland were rolling hills prolifically populated with animals. Thousands of specimens, hundreds of tons of bones, have been recovered from the bottom of the North Sea, termed “doggerland”, and continue to be recovered.

The brief lists of plants and animals stated below are a fraction of the total number of species found for the period. Most families were more diverse than they are today, and were yet more so in the last interglacial. A great extinction, especially of mammals, continued throughout the end of the Pleistocene, and may be continuing today.

Flora

Older Dryas species are usually found in sediment below the bottom layer of the bog. Indicator species are the Alpine plants:

Betula pubescens or Downy birch (Central Europe);
Pinaceae or pine family (Poland);
Dryas octopetala, or dryas;
Salix herbacea, or dwarf willow;
Oxyria digyna, or mountain sorrel.

Grasslands species are:

Artemisia, sagebrush or wormwood;
Ephedra, or joint-fir.
Hippophae

Fauna

A well-stocked biozone prevailed on the Arctic plains and thickets of the late Pleistocene. Plains mammals were most predominant.

Artiodactyls:

Bison priscus, the steppe wisent or steppe bison
Rangifer tarandus, the reindeer or caribou
Megaloceros giganteus, the Irish elk
Alces alces, the elk
Cervus elaphus, the red deer
Ovibos moschatus, the musk ox
Saiga tatarica, the saiga

Perissodactyls:

Equus ferus, the wild horse. Many authors refer to it as Equus caballus, but the latter term is most correctly reserved for the domestic horse. Ferus is presumed to be one or more ancestral or related stocks to caballus and has been described as "caballine".
Coelodonta antiquitatis, woolly rhinoceros

Proboscidea:

Mammuthus primigenius, the wooly mammoth

So much meat on the hoof must have supported large numbers of Carnivora, such as:

Ursidae:

Ursus arctos, the brown bear
Ursus spelaeus, the cave bear

Hyaenidae:

Crocuta crocuta, the spotted hyena

Felidae:

Panthera spelaea, the cave lion

Canidae:

Canis lupus, the wolf
Alopex lagopus, the arctic fox

Mustelidae:

Gulo gulo, the wolverine

The sea also had its share of carnivores, which due to their maritime location, survived until modern times. Phocidae:

Pagophilus groenlandica, the harp seal
Pusa hispida, the ringed seal

Odobenidae:

Odobenus rosmarus, the walrus

Of the Cetacean Odontoceti, the Monodontidae:

Delphinapterus leucas, the beluga

Delphinidae:

Orcinus orca, the killer whale

Of the Mysticetian Eschrichtiidae:

Eschrictius robustus, the gray whale

The top of the food chain was supported by larger numbers of smaller animals farther down it, which lived in the herbaceous blanket covering the tundra or steppe and helped maintain it by carrying seeds, manuring and aerating it.

Leporidae:

Lepus tanaiticus, the hare

Ochotonidae:

Ochotona spelaeus, the pika

Cricetidae:

Lemmus obensis, Siberian lemming
Dicrostonix, collared lemming
Lagurus lagurus, steppe lemming
Microtus gregalis, narrow-headed vole
Arvicola terrestris. Water vole

Sciuridae:

Spermophilus, ground squirrel

Dipodidae:

Allactaga jaculus, the jerboa

Humans

Eurasia was populated by Homo sapiens sapiens (Cro-Magnon man) in the late Upper Paleolithic stage of tool development. Bands of humans survived by hunting the plains mammals. In north Europe they preferred reindeer; in Ukraine—the wooly mammoth. They sheltered in huts and manufactured tools around campfires. Ukrainian shelters were supported by mammoth tusks. Man was already established across Siberia and in North America.^[4]

Man did not hunt alone. Two domestic dogs, Canis familiaris, have been found in late Pleistocene Ukraine. They were a heavy breed similar to a Great Dane, perhaps of use in running down Elephantidae. The large number of mammoth bones at campsites make it clear that even then the Elephantidae in Europe were approaching the limit of their duration. Their bones were used for many purposes, not the least interesting of which are the numerous objects of art, including an engraved star map.

Late upper palaeolithic culture was by no means uniform. A large number of local traditions have been defined. The Hamburgian culture had occupied the lowlands and north Germany before the Older Dryas. During the Older Dryas, contemporaneous with the Havelte Group of the late Hamburgian, the Federmesser culture appeared and occupied Denmark and south Sweden, following the reindeer. South of the Hamburgian was the Magdalenian, which at that time was long-standing. In Ukraine was the Molodovan, which used tusks in building shelters.

External links

References

^ Curriculum: University of Arizona, Department of Palynology, References to Axel Blytt, Rutger Sernander, Gerard DeGeer, and Lenart Von Post.[1]
^ Perry, Charles A., Hsu, Kenneth A.; Geophysical, archaeological, and historical evidence support a solar-output model for climate change. Section: Model Timeline Calibration, Procedings of the National Academy of Sciences.
^ Edwige Pons-Branchu, Climatic control on speleothems growth. High precision U/Th dating of speleothems from South and East of France.
^ http://www.palaeolithic.dk/books/JAS_39/excerpt.pdf Eriksen, Berit Valentin; Reconsidering the geochronological framework of Lateglacial hunter-gatherer colonization of southern Scandinavia.

Geologic history of Earth

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.

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:

Paleozoic (542 – 251 Mya)

Cambrian (542 – 488.3 Mya)	de): 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) · de) · de) Furongian (499 – 488.3 Mya): Paibian (499 – 496 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)

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)

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.

Categories:

Wikimedia Foundation. 2010.

Игры ⚽ Нужно сделать НИР?

Look at other dictionaries:

Dryas (plant) — Dryas Dryas × suendermannii Scientific classification Kingdom: Plantae … Wikipedia
Dryas octopetala — Scientific classification Kingdom: Plantae (unranked) … Wikipedia
Dryas (disambiguation) — Dryas is the name of multiple characters in Greek mythology. Dryas may also refer to: In biology: Dryas (plant), a genus of plants Dryas (butterfly), a monotypic genus of butterflies containing the single species Dryas iulia Dryas monkey… … Wikipedia
Dryas monkey — Dryas monkey[1] Conservation status Critically Endangered (IUCN 3.1)[2 … Wikipedia
Dryas Monkey — Taxobox name = Dryas Monkey status = CR trend = unknown status system = iucn3.1 regnum = Animalia phylum = Chordata classis = Mammalia ordo = Primates familia = Cercopithecidae genus = Cercopithecus species = C. dryas binomial = Cercopithecus… … Wikipedia
Oldest Dryas — Alpine valley, like Oldest Dryas The Oldest Dryas was a climatic period, which occurred during the coldest stadial after the Weichselian glaciation in north Europe. In the Alps, the Oldest Dryas corresponds to the Gschnitz stadial of the Würm… … Wikipedia
Younger Dryas — Three temperature records, the GRIP sequence (red) showing the Younger Dryas event at around 11.0 ka BP. The vertical axis shows δ18O, which is a temperature proxy showing the water molecule isotopic composition of 18O in an ice core … Wikipedia
Allerød oscillation — The Allerød period was a warm and moist global interstadial that occurred at the end of the last glacial period. The Allerød oscillation raised temperatures (in the northern Atlantic region to almost present day levels), before they declined… … Wikipedia
Geologic time scale — This clock representation shows some of the major units of geological time and definitive events of Earth history. The Hadean eon represents the time before fossil record of life on Earth; its upper boundary is now regarded as 4.0 Ga.[1] Other… … Wikipedia
Bølling Oscillation — The Bølling Oscillation was a warm period that occurred during the final stages of the last glaciation of Europe. It corresponds to Pollen zone 1b. Named after a peat sequence discovered at Bølling lake, central Jutland, it was subsequent to the… … Wikipedia

Academic Dictionaries and Encyclopedias

Older Dryas

Contents

Dates

Description

Flora

Fauna

Humans

See also

External links

References

Look at other dictionaries:

Share the article and excerpts

Academic Dictionaries and Encyclopedias

Wikipedia

Older Dryas

Contents

Dates

Description

Flora

Fauna

Humans

See also

External links

References

Look at other dictionaries:

Share the article and excerpts

Direct link