Expedition 374 summary

The marine-based West Antarctic Ice Sheet (WAIS) is currently locally retreating because of shifting wind-driven oceanic currents that transport warm waters toward the ice margin, resulting in ice shelf thinning and accelerated mass loss. Previous results from geologic drilling on Antarctica’s continental margins show significant variability in ice sheet extent during the late Neogene and Quaternary. Climate and ice sheet models indicate a fundamental role for oceanic heat in controlling ice sheet variability over at least the past 20 My. Although evidence for past ice sheet variability is available from ice-proximal marine settings, sedimentary sequences from the continental shelf and rise are required to evaluate the extent of past ice sheet variability and the associated forcings and feedbacks. International Ocean Discovery Program Expedition 374 drilled a latitudinal and depth transect of five sites from the outer continental shelf to rise in the central Ross Sea to resolve Neogene and Quaternary relationships between climatic and oceanic change and WAIS evolution. The Ross Sea was targeted because numerical ice sheet models indicate that this sector of Antarctica responds sensitively to changes in ocean heat flux. Expedition 374 was designed for optimal data-model integration to enable an improved understanding of Antarctic Ice Sheet (AIS) mass balance during warmer-than-present climates (e.g., the Pleistocene “super interglacials,” the mid-Pliocene, and the Miocene Climatic Optimum). The principal goals of Expedition 374 were to Evaluate the contribution of West Antarctica to far-field ice volume and sea level estimates; Reconstruct ice-proximal oceanic and atmospheric temperatures to quantify past polar amplification; Assess the role of oceanic forcing (e.g., temperature and sea level) on AIS variability; Identify the sensitivity of the AIS to Earth’s orbital configuration under a variety of climate boundary conditions; and Reconstruct Ross Sea paleobathymetry to examine relationships between seafloor geometry, ice sheet variability, and global climate. To achieve these objectives, postcruise studies will Use data and models to reconcile intervals of maximum Neogene and Quaternary ice advance and retreat with far-field records of eustatic sea level; Reconstruct past changes in oceanic and atmospheric temperatures using a multiproxy approach; Reconstruct Neogene and Quaternary sea ice margin fluctuations and correlate these records to existing inner continental shelf records; Examine relationships among WAIS variability, Earth’s orbital configuration, oceanic temperature and circulation, and atmospheric pCO2; and Constrain the timing of Ross Sea continental shelf overdeepening and assess its impact on Neogene and Quaternary ice dynamics. Expedition 374 departed from Lyttelton, New Zealand, in January 2018 and returned in March 2018. We recovered 1292.70 m of high-quality core from five sites spanning the early Miocene to late Quaternary. Three sites were cored on the continental shelf (Sites U1521, U1522, and U1523). At Site U1521, we cored a 650 m thick sequence of interbedded diamictite and diatom-rich mudstone penetrating seismic Ross Sea Unconformity 4 (RSU4). The depositional reconstructions of past glacial and open-marine conditions at this site will provide unprecedented insight into environmental change on the Antarctic continental shelf during the late early and middle Miocene. At Site U1522, we cored a discontinuous late Miocene to Pleistocene sequence of glacial and glaciomarine strata from the outer shelf with the primary objective of penetrating and dating RSU3, which is interpreted to reflect the first continental shelf–wide expansion of East and West Antarctic ice streams. Site U1523, located on the outer continental shelf, targeted a sediment drift beneath the westward-flowing Antarctic Slope Current (ASC) to test the hypothesis that changes in ASC vigor regulate ocean heat flux onto the continental shelf and thus ice sheet mass balance. We also cored two sites on the continental rise and slope. At Site U1524, we recovered a Plio–Pleistocene sedimentary sequence from the levee of the Hillary Canyon, one of the largest conduits of Antarctic Bottom Water from the continental shelf to the abyssal ocean. Site U1524 was designed to penetrate into middle Miocene and older strata, but coring was initially interrupted by drifting sea ice that forced us to abandon coring in Hole U1524A at 399.5 m drilling depth below seafloor (DSF). We moved to a nearby alternate site on the continental slope (Site U1525) to core a single hole designed to complement the record at Site U1524. We returned to Site U1524 after the sea ice cleared and cored Hole U1524C with the rotary core barrel system with the intention of reaching the target depth of 1000 m DSF. However, we were forced to terminate Hole U1524C at 441.9 m DSF because of a mechanical failure with the vessel that resulted in termination of all drilling operations and forced us to return to Lyttelton 16 days earlier than scheduled. The loss of 39% of our operational days significantly impacted our ability to achieve all Expedition 374 objectives. In particular, we were not able to recover continuous middle Miocene sequences from the continental rise designed to complement the discontinuous record from continental shelf Site U1521. The mechanical failure also meant we could not recover cores from proposed Site RSCR-19A, which was targeted to obtain a high-fidelity, continuous record of upper Neogene and Quaternary pelagic/hemipelagic sedimentation. Despite our failure to recover a continental shelf-to-rise Miocene transect, records from Sites U1522, U1524, and U1525 and legacy cores from the Antarctic Geological Drilling Project (ANDRILL) can be integrated to develop a shelf-to-rise Plio–Pleistocene transect.

[1]  B. Rosenheim,et al.  A centuries-long delay between a paleo-ice-shelf collapse and grounding-line retreat in the Whales Deep Basin, eastern Ross Sea, Antarctica , 2018, Scientific Reports.

[2]  F. Colleoni,et al.  Past continental shelf evolution increased Antarctic ice sheet sensitivity to climatic conditions , 2018, Scientific Reports.

[3]  G. Kuhn,et al.  Geochemical fingerprints of glacially eroded bedrock from West Antarctica: Detrital thermochronology, radiogenic isotope systematics and trace element geochemistry in Late Holocene glacial-marine sediments , 2018, Earth-Science Reviews.

[4]  F. Colleoni,et al.  Spatio-temporal variability of processes across Antarctic ice-bed–ocean interfaces , 2018, Nature Communications.

[5]  S. Tulaczyk,et al.  Extensive retreat and re-advance of the West Antarctic Ice Sheet during the Holocene , 2018, Nature.

[6]  John B. Anderson,et al.  Seismic and geomorphic records of Antarctic Ice Sheet evolution in the Ross Sea and controlling factors in its behaviour , 2018, Special Publications.

[7]  R. McKay,et al.  Southern Ocean warming and Wilkes Land ice sheet retreat during the mid-Miocene , 2018, Nature Communications.

[8]  S. Hemming,et al.  Evidence for a dynamic East Antarctic ice sheet during the mid-Miocene climate transition , 2017 .

[9]  Claire E Huck,et al.  Antarctic climate, Southern Ocean circulation patterns, and deep-water formation during the Eocene , 2017 .

[10]  A. Langone,et al.  Multianalytical provenance analysis of Eastern Ross Sea LGM till sediments (Antarctica): Petrography, geochronology, and thermochronology detrital data , 2017 .

[11]  P. c. Tzedakis,et al.  A simple rule to determine which insolation cycles lead to interglacials , 2017, Nature.

[12]  T. Herbert,et al.  Late Miocene global cooling and the rise of modern ecosystems , 2016 .

[13]  R. McKay,et al.  Southern Ocean phytoplankton turnover in response to stepwise Antarctic cooling over the past 15 million years , 2016, Proceedings of the National Academy of Sciences.

[14]  R. DeConto,et al.  Contribution of Antarctica to past and future sea-level rise , 2016, Nature.

[15]  R. DeConto,et al.  Dynamic Antarctic ice sheet during the early to mid-Miocene , 2016, Proceedings of the National Academy of Sciences.

[16]  B. Davy,et al.  Seismic stratigraphy along the Amundsen Sea to Ross Sea continental rise: A cross-regional record of pre-glacial to glacial processes of the West Antarctic margin , 2016 .

[17]  R. DeConto,et al.  Antarctic ice sheet sensitivity to atmospheric CO2 variations in the early to mid-Miocene , 2015, Proceedings of the National Academy of Sciences.

[18]  R. DeConto,et al.  Antarctic glacio-eustatic contributions to late Miocene Mediterranean desiccation and reflooding , 2015, Nature Communications.

[19]  K. Licht,et al.  The U-Pb detrital zircon signature of West Antarctic ice stream tills in the Ross embayment, with implications for Last Glacial Maximum ice flow reconstructions , 2014, Antarctic Science.

[20]  R. McKay,et al.  Orbital forcing of the East Antarctic ice sheet during the Pliocene and Early Pleistocene , 2014 .

[21]  R. McKay,et al.  Glaciology and geological signature of the Last Glacial Maximum Antarctic ice sheet , 2013 .

[22]  Robert B. Dunbar,et al.  Dynamic behaviour of the East Antarctic ice sheet during Pliocene warmth , 2013 .

[23]  R. DeConto,et al.  Initiation of the West Antarctic Ice Sheet and estimates of total Antarctic ice volume in the earliest Oligocene , 2013 .

[24]  A. Sluijs,et al.  Reorganization of Southern Ocean Plankton Ecosystem at the Onset of Antarctic Glaciation , 2013, Science.

[25]  John B. Anderson,et al.  Pliocene‐Pleistocene Seismic Stratigraphy of the Ross Sea: Evidence for Multiple Ice Sheet Grounding Episodes , 2013 .

[26]  John B. Anderson,et al.  Cenozoic Glacial History of the Ross Sea Revealed by Intermediate Resolution Seismic Reflection Data Combined with Drill Site Information , 2013 .

[27]  Wolfgang H Berger,et al.  Carbon Dioxide and Polar Cooling in the Miocene: The Monterey Hypothesis , 2013 .

[28]  R. Locarnini,et al.  Water Masses and Mixing Near the Antarctic Slope Front , 2013 .

[29]  John B. Anderson,et al.  Seismic Record of Late Oligocene Through Miocene Glaciation on the Central and Eastern Continental Shelf of the Ross Sea , 2013 .

[30]  C. Schneider,et al.  Morphology and Stratal Geometry of the Antarctic Continental Shelf: Insights from Models , 2013 .

[31]  F. Nitsche,et al.  The International Bathymetric Chart of the Southern Ocean (IBCSO) Version 1.0—A new bathymetric compilation covering circum‐Antarctic waters , 2013 .

[32]  Michael Schulz,et al.  Information from paleoclimate archives , 2013 .

[33]  Kenji Kawamura,et al.  Eemian interglacial reconstructed from a Greenland folded ice core , 2013, Nature.

[34]  F. Nitsche,et al.  The International Bathymetric Chart of the Southern Ocean (IBCSO) - digital chart for printing , 2013 .

[35]  E. Rohling,et al.  Relationship between sea level and climate forcing by CO2 on geological timescales , 2013, Proceedings of the National Academy of Sciences.

[36]  S. Ishman,et al.  Neogene benthic foraminiferal assemblages and paleoenvironmental record for McMurdo Sound, Antarctica , 2012 .

[37]  Ian Joughin,et al.  Ice-Sheet Response to Oceanic Forcing , 2012, Science.

[38]  Eric Rignot,et al.  A Reconciled Estimate of Ice-Sheet Mass Balance , 2012, Science.

[39]  J. Crampton,et al.  Selection and stability of quantitative stratigraphic age models: Plio-Pleistocene glaciomarine sediments in the ANDRILL 1B drillcore, McMurdo Ice Shelf , 2012 .

[40]  D. Schmitt,et al.  Neogene tectonic and climatic evolution of the Western Ross Sea, Antarctica — Chronology of events from the AND-1B drill hole , 2012 .

[41]  R. McKay,et al.  Late Cenozoic oscillations of Antarctic ice sheets revealed by provenance of basement clasts and grain detrital modes in ANDRILL core AND-1B , 2012 .

[42]  N. Golledge,et al.  Dynamics of the last glacial maximum Antarctic ice-sheet and its response to ocean forcing , 2012, Proceedings of the National Academy of Sciences.

[43]  L. D. Santis,et al.  Glacial Intensification During the Neogene: A Review of Seismic Stratigraphic Evidence from the Ross Sea, Antarctica, Continental Shelf , 2012 .

[44]  D. P. Murphy,et al.  A Cenozoic record of the equatorial Pacific carbonate compensation depth , 2012, Nature.

[45]  H. Elderfield,et al.  Evolution of Ocean Temperature and Ice Volume Through the Mid-Pleistocene Climate Transition , 2012, Science.

[46]  S. Feakins,et al.  Hydrologic cycling over Antarctica during the middle Miocene warming , 2012 .

[47]  G. Foster,et al.  The evolution of pCO2, ice volume and climate during the middle Miocene , 2012 .

[48]  R. McKay,et al.  Chronostratigraphic framework for the IODP Expedition 318 cores from the Wilkes Land Margin: Constraints for paleoceanographic reconstruction , 2012 .

[49]  P. Bart,et al.  The overdeepening hypothesis: How erosional modification of the marine-scape during the early Pliocene altered glacial dynamics on the Antarctic Peninsula's Pacific margin , 2012 .

[50]  Andrew A. Kulpecz,et al.  High tide of the warm Pliocene: Implications of global sea level for Antarctic deglaciation , 2012 .

[51]  D. Vaughan,et al.  Antarctic ice-sheet loss driven by basal melting of ice shelves , 2012, Nature.

[52]  R. DeConto,et al.  Antarctic and Southern Ocean influences on Late Pliocene global cooling , 2012, Proceedings of the National Academy of Sciences.

[53]  G. Johnson,et al.  Global Contraction of Antarctic Bottom Water between the 1980s and 2000s , 2012 .

[54]  R. McKay,et al.  Pleistocene variability of Antarctic Ice Sheet extent in the Ross Embayment , 2012 .

[55]  R. DeConto,et al.  Antarctic Ice Sheet variability across the Eocene-Oligocene boundary climate transition , 2011, Science.

[56]  P. Bart,et al.  Piston-core based biostratigraphic constraints on Pleistocene oscillations of the West Antarctic Ice Sheet in western Ross Sea between North Basin and AND-1B drill site , 2011 .

[57]  K. Panter,et al.  Early and middle Miocene Antarctic glacial history from the sedimentary facies distribution in the AND-2A drill hole, Ross Sea, Antarctica , 2011 .

[58]  K. Calvin,et al.  The RCP greenhouse gas concentrations and their extensions from 1765 to 2300 , 2011 .

[59]  S. Jacobs,et al.  Stronger ocean circulation and increased melting under Pine Island Glacier ice shelf , 2011 .

[60]  A. Klaus,et al.  Expedition 318 summary , 2011 .

[61]  K. Miller,et al.  A 180-Million-Year Record of Sea Level and Ice Volume Variations from Continental Margin and Deep-Sea Isotopic Records , 2011 .

[62]  K. Panter,et al.  Sequence stratigraphy of the ANDRILL AND-2A drillcore, Antarctica: A long-term, ice-proximal record of Early to Mid-Miocene climate, sea-level and glacial dynamism , 2011 .

[63]  Maureen E. Raymo,et al.  Departures from eustasy in Pliocene sea-level records , 2011 .

[64]  R. Leckie,et al.  Timing and magnitude of Miocene eustasy derived from the mixed siliciclastic-carbonate stratigraphic record of the northeastern Australian margin , 2011 .

[65]  A. Shevenell,et al.  Holocene Southern Ocean surface temperature variability west of the Antarctic Peninsula , 2011, Nature.

[66]  Gregory C. Johnson,et al.  Warming of Global Abyssal and Deep Southern Ocean Waters between the 1990s and 2000s: Contributions to Global Heat and Sea Level Rise Budgets* , 2010 .

[67]  S. Jacobs,et al.  Large multidecadal salinity trends near the Pacific-Antarctic Continental margin. , 2010 .

[68]  L. D. Santis,et al.  Sedimentary processes on the Wilkes Land continental rise reflect changes in glacial dynamic and bottom water flow , 2010 .

[69]  R. Kopp,et al.  Probabilistic assessment of sea level during the last interglacial stage , 2009, Nature.

[70]  J. Toggweiler,et al.  Ocean overturning since the Late Cretaceous: Inferences from a new benthic foraminiferal isotope compilation , 2009 .

[71]  R. McKay,et al.  The stratigraphic signature of the late Cenozoic Antarctic Ice Sheets in the Ross Embayment , 2009 .

[72]  L. D. Santis,et al.  West Antarctic Ice Sheet evolution: New insights from a seismic tomographic 3D depth model in the Eastern Ross Sea (Antarctica) , 2009 .

[73]  D. Harwood,et al.  Palynomorphs from a sediment core reveal a sudden remarkably warm Antarctica during the middle Miocene , 2009 .

[74]  B. Luyendyk,et al.  West Antarctic paleotopography estimated at the Eocene‐Oligocene climate transition , 2009 .

[75]  A. Orsi,et al.  A recount of Ross Sea waters , 2009 .

[76]  P. Barrett Cenozoic Climate and Sea Level History from Glacimarine Strata off the Victoria Land Coast, Cape Roberts Project, Antarctica , 2009 .

[77]  G. Kuhn,et al.  Obliquity-paced Pliocene West Antarctic ice sheet oscillations , 2009, Nature.

[78]  David Pollard,et al.  Modelling West Antarctic ice sheet growth and collapse through the past five million years , 2009, Nature.

[79]  M. Huber,et al.  Simulation of the Middle Miocene Climate Optimum , 2009 .

[80]  G. Wilson,et al.  Constraints on the amplitude of Mid-Pliocene (3.6–2.4 Ma) eustatic sea-level fluctuations from the New Zealand shallow-marine sediment record , 2009, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[81]  A. P. Wolfe,et al.  Mid-Miocene cooling and the extinction of tundra in continental Antarctica , 2008, Proceedings of the National Academy of Sciences.

[82]  M. Kominz,et al.  Late Cretaceous to Miocene sea‐level estimates from the New Jersey and Delaware coastal plain coreholes: an error analysis , 2008 .

[83]  Gregory C. Johnson,et al.  Quantifying Antarctic Bottom Water and North Atlantic Deep Water volumes , 2008 .

[84]  D. Harwood,et al.  Thinking outside the zone: High-resolution quantitative diatom biochronology for the Antarctic Neogene , 2008 .

[85]  S. Pekar,et al.  A Pleistocene warming event at 1 Ma in Prydz Bay, East Antarctica: Evidence from ODP Site 1165 , 2008 .

[86]  D. Lea,et al.  Middle Miocene ice sheet dynamics, deep‐sea temperatures, and carbon cycling: A Southern Ocean perspective , 2008 .

[87]  M. Taviani,et al.  Antarctic records of precession‐paced insolation‐driven warming during early Pleistocene Marine Isotope Stage 31 , 2008 .

[88]  Gerald R. Dickens,et al.  An early Cenozoic perspective on greenhouse warming and carbon-cycle dynamics , 2008, Nature.

[89]  E. Martin,et al.  Circulation through the Central American Seaway during the Miocene carbonate crash , 2007 .

[90]  M. Schulz,et al.  Orbitally-paced climate evolution during the middle Miocene “Monterey” carbon-isotope excursion , 2007 .

[91]  J. Diebold,et al.  Oligocene development of the West Antarctic Ice Sheet recorded in eastern Ross Sea strata , 2007 .

[92]  D. Hodell,et al.  Late Neogene history of deepwater ventilation in the Southern Ocean , 2006 .

[93]  Kerim H. Nisancioglu,et al.  Plio-Pleistocene Ice Volume, Antarctic Climate, and the Global δ18O Record , 2006, Science.

[94]  Peter Huybers,et al.  Early Pleistocene Glacial Cycles and the Integrated Summer Insolation Forcing , 2006, Science.

[95]  D. Marchant,et al.  The age and origin of the Labyrinth, western Dry Valleys, Antarctica: Evidence for extensive middle Miocene subglacial floods and freshwater discharge to the Southern Ocean , 2006 .

[96]  E. Martin,et al.  Timing and Climatic Consequences of the Opening of Drake Passage , 2006, Science.

[97]  M. Canals,et al.  Margin architecture reveals the transition to the modern Antarctic ice sheet ca. 3 Ma , 2006 .

[98]  T. Mörz,et al.  Pliocene glacial cyclicity in a deep-sea sediment drift (Antarctic Peninsula Pacific Margin) , 2006 .

[99]  K. Miller,et al.  The Phanerozoic Record of Global Sea-Level Change , 2005, Science.

[100]  H. Fricker,et al.  Tides on the Ross Ice Shelf observed with ICESat , 2005 .

[101]  J. Zachos,et al.  Marked Decline in Atmospheric Carbon Dioxide Concentrations During the Paleogene , 2005, Science.

[102]  R. Bell,et al.  Gravity anomalies of sedimentary basins and their mechanical implications: Application to the Ross Sea basins, West Antarctica [rapid communication] , 2005 .

[103]  K. Licht,et al.  Provenance of LGM glacial till (sand fraction) across the Ross embayment, Antarctica , 2005 .

[104]  T. Williams,et al.  A high‐resolution record of early Miocene Antarctic glacial history from ODP Site 1165, Prydz Bay , 2005 .

[105]  M. Raymo,et al.  A Pliocene‐Pleistocene stack of 57 globally distributed benthic δ18O records , 2005 .

[106]  A. Roberts,et al.  Magnetostratigraphic chronology of a late Eocene to early Miocene glacimarine succession from the Victoria Land Basin, Ross Sea, Antarctica , 2005 .

[107]  D. Lea,et al.  Middle Miocene Southern Ocean Cooling and Antarctic Cryosphere Expansion , 2004, Science.

[108]  D. Günther,et al.  Deep and bottom water export from the Southern Ocean to the Pacific over the past 38 million years , 2004 .

[109]  P. Bart Were West Antarctic Ice Sheet grounding events in the Ross Sea a consequence of East Antarctic Ice Sheet expansion during the middle Miocene , 2003 .

[110]  D. Hoffmann,et al.  The Pleistocene evolution of the East Antarctic Ice Sheet in the Prydz bay region: stable isotopic evidence from ODP Site 1167 , 2003 .

[111]  P. Bart,et al.  West Antarctic Ice Sheet grounding events on the Ross Sea outer continental shelf during the middle Miocene , 2003 .

[112]  G. Wefer,et al.  Evidence for orbitally controlled size variations of the East Antarctic Ice Sheet during the late Miocene , 2003 .

[113]  B. Pluijm,et al.  Neogene history of the Deep Western Boundary Current at Rekohu sediment drift, Southwest Pacific (ODP Site 1124) , 2002 .

[114]  A. Roberts,et al.  Magnetobiostratigraphic chronology and palaeoenvironmental history of Cenozoic sequences from ODP sites 1165 and 1166, Prydz Bay, Antarctica , 2002 .

[115]  E. Zambianchi,et al.  Evidence of dense water overflow on the Ross Sea shelf-break , 2002, Antarctic Science.

[116]  R. Harland,et al.  Protoperidiniacean dinoflagellate cyst taxa from the Upper Miocene of ODP Leg 178, Antarctic Peninsula , 2002 .

[117]  S. Jacobs,et al.  Freshening of the Ross Sea During the Late 20th Century , 2002, Science.

[118]  S. Jacobs,et al.  Rapid Bottom Melting Widespread near Antarctic Ice Sheet Grounding Lines , 2002, Science.

[119]  R. W. Kruk,et al.  Ocean circulation and iceberg discharge in the glacial North Atlantic: Inferences from unmixing of sediment size distributions , 2002 .

[120]  L. Bartek,et al.  Structural and tectonic evolution of the Ross Sea rift in the Cape Colbeck region, Eastern Ross Sea, Antarctica , 2001 .

[121]  A. Roberts,et al.  Orbitally induced oscillations in the East Antarctic ice sheet at the Oligocene/Miocene boundary , 2001, Nature.

[122]  N. Shackleton,et al.  Intensified deep Pacific inflow and ventilation in Pleistocene glacial times , 2001, Nature.

[123]  L. Sloan,et al.  Trends, Rhythms, and Aberrations in Global Climate 65 Ma to Present , 2001, Science.

[124]  L. D. Santis The Eastern Ross Sea continental shelf during the Cenozoic: implications for the West Antarctic ice sheet development , 1999 .

[125]  Hall,et al.  Measurement of the sortable silt current speed proxy using the Sedigraph 5100 and Coulter Multisizer IIe: precision and accuracy , 1999 .

[126]  M. Batist,et al.  Interglacial Collapse of Crary Trough-Mouth Fan, Weddell Sea, Antarctica: Implications for Antarctic Glacial History , 1999 .

[127]  N. Dunbar,et al.  Late Quaternary volcanic activity in Marie Byrd Land: Potential 40Ar/39Ar-dated time horizons in West Antarctic ice and marine cores , 1999 .

[128]  S. Tulaczyk,et al.  Pleistocene collapse of the west antarctic ice sheet , 1998, Science.

[129]  James C. Zachos,et al.  Orbitally paced climate oscillations across the Oligocene/Miocene boundary , 1997, Nature.

[130]  B. Flower,et al.  The middle Miocene climatic transition: East Antarctic ice sheet development, deep ocean circulation and global carbon cycling , 1994 .

[131]  D. Harwood,et al.  Middle Eocene to Pleistocene Diatom Biostratigraphy of Southern Ocean Sediments from the Kerguelen Plateau, Leg 120 , 1992 .

[132]  A. Tréhu,et al.  Geophysical studies of the West Antarctic Rift System , 1991 .

[133]  Karl Hinz,et al.  Cenozoic prograding sequences of the Antarctic continental margin: a record of glacio-eustatic and tectonic events , 1991 .

[134]  R. Fairbanks,et al.  Evolution of Modern Deepwater Circulation: Evidence from the Late Miocene Southern Ocean , 1991 .

[135]  J. Kennett,et al.  Latest Cretaceous to Cenozoic Climate and Oceanographic Developments in the Weddell Sea, Antarctica: an Ocean-Drilling Perspective , 1990 .

[136]  P. Barrett Antarctic Cenozoic history from the CIROS-1 drillhole, McMurdo Sound , 1990, Polar Record.

[137]  S. Savin,et al.  δ13C values of Miocene Pacific benthic foraminifera: Correlations with sea level and biological productivity , 1985 .

[138]  P. Barrett History of the Ross Sea region during the deposition of the Beacon Supergroup 400 - 180 million years ago , 1981 .

[139]  S. Jacobs,et al.  Sea-bird affinities for ocean and ice boundaries in the Antarctic , 1981 .

[140]  C. Bentley,et al.  A Model for Holocene Retreat of the West Antarctic Ice Sheet , 1978, Quaternary Research.

[141]  J. H. Mercer West Antarctic ice sheet and CO2 greenhouse effect: a threat of disaster , 1978, Nature.

[142]  J. Kennett Cenozoic evolution of Antarctic glaciation the Circum-Antarctic Ocean and their impact on global paleoceanography , 1977 .

[143]  A. B. Ford Basement Rocks of the South-Central Ross Sea, Site 270, DSDP Leg 28 , 1975 .

[144]  L. Frakes,et al.  Initial Reports of the Deep Sea Drilling Project, 28 , 1975 .

[145]  L. Frakes,et al.  Sites 270, 271, 272 , 1975 .

[146]  J. E. Andrews,et al.  Initial Reports of the Deep Sea Drilling Project , 1973 .

[147]  M. Peterson,et al.  Initial Reports of the Deep Sea Drilling Project, 2 , 1970 .

[148]  N. Weatherill,et al.  Introduction * , 1947, Nordic Journal of Linguistics.

[149]  J. Laberg,et al.  Site U1525 , 2019, Ross Sea West Antarctic Ice Sheet History.

[150]  J. L. Ash,et al.  Site U1524 , 2019, Ross Sea West Antarctic Ice Sheet History.

[151]  J. L. Ash,et al.  Site U1523 , 2019, Ross Sea West Antarctic Ice Sheet History.

[152]  J. Laberg,et al.  Site U1522 , 2019, Ross Sea West Antarctic Ice Sheet History.

[153]  L. D. Santis,et al.  Ross Sea West Antarctic Ice Sheet History , 2019, Proceedings of the International Ocean Discovery Program.

[154]  Young-Gyun Kim,et al.  Seismic stratigraphy of the Central Basin in northwestern Ross Sea slope and rise, Antarctica: Clues to the late Cenozoic ice-sheet dynamics and bottom-current activity , 2018 .

[155]  P. Barrett TEXTURAL CHARACTERISTICS OF CENOZOIC PREGLACIAL AND GLACIAL SEDIMENTS AT SITE 270 , ROSS SEA , ANTARCTICA , 2007 .

[156]  J. Diebold,et al.  Regional seismic stratigraphic correlations of the Ross Sea: Implications for the tectonic history of the West Antarctic Rift System , 2007 .

[157]  M. Rebesco,et al.  Glacial contourites on the Antarctic Peninsula margin: insight for palaeoenvironmental and palaeoclimatic conditions , 2007, Geological Society, London, Special Publications.

[158]  B. Luyendyk,et al.  Ross Sea mylonites and the timing of intracontinental extension within the West Antarctic rift system , 2004 .

[159]  R. Powell,et al.  A glacial sequence stratigraphic model for temperate, glaciated continental shelves , 2002, Geological Society, London, Special Publications.

[160]  S. Party,et al.  Leg 189 Summary , 2001 .

[161]  C. Fielding,et al.  Facies analysis and sequence stratigraphy of CRP-2/2A, Victoria Land Basin, Antarctica , 2000 .

[162]  Gregory C. Johnson,et al.  Circulation, mixing, and production of Antarctic Bottom Water , 1999 .

[163]  P. O'Brien,et al.  1. LEG 188 SYNTHESIS: TRANSITIONS IN THE GLACIAL HISTORY OF THE PRYDZ BAY REGION, EAST ANTARCTICA, FROM ODP DRILLING , 1998 .

[164]  John B. Anderson,et al.  Glaciomarine Deposits on the Continental Shelf of Ross Sea, Antarctica , 1997 .

[165]  L. Frakes Antarctic cenozoic history from the Ciros-1 drillhole, McMurdo sound: Edited by P. J. Barrett. DSIR, Wellington, 1989. ISBN 0077-961X. 254 pp. Price NZ$29.95. Softcover , 1992 .

[166]  R. Leckie,et al.  Late Paleogene and Early Neogene Foraminifers of Deep Sea Drilling Project Site 270, Ross Sea, Antarctica , 1986 .

[167]  Wallace S. Broecker,et al.  The Carbon cycle and atmospheric CO[2] : natural variations Archean to present , 1985 .

[168]  J. Weertman,et al.  Stability of the Junction of an Ice Sheet and an Ice Shelf , 1974, Journal of Glaciology.