Ice rafting history and paleoceanographic reconstructions of Core 08P23 from southern Chukchi Plateau, western Arctic Ocean since Marine Isotope Stage 3

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• 作者：Taoliang Zhang (1)
  Rujian Wang (1)
  Wenshen Xiao (1)
  Zhihua Chen (2)
  Jianfang Chen (3)
  Zhenbo Cheng (2)
  Yechen Sun (1)
  
  1. State Key Laboratory of Marine Geology ; Tongji University ; Shanghai ; 200092 ; China
  2. The First Institute of Oceanography ; State Oceanic Adiministration ; Qingdao ; 266061 ; China
  3. The Second Institute of Oceanography ; State Oceanic Adiministration ; Hangzhou ; 310012 ; China
  
• 关键词：Chukchi Plateau ; western Arctic Ocean ; Marine Isotope Stage 3 ; ice rafted detritus events ; oxygen and carbon isotope ; water mass changes
• 刊名：Acta Oceanologica Sinica
• 出版年：2015
• 出版时间：March 2015
• 年：2015
• 卷：34
• 期：3
• 页码：68-75
• 全文大小：246 KB
• 参考文献：1. Aagaard, K, Coachman, L K, Carmack, E (1981) On the halocline of the Arctic Ocean. Deep-Sea Research Part A. Oceanographic Research Papers 28: pp. 529-545 CrossRef
  2. Adler, R E, Polyak, L, Ortiz, D (2009) Sediment record from the western Arctic Ocean with an improved Late Quaternary age resolution: HOTRAX core HLY0503-8JPC, Mendeleev Ridge. Global and Planetary Change 68: pp. 18-29 CrossRef
  3. Backman, J, Jakobsson, M, L酶vlie, R (2004) Is the central Arctic Ocean a sediment starved basin?. Quaternary Science Reviews 23: pp. 1435-1454 CrossRef
  4. Bates, N R, Mathis, J T (2009) The Arctic Ocean marine carbon cycle: evaluation of air-sea CO2 exchanges, ocean acidification impacts and potential feedbacks. Biogeosciences 6: pp. 2433-2459 CrossRef
  5. Bauch, D, Carstens, J, Wefer, G (1997) Oxygen isotope composition of living Neogloboquadrina pachyderma (sin.) in the Arctic Ocean. Earth and Planetary Science Letters 146: pp. 47-58 CrossRef
  6. Bischof, J F, Clark, D L, Vincent, J S (1996) Origin of ice-rafted debris: Pleistocene paleoceanography in the western Arctic Ocean. Paleoceanography 11: pp. 743-756 CrossRef
  7. Bischof, J F, Darby, D A (1997) Mid- to Late Pleistocene ice drift in the Western Arctic Ocean: evidence for a different circulation in the past. Science 277: pp. 74-78 CrossRef
  8. Clark, D L, Whitman, R, Morgan, K A (1980) Stratigraphy and glacial-marine sediments of the Amerasian Basin, central Arctic Ocean. The Geological Society of America 181: pp. 1-65 CrossRef
  9. Comiso, J C, Steffen, K (2008) Introduction to special section on largescale characteristics of the sea ice cover from AMSR-E and other satellite sensors. Journal of Geophysical Research 113: pp. C02S01
  10. Coulthard, R D, Furze, M F A, Pie艅kowski, A J (2010) New marine 螖R values for Arctic Canada. Quaternary Geochronology 5: pp. 419-434 CrossRef
  11. Darby, D A, Bischof, J F, Jones, G A (1997) Radiocarbon chronology of depositional regimes in the western Arctic Ocean. Deep-Sea Research Part II, Topical Studies in Oceanography 44: pp. 1745-1757 CrossRef
  12. Darby, D A, Jakobsson, M, Polyak, L (2005) Icebreaker expedition collects key Arctic seafloor and ice data. EOS, Transactions American Geophysical Union 86: pp. 549-552 CrossRef
  13. Darby, D A, Naidu, A S, Mowatt, T C Sediment composition and sedimentary processes in the Arctic Ocean. In: Herman, Y eds. (1989) The Arctic Seas. Springer, New York, pp. 657-720 CrossRef
  14. Darby, D A, Zimmerman, P (2008) Ice-rafted detritus events in the Arctic during the last glacial interval, and the timing of the Innuitian and Laurentide ice sheet calving events. Polar Research 27: pp. 114-127 CrossRef
  15. Dieckmann, G S, Hellmer, H H Sea ice: an introduction to its physics, chemistry, biology and geology. In: Thomas, D N, Dieckmann, G S eds. (2003) The Importance of Sea Ice: an Overview. John Wiley & Sons, Inc, Hoboken, pp. 1-21 CrossRef
  16. Dong, L, Liu, Y, Shi, X (2014) Distributions and sources of clay minerals in the suiface sediments of the western Arctic Ocean. Haiyang Xuebao (in Chinese) 36: pp. 22-32
  17. Duplessy, J C Isotope studies. In: Gribbin, J eds. (1978) Climate Change. Cambridge University Press, Cambridge, pp. 47-67
  18. Eynaud, F (2011) Planktonic foraminifera in the Arctic: potentials and issues regarding modern and quaternary populations. Earth and Environmental Science 14: pp. 012005
  19. Fairbanks, R G, Mortlock, R A, Chiu, T C (2005) Radiocarbon calibration curve spanning 0 to 50 000 years BP based on paired 230Th/234U/238U and 14C dates on pristine corals. Quaternary Science Reviews 24: pp. 1781-1796 CrossRef
  20. Farmer, J, Cronin, T, Vernal, A (2011) Western Arctic Ocean temperature variability during the last 8 000 years. Geophysical Research Letters 38: pp. L24602 CrossRef
  21. Hanslik, D, Jakobsson, M, Backman, J (2010) Quaternary Arctic Ocean sea ice variations and radiocarbon reservoir age corrections. Quaternary Science Reviews 29: pp. 3430-3441 CrossRef
  22. Hillaire-Marcel, C, Vernal, A (2008) Stable isotope clue to episodic sea ice formation in the glacial North Atlantic. Earth and Planetary Science Letters 268: pp. 143-150 CrossRef
  23. Hillaire-Marcel, C, Vernal, A, Polyak, L (2004) Size-dependent isotopic composition of planktic foraminifers from Chukchi Sea vs. NW Atlantic sediments-implications for the Holocene paleoceanography of the western Arctic. Quaternary Science Reviews 23: pp. 245-260 CrossRef
  24. Holmes, R M, McClelland, J W, Peterson, B J (2002) A circumpolar perspective on fluvial sediment flux to the Arctic Ocean. Global Biogeochemical Cycles 16: pp. 45-1-45-14 CrossRef
  25. Jahn, A, Holland, M M (2013) Implications of Arctic sea ice changes for North Atlantic deep convection and the meridional overturning circulation in CCSM4-CMIP5 simulations. Geophysical Research Letters 40: pp. 1206-1211 CrossRef
  26. Jakobsson, M, L酶vlie, R, Al-Hanbali, H (2000) Manganese and color cycles in Arctic Ocean sediments constrain Pleistocene chronology. Geology 28: pp. 23-26 CrossRef
  27. Jones, E P (2001) Circulation in the Arctic Ocean. Polar Research 20: pp. 139-146 CrossRef
  28. Jones, A, Kaiteris, P (1983) A vacuum-gasometric technique for rapid and precise analysis of calcium carbonate in sediments and soils. Journal of Sedimentary Research 53: pp. 655-660 CrossRef
  29. Liu, W, Wang, R, Chen, J (2011) Late Quaternary terrigenous sedimentation in the Western Arctic Ocean as exemplified by a sedimentary record from the Alpha Ridge. Advances in Polar Science (in Chinese) 22: pp. 215-222
  30. L枚wemark, L, Jakobsson, M, M枚rth, M (2008) Arctic Ocean manganese contents and sediment colour cycles. Polar Research 27: pp. 105-113 CrossRef
  31. L枚wemark, L, M盲rz, C, O鈥橰egan, M (2014) Arctic Ocean Mn-stratigraphy: genesis, synthesis and inter-basin correlation. Quaternary Science Reviews 92: pp. 97-111 CrossRef
  32. Lubinski, D J, Polyak, L, Forman, S L (2001) Freshwater and Atlantic water inflows to the deep northern Barents and Kara seas since ca 13 14C ka: foraminifera and stable isotopes. Quaternary Science Reviews 20: pp. 1851-1879 CrossRef
  33. Macdonald, R C, Gobeil, C (2012) Manganese sources and sinks in the Arctic Ocean with reference to periodic enrichments in basin sediments. Aquatic Geochemistry 18: pp. 565-591 CrossRef
  34. M盲rz, C, Stratmann, A, Matthiessen, J (2011) Manganese-rich brown layers in Arctic Ocean sediments: composition, formation mechanisms, and diagenetic overprint. Geochimica et Cosmochimica Acta 75: pp. 7668-7687 CrossRef
  35. Mei, J, Wang, R, Chen, J (2012) Late Quaternary terrigenous deposits from Core P31 on the Chukchi Plateau of Western Arctic Ocean and their paleoceanographic and paleoclimatic implications. Marine Geology & Quaternary Geology (in Chinese) 32: pp. 77-86 CrossRef
  36. N酶rgaard-Pedersen, , Mikkelsen, N, Kristoffersen, Y (2007) Arctic Ocean record of last two glacial-interglacial cycles off North Greenland/Ellesmere Island-Implications for glacial history. Marine Geology 244: pp. 93-108 CrossRef
  37. O鈥橰egan, M, John, K, Moran, K (2010) Plio-Pleistocene trends in ice rafted debris on the Lomonosov Ridge. Quaternary International 219: pp. 168-176 CrossRef
  38. Parkinson, C L, Cavalieri, D J (2008) Arctic sea ice variability and trends, 1979鈥?006. Journal of Geophysical Research: Oceans (1978鈥?012) 113: pp. C07003 CrossRef
  39. Phillips, R L, Grantz, A (2001) Regional variations in provenance and abundance of ice-rafted clasts in Arctic Ocean sediments: implications for the configuration of late Quaternary oceanic and atmospheric circulation in the Arctic. Marine Geology 172: pp. 91-115 CrossRef
  40. Polyak, L, Bischof, J, Ortiz, J D (2009) Late Quaternary stratigraphy and sedimentation patterns in the western Arctic Ocean. Global and Planetary Change 68: pp. 5-17 CrossRef
  41. Polyak, L, Curry, W B, Darby, D A (2004) Contrasting glacial/interglacial regimes in the western Arctic Ocean as exemplified by a sedimentary record from the Mendeleev Ridge. Palaeogeography 203: pp. 73-93 CrossRef
  42. Polyak, L, Edwards, M H, Coakley, B J (2001) Ice shelves in the Pleistocene Arctic Ocean inferred from glaciogenic deep-sea bedforms. Nature 410: pp. 453-457 CrossRef
  43. Poore, R Z, Osterman, L, Curry, W B (1999) Late Pleistocene and Holocene meltwater events in the western Arctic Ocean. Geology 27: pp. 759-762 CrossRef
  44. Sarnthein, M, Winn, K, Jung, S J A (1994) Changes in east Atlantic deepwater circulation over the last 30000 years: eight time slice reconstructions. Paleoceanography 9: pp. 209-267 CrossRef
  45. Shackleton, N J Attainment of isotopic equilibrium between ocean water and the benthic foraminifera genus Uvigerina: isotopic changes in the ocean during the last glacial. In: Labeyrie, L eds. (1974) Variation du Climat au Cours du Pleistoc猫ne Vol: 219. Colloques Internationaux du C N R S, Paris, pp. 203-209
  46. Spielhagen, R F, Baumann, K, Erlenkeuser, H (2004) Arctic Ocean deep-sea record of northern Eurasian ice sheet history. Quaternary Science Reviews 23: pp. 1455-1483 CrossRef
  47. Spielhagen, R F, Bonani, G, Eisenhauer, A (1997) Arctic Ocean evidence for Late Quaternary initiation of northern Eurasian ice sheets. Geology 25: pp. 783-786 CrossRef
  48. Spielhagen, R F, Erlenkeuser, H (1994) Stable oxygen and carbon isotopes in planktic foraminifers from Arctic Ocean surface sediments: Reflection of the low salinity surface water layer. Marine Geology 119: pp. 227-250 CrossRef
  49. St盲rz, M, Gong, X, Stein, R (2012) Glacial shortcut of Arctic sea-ice transport. Earth and Planetary Science Letters 357鈥?58: pp. 257-267 CrossRef
  50. Stein, R, Matthie脽en, J, Niessen, F (2010) Towards a better (litho-) stratigraphy and reconstruction of Quaternary paleoenvironment in the Amerasian Basin (Arctic Ocean). Polarforschung 79: pp. 97-121
  51. Stroeve, J, Holland, M M, Meier, W (2007) Arctic sea ice decline: faster than forecast. Geophysical Research Letters 34: pp. L09501 CrossRef
  52. Thomas, D N, Dieckmann, G S (2003) Sea Ice: An Introduction to Its Physics, Chemistry, Biology and Geology. Chapter 4. Wiley-Blackwell, New York, pp. 112-141
  53. Wang, R, Xiao, W, Cheng, X (2009) Sea ice formation rates recorded in planktonic foraminiferal oxygen and carbon isotopes in the western Arctic Ocean during the late quaternary. Advances in Earth Science (in Chinese) 24: pp. 643-651
  54. Wang, R, Xiao, W, Li, W (2010) Late Quaternary ice-rafted detritus events in the Chukchi Basin, western Arctic Ocean. Chinese Sci Bull 55: pp. 432-440 CrossRef
  55. Wang, R, Xiao, W, M盲rz, C (2013) Late Quaternary paleoenvironmental changes revealed by multi-proxy records from the Chukchi Abyssal Plain, western Arctic Ocean. Global and Planetary Change 108: pp. 100-118 CrossRef
  56. Weingartner, T J, Danielson, S L, Royer, T C (2005) Freshwater variability and predictability in the Alaska Coastal Current. Deep-Sea Research Part II. Topical Studies in Oceanography 52: pp. 169-191 CrossRef
  57. Woodgate, R A, Aagaard, K, Weingartner, T J (2005) A year in the physical oceanography of the Chukchi Sea: moored, measurements from autumn 1990鈥?991. Deep-Sea Research Part II: Topical Studies in Oceanography 52: pp. 3116-3149 CrossRef
  58. Xiao, W, Wang, R, Cheng, Xinrong (2011) Stable oxygen and carbon isotopes from the planktonic foraminifera Neogloboquadrina pachyderma in the western Arctic surface sediments: implications for water mass distribution. Advances in Polar Science (in Chinese) 22: pp. 205-214
  59. Xiao, W, Wang, R, Polyak, L (2014) Stable oxygen and carbon isotopes in planktonic foraminifera Neogloboquadrina pachyderma in the Arctic Ocean: an overview of published and new surface-sediment data. Marine Geology 352: pp. 397-408 CrossRef
  60. Yurco, L N, Ortiz, J D, Polyak, L (2010) Clay mineral cycles identified by diffuse spectral reflectance in Quaternary sediments from the Northwind Ridge: implications for glacial-interglacial sedimentation patterns in the Arctic Ocean. Polar Research 29: pp. 176-197 CrossRef
  61. Zhang, Haisheng (2009) The Report of 2008 Chinese Arctic Research Expedition (in Chinese). China Ocean Press, Beijing
  
• 刊物主题：Oceanography; Climatology; Ecology; Engineering Fluid Dynamics; Marine & Freshwater Sciences; Environmental Chemistry;
• 出版者：Springer Berlin Heidelberg
• ISSN：1869-1099

文摘

Multiproxy investigations have been performed on Core 08P23 collected from the Chukchi Plateau, the western Arctic Ocean, during the Third Chinese National Arctic Expedition. The core was dated back to Marine Isotope Stage (MIS) 3 by a combination of Accelerator Mass Spectrometric (AMS) carbon-14 dating and regional core correlation. A total of five prominent ice-rafted detritus (IRD) events were recognized in MIS 2 and MIS 3. The IRD sources in MIS 3 are originated from vast carbonate rock outcrops of the Canadian Arctic Archipelago and clastic quartz in MIS 2 may have a Eurasian origin. Most 18O and 13C values of Neogloboquadrina pachyderma (sinistral) (Nps) in Core 08P23 are lighter than the average values of surface sediments. The lighter 18O and 13C values of Nps in the two brown layers in MIS 1 and MIS 3 were resulted from meltwater events; and those in the gray layers in MIS 3 were caused by the enhanced sea ice formation. The 18O values varied inversely with 13C in MIS 2 indicate that the study area was covered by thick sea ice or ice sheet with low temperature and little meltwater, which prevented the biological productivity and sea-atmosphere exchange, as well as water mass ventilation. The covaried light values of 18O and 13C in MIS 1 and MIS 3 were resulted from meltwater and/or brine injection.