Integrated Ocean Drilling Program Expedition 323 preliminary report; Bering Sea paleoceanography; Pliocene-Pleistocene paleoceanography and climate history of the Bering Sea; 5 July-4 September 2009

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doi: 10.2204/
Author(s): Ravelo, Christina; Takahashi, Kozo; Alvarez Zarikian, Carlos; Guèrin, Gilles; Liu, Tanzhuo; Aiello, Ivano; Ashahi, Hirofumi; Bartoli, Gretta; Caissie, Beth E.; Chen Muhong; Colmenero-Hidalgo, Elena; Cook, Mea S.; Dadd, Kelsie; Hugh, Youngsook; Husum, Katrine; Ijiri, Akira; Ikehara, Minoru; Kender, Sev; LaVigne, Douglas; Lund, Steve; März, Christian; Mix, Alan; Ojha, Maheswar; Okada, Makoto; Okazaki, Yusuke; Onodera, Jonaotaro; Pierre, Catherine; Radi, Taoufik; Risgaard-Petersen, Nils; Sakamoto, Tatsuhiko; Scholl, David; Schrum, Heather; Stroynowski, Zuzanna N.; Walsh, Emily A.; Wehrmann, Laura M.
Integrated Ocean Drilling Program, Expedition 323, Scientific Party, College Station, TX
Author Affiliation(s): Primary:
University of California, Santa Cruz, Ocean Sciences Department, Santa Cruz, CA, United States
Kyushu University, Japan
Texas A&M University, United States
Lamont-Doherty Earth Observatory, United States
Moss Landing Marine Laboratories, United States
University of Tokyo, Japan
Eidenössische Technische Hochschule Zürich-Zentrum, Switzerland
University of Massachusetts, United States
Chinese Academy of Sciences, China
Universidad de Salamanca, Spain
Williams College, United States
Macquarie University, Australia
Seoul National University, South Korea
University of Tromso, Norway
Japan Agency for Marine-Earth Science and Technology, Japan
Kochi University, Japan
British Geological Survey, United Kingdom
South Cobb High School, Austell, GA, United States
University of Southern California, United States
Carl von Ossietzky Universität Oldenburg, Federal Republic of Germany
Oregon State University, United States
National Geophysical Research Institute, India
Ibaraki University, Japan
Université Pierre et Marie Curie, France
Université du Québec-Montrëal, Canada
Aarhus Universitet, Denmark
University of Alaska-Fairbanks, United States
University of Rhode Island, United States
INETI, Portugal
Max Planck Institute for Marine Microbiology, Federal Republic of Germany
Source: Preliminary Report (Integrated Ocean Drilling Program), Vol.323, 201p. Publisher: IODP Management International, College Station, TX, United States. ISSN: 1932-9423
Note: In English. 92 refs.
Summary: Paleoclimate and paleoceanographic studies present opportunities to study the dynamics of the climate system by examining how it responds to external forcing (e.g., greenhouse gas and solar radiation changes) and how its interacting components generate climate oscillations and abrupt changes. Of note is the amplified recent warming of the high latitudes in the Northern Hemisphere, which is presumably related to sea ice albedo feedback and teleconnections to other regions; both the behavior of sea ice-climate interactions and the role of large-scale atmospheric and oceanic circulation in climate change can be studied with geologic records of past climate change in the Bering Sea. Over the last 5 m.y., global climate has evolved from being warm with only small Northern Hemisphere glaciers to being cold with major Northern Hemisphere glaciations every 100-40 k.y. The ultimate reasons for this major transition are unknown. Over the last hundreds of thousands of years, Milankovitch- and millennial-scale climate oscillations have occurred. Although the regional environmental changes reflected in the sediment are known in some regions, the mechanisms by which they propagate globally are not understood. Possible mechanisms responsible for both the long-term evolution of global climate as well as the generation of high-frequency climate oscillations involve processes such as intermediate water ventilation and sea ice formation in the North Pacific. However, the paucity of data in critical regions of the Pacific such as the Bering Sea has prevented an evaluation of the role of North Pacific processes in global climate change. Because North Pacific Intermediate Water (NPIW) has the potential to be influenced by dense water forming in the Bering Sea and because of the potential far-field impacts of sea ice, the Bering Sea may be critically involved in causing major climate changes. Thus, drilling in the Bering Sea may help answer questions not only about the global extent of climate trends and oscillations but about the mechanisms that produce them. In addition to having important sedimentary records of past climate change, the Bering Sea is also a region of relatively high surface productivity, elevated intermediate and deepwater nutrient concentrations, and, presumably, microbial-mediated biogeochemical cycling. Thus, Integrated Ocean Drilling Program (IODP) Expedition 323 was also dedicated to examining subseafloor biomass and microbial processes in high-productivity regions for the first time. The major objectives of Expedition 323 in the Bering Sea are 1. To elucidate a detailed evolutionary history of climate and surface ocean conditions since the earliest Pliocene in the Bering Sea, where amplified high-resolution changes of climatic signals are recorded; 2. To shed light on temporal changes in the origin and intensity of NPIW and possibly deeper water mass formation in the Bering Sea; 3. To characterize the history of continental glaciation, river discharges, and sea ice formation in order to investigate the link between continental and oceanic conditions of the Bering Sea and adjacent land areas; 4. To investigate linkages through comparison to pelagic records between ocean/climate processes that occur in the more sensitive marginal sea environment and processes that occur in the North Pacific and/or globally. This objective includes an evaluation of how the ocean/climate history of the Bering Strait gateway region may have affected North Pacific and global conditions; and 5. To constrain global models of subseafloor biomass and microbial respiration by quantifying subseafloor cell abundance and pore water chemistry in an extremely high productivity region of the ocean. We also aim to determine how subseafloor community composition is influenced by high productivity in the overlying water column. During Expedition 323 in the Bering Sea, 5741 m of sediment (97.4% recovery) was drilled at seven sites covering three different areas: Umnak Plateau, proximal to the modern Alaskan Stream entry; Bowers Ridge, proximal to the glacial Alaskan Stream entry; and the Bering Sea shelf region, proximal to the modern sea ice extent. Four deep holes were drilled that ranged in depth from 600 to 745 m below seafloor, spanning 1.9 to 5 Ma in age. The water depths ranged from 818 to 3174 m in order to characterize past vertical water mass distribution and circulation. The highlights of our findings include the following: 1. An understanding of the long-term evolution of surface water mass distribution during the past 5 m.y., including the expansion of seasonal sea ice to Bowers Ridge between 3.0 and 2.5 Ma and the intensification of seasonal sea ice at both Bowers Ridge and the Bering slope at ∼1.0 Ma, the mid-Pleistocene Transition. 2. The characterization of intermediate and deep water masses, including evidence from benthic foraminifers and sediment laminations, for episodes of low-oxygen conditions in the Bering Sea throughout the last 5 m.y. 3. The terrigenous and biogenic sedimentary history of the Bering Sea, including evidence for strong climatological and sea level control of siliciclastic deposition at all sites. Records of lithostratigraphic variations indicate that Bering Sea environmental conditions were strongly linked to global climate change; this is apparent both in long-term million year trends and in the orbital, millennial, and shorter oscillations within the lithostratigraphic records generated at sea. 4. A large range of inferred microbial activity with notable site-to-site variations, including significant activity as deep as 700 m core depth below seafloor (CSF) at the Bering slope sites, and, in contrast, very low rates of microbial-mediated sulfate reduction at Bowers Ridge.
Year of Publication: 2009
Research Program: IODP Integrated Ocean Drilling Program
Key Words: 12 Stratigraphy, Historical Geology and Paleoecology; Alaska; Algae; Bering Sea; Biostratigraphy; Boreholes; Bowers Ridge; Cenozoic; Chemostratigraphy; Climate change; Continental shelf; Continental slope; Cores; Correlation; Depositional environment; Diatoms; Drilling; Expedition 323; Foraminifera; Glacial environment; Glaciation; IODP Site U1339; IODP Site U1340; IODP Site U1341; IODP Site U1342; IODP Site U1343; IODP Site U1344; IODP Site U1345; Ice; Integrated Ocean Drilling Program; Interglacial environment; Invertebrata; Lithofacies; Lithostratigraphy; Magnetostratigraphy; Marine drilling; Microfossils; Nannofossils; Neogene; North Pacific; Northwest Pacific; Pacific Ocean; Paleo-oceanography; Paleoclimatology; Paleoenvironment; Paleomagnetism; Physical properties; Plantae; Pleistocene; Pliocene; Productivity; Protista; Quaternary; Radiolaria; Sea ice; Siliciclastics; Southwestern Alaska; Terrigenous materials; Tertiary; Umnak Plateau; United States; Well logs; West Pacific
Coordinates: N544000 N544000 W1695900 W1695900
N532400 N532400 W1793100 W1793100
N540200 N540200 E1790100 E1790100
N545000 N545000 E1765500 E1765500
N573300 N573300 W1754900 W1754900
N590300 N590300 W1791200 W1791200
N600900 N600900 W1792800 W1792800
Record ID: 2010022555
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