Náttúrufræðingurinn 144 Þakkir Rannsóknamiðstöð Íslands (áður Rannsóknarráð Íslands) hefur styrkt þátt- töku Íslands í djúpborunarverkefnum á Grænlandi. Einnig hafa rannsóknar- sjóður Rannís og Tækjakaupasjóður styrkt vísindarannsóknir á djúpkjörn- unum með margvíslegum hætti. Rannsóknarsjóður Háskólans hefur einnig styrkt rannsóknirnar. Heimildir 1. Halldór Björnsson, Árný E. Sveinbjörnsdóttir, Anna K. Daníelsdóttir, Árni Snorrason, Bjarni D. Sigurðsson, Einar Sveinbjörnsson, Gísli Viggósson, Jóhann Sigurjónsson, Snorri Baldursson, Sólveig Þorvalds- dóttir & Trausti Jónsson 2008. Hnattrænar loftslagsbreytingar og áhrif þeirra á Íslandi – Skýrsla vísindanefndar um loftslagsbreytingar. Umhverfisráðuneytið. 118 bls. 2. North Greenland Ice-Core Project (NorthGRIP) Members 2004. High- resolution record of Northern Hemisphere climate extending into the last interglacial period. Nature 431. 147–151. 3. EPICA community members 2004. Eight glacial cycles from an Antarctic ice core. 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Science 259. 926–934. 16. Sowers, T. & Bender, M. 1995. Climate records covering the last degla- ciation. Science 269. 210–214. 17. Clausen, H.B., Hammer, C.U., Christensen, J., Hvidberg, C.S., Dahl- Jensen, D. Legrand, M.R. & Steffensen, J.P. 1995. 1250 years of global volcanism as revealed by central Greenland ice cores. Bls. 175–194 í: Ice core studies of global biogeochemical cycles (ritstj. Delmas, R.J.). NATO Advanced Sciences Institutes Series 1. 30. 18. Hammer, C.U., Clausen, H.B. & Dansgaard, W. 1980. Greenland ice sheet evidence of post-glacial volcanism and its climatic impact. Nature 288. 230–235. 19. Fuhrer, K., Neftel, A., Anklin, M. & Maggi, V. 1993. Continuous meas- urements of hydrogen peroxide, formaldehyde, calcium and ammoni- um concentrations along the new GRIP ice core from Summit, Central Greenland. Atmospheric Environment 27A. 1873–1880. 20. Mayewski, P.A., Meeker, L.D., Morrison, M.C., Twickler, M.S., Whitlow, S.I., Ferland, K.K., Meese, D.A., Legrand, M. & Steffensen, J.P. 1993. Greenland ice core “signal” characteristics : An expanded view of cli- mate change. Journal of Geophysical Research 98 (7). 12839–12847. 21. Dansgaard, W., Sigfús J. Johnsen, Clausen, H.B. & Langway Jr., C.C. 1971. Climatic record revealed by the Camp Century ice core. Bls. 37–56 í: The late Cenozoic glacial ages (ritstj. Turkekian, K.K.). Yale Univ. Press, New Haven. Conn. vegasaltið milli suður- og norður- hvels (e. north-south thermal see- saw) og er skýrður með breytingum á hringrás heimshafanna. Stöðvist djúpsjávarmyndun, sem á sér stað á hlýskeiðum norður af Íslandi, berst hingað norðureftir minna af hlýjum hafstraumum úr suðri. Þetta veldur snöggkólnun á norðurhveli en hægfara hlýnun og síðan kólnun í suðurhöfum og í kringum Suður- skautslandið. Summary Paleotemperature reconstruction from Greenland deep ice-cores Research on Greenland deep ice-cores shows that the ice sheet archives span at least 123,000 years of continuous paleoclimate data. The deep ice cores demonstrate that climate has been highly unstable during the last glacia- tion when temperature oscillated 25 times between 8–15 °C, with the dura- tion of the warmer episodes between 1000 to 2000 years. The warming oc- curred in a matter of decades, followed by a more gradual cooling. At the end of the last glaciation some 11,700 years ago climate changed dramatically in 3 to 50 years, depending on the variable studied. The most rapid changes are ob- served in the deuterium excess, that re- flects changes in the moisture source area, whereas changes in averaged an- nual temperature on the Greenland ice sheet varied about 8°C over 40 years. The changes from the last interglacial period, the Eemian, into the last glacial period that started some 122,000 years ago were according to the isotopic record of the NGRIP ice core much slower or about 7000 years. The last interglacial period seems to have been about 5°C warmer than at present. However, this seems not to have greatly affected the thickness of the ice sheet at the drilling sites except for the Dye-3 site located in southeast Greenland where the glacier was about 500 m lower at that time due to ice melting. Compared to the last glaciation the cur- rent Holocene epoch has been stable. When studied in detail it becomes how- ever evident that climatic changes have occurred during this 11,700 years pe- riod. The most rapid and severe change occurred 8,200 years ago, when temper- ature dropped by about 4°C for 100 to 200 years. Cold periods also occurred 11,300 years and 9,300 years ago. The warmest period during Holocene, the climatic optimum, occurred ca 9000 to 6000 years ago, followed by a gradual decline until about two millennia ago. Cold periods are evident in the ice cores at the end of the 14th and 17th centuries and the warming at the beginning of the 20th century is also very distinct. Comparison between the Greenland and Antarctic ice cores suggest that the Dansgaard-Oeschger events in Greenland are related to the Antarctic Isotope Maxima by means of the Bi- polar seesaw, triggered by North Atlantic Ocean circulation.

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