Academic literature on the topic 'Prydz Bay'

Fossil diatom-bearing marine sediment cores recovered from Prydz Channel, Prydz Bay, record episodes of glacial advance and retreat in the bay. Diatom frustules are abundant, well preserved, and the species composition is diverse in two biogenic sediment units composed of siliceous diatom ooze (SMO-1 and SMO-2). Between SMO-1 and SMO-2 a terrigenous unit (T) is present, composed of muddy diamicton and sandy silty clay, which contains poorly preserved rare diatoms. The SMO units are interpreted to represent an open marine setting with seasonal sea ice cover; the T unit is interpreted to represent glacial ice expansion from the Amery Ice Shelf over the site. Based on an age model developed previously for other cores from Prydz Channel with analogous stratigraphies, we interpret our record to be late Quaternary through Holocene in age. The T unit records the Last Glacial Maximum (LGM) in Prydz Bay; the SMO-1 and SMO-2 units record interstadial episodes that are post- and pre-LGM respectively. Extinct diatom taxa in the T and SMO-2 units indicate reworked sediment sourced from two different-aged deposits. Our results provide both a new interpretation of late Quaternary deposition in Prydz Channel and support for previous studies in this region.

The Cenozoic glacial history of East Antarctica is recorded in part by the stratigraphy of the Prydz Bay—Lambert Graben region. The glacigene strata and associated erosion surfaces record at least 10 intervals of glacial advance (with accompanying erosion and sediment compaction), and more than 17 intervals of glacial retreat (enabling open marine deposition in Prydz Bay and the Lambert Graben). The number of glacial advances and retreats is considerably less than would be expected from Milankovitch frequencies due to the incomplete stratigraphic record. Large advances of the Lambert Glacier caused progradation of the continental shelf edge. At times of extreme glacial retreat, marine conditions reached > 450 km inland from the modern ice shelf edge. This review presents a partial reconstruction of Cenozoic glacial extent within Prydz Bay and the Lambert Graben that can be compared to eustatic sea-level records from the southern Australian continental margin.

The minimum total breeding seabird biomass in the Australian Antarctic Territory was estimated to be 9,971.1 t, dominated by Emperor Penguins, 3,863 t (38.7%) and Adélie Penguins, 5,825 t (58.4%). The 5° sector between 75°E and 80°E, in south-east Prydz Bay, held 35% of the total AAT seabird biomass. Prydz Bay has been shown to be an area of high productivity, and the concentration of seabird biomass in this area reflects the high biomass of prey species and the availability of nesting habitat in the Vestfold Hills, a large ice-free area adjacent to Prydz Bay. Activities associated With research stations are believed to be the only factors that have impacted on breeding seabird populations to date, but minerals activities, tourism and support facilities, and a Krill fishery, are future conservation issues that will have an impact on this major concentration of seabird biomass in East Antarctica.

A marine survey in Prydz Bay, provides an unparalleled view of glacigenic and marine sedimentation across Prydz Channel and Amery Depression during the Late Quaternary. Gravity cores and a suite of eight radiocarbon dates indicate that the Late Wisconsin Glacial Maximum (LGM) was associated with grounding of a palaeo-ice shelf along the periphery of Prydz Channel. Deposition in front of the grounding line was dominated by ice-rafting. A granulated facies, containing angular clay and diamicton clasts, was producd by a combination of regelation freezing, near to the grounding line, and remelting of this basal debris in the sub-ice shelf setting. Beneath these LGM marine deposits lie two key beds of diatom ooze that are distinct in size sorting and Pliocene diatoms. These “interstadial” units can be traced across most of the Prydz Channel, and are underlain by additional glacial marine units. Debris related to the Lambert Deep is distinct from detritus from eastern Prydz Bay and deposition of these two sources within the channel oscillated during the LGM. We suggest that coastal drainage systems contributed to a limited glaciation of the shelf during the LGM, rather than direct outflow via the Lambert/Amery system. It is proposed that shelf-wide glaciation is related to the duration of glacial sea level lowstands rather than the absolute magnitude of eustatic fall during such episodes.

AbstractDuring Leg 119 of the Ocean Drilling Program, between December 1987 and February 1988, six holes were drilled in the Kerguelen Plateau, southern Indian Ocean, and five in Prydz Bay at the mouth of the Amery Ice Shelf, on the East Antarctic continental shelf. The Prydz Bay holes, reported here, form a transect from the inner shelf to the continental slope, recording a prograding sequence of possible Late Paleozoic to Eocene continental sediments of fluvial aspect, followed by several hundred metres of Early Oligocene (possibly Middle Eocene) to Quaternary glaciallydominated sediments. This extends the known onset of large-scale glaciation of Antarctica back to about 36–40 million years ago, the sedimentary record suggesting that a fully developed East Antarctic Ice Sheet reached the coast at Prydz Bay at this time, and was more extensive than the present sheet. Subsequent glacial history is complex, with the bulk of sedimentation in the outer shelf taking place close to the grounding line of an extended Amery Ice S helf. However, breaks in the record and intervals of no recovery may hide evidence of periods of glacial retreat.

In January 1985 a net sampling survey was carried out on the distribution and abundance of euphausiid larvae in the Prydz Bay region. Euphausia superba occurred in low abundance, probably due to sampling preceding the main spawning period. Thysanoessa macrura occurred throughout the study area in consistently high abundance. Euphausia crystallorophias was marginally more abundant within its restricted range. Distinct north-south variations in larval age and developmental stages of T. macrura were observed indicating regional differences in spawning. Euphausia frigida was mainly confined to the upper 200 m of the Antarctic Circumpolar Current. E. superba larvae produced north of the shelf break, between 70°–83°E, moved north-east into the Antarctic Circumpolar Current. Larvae originating on the shelf moved rapidly west in the East Wind drift. E. crystallorophias had the same westward dispersion, but some larvae appeared to return eastward via the Prydz Bay Gyre and remain in the region. The data indicate that most E. superba larvae, providing they survive injuries cold temperature an food deprivation, will leave the area, suggests that Prydz Bay krill may not be a self maintaining stock.

Based on satellite remote sensing, several polynyas have been found in Prydz Bay, East Antarctica. Compared with the Mackenzie Bay Polynya, the only polynya in the west, the polynyas in eastern Prydz Bay have a larger area and higher ice production, but have never been studied individually. In this study, four recurrent polynyas were identified in eastern Prydz Bay from sea ice concentration data during 2002–2011. Their areas generally exhibit synchronous temporal variations and have good correlation with wind speed, which indicates that they are primarily wind-driven polynyas that need at least one stationary ice barrier to block the inflow of drifting sea ice. The components of the ice barriers of these four polynyas were identified through comparison of satellite remote sensing visible images and synthetic aperture radar images. All types of fast ice, including landfast ice, offshore fast ice and ice fingers serving as ice barriers for these polynyas are anchored by an assemblage of small icebergs and have an approximately year-round period of variations that also regulates the variability of polynyas. The movement and grounding of giant icebergs near the polynyas significantly affects the development of the polynyas. The results of this study illustrate the important impact of icebergs on Antarctic wind-driven polynyas and the formation of dense shelf water.

Partial melting has been proposed as a mechanism for producing the low aH₂O conditions characteristic of granulites, but the extent to which melts produced by water-undersaturated partial melting can be removed from granulite-facies migmatite complexes is less well understood. Three leucogneiss suites produced by water-undersaturated partial melting under high temperature, moderate pressure (6Kbar, 860°C), granulite-facies conditions have been distinguished on the basis of geochemistry and petrography. Type 1 Leucogneisses from the Brattstrand Bluffs coastline, eastern Antarctica, have near minimum-melt major element compositions (high SiO₂, low Fe₂O₃, MgO) low Zr, Th and LREE concentrations, positive Eu anomalies and limited entrained residual material, suggesting efficient segregation of small melt volumes before equilibration with the source. The limited dissolution of accessory phases in water-undersaturated melts has led to a concentration of monazite and zircon and high LREE concentrations in melanosomes. Melting depleted the plagioclase component of the metapelite source rocks almost completely, producing melts with high Eu concentrations. Granitic melts formed under vapour-present conditions are unlikely to show such extreme LREE and HREE depletion or positive Eu anomalies, even at high degrees of partial melting. Type 2 Leucogneisses have high Fe₂O₃, MgO and TiO₂ contents and were formed at higher degrees of melting than the Type 1 Leucogneisses. Consequently they were more viscous, less extractable and more likely to entrain restitic and peritectic phases as the metapelitic source rocks lost their coherence. Type 3 Leucogneisses have strongly enriched Zr, Th and LREE abundances, negative Eu anomalies, and Zr/Zr^* and LREE_t/LREE_t^* >1 resulting from preferential accessory phase entrainment.

The Antarctic plays an important role in the global climate system. On the one hand, the Antarctic Ice Sheet is the largest freshwater reservoir on Earth. On the other hand, a major proportion of the global bottom-water formation takes place in Antarctic shelf regions, forcing the global thermohaline circulation. The main goal of this dissertation is to provide new insights into the dynamics and stability of the EAIS during the Quaternary. Additionally, variations in the activity of bottom-water formation and their causes are investigated. The dissertation is a German contribution to the International Polar Year 2007/ 2008 and was funded by the ‘Deutsche Forschungsgesellschaft’ (DFG) within the scope of priority program 1158 ‘Antarctic research with comparative studies in Arctic ice regions’. During RV Polarstern expedition ANT-XXIII/9, glaciomarine sediments were recovered from the Prydz Bay-Kerguelen region. Prydz Bay is a key region for the study of East EAIS dynamics, as 16% of the EAIS are drained through the Lambert Glacier into the bay. Thereby, the glacier transports sediment into Prydz Bay which is then further distributed by calving icebergs or by current transport. The scientific approach of this dissertation is the reconstruction of past glaciomarine environments to infer on the response of the Lambert Glacier-Amery Ice Shelf system to climate shifts during the Quaternary. To characterize the depositional setting, sedimentological methods are used and statistical analyses are applied. Mineralogical and (bio)geochemical methods provide a means to reconstruct sediment provenances and to provide evidence on changes in the primary production in the surface water column. Age-depth models were constructed based on palaeomagnetic and palaeointensity measurements, diatom stratigraphy and radiocarbon dating. Sea-bed surface sediments in the investigation area show distinct variations in terms of their clay minerals and heavy-mineral assemblages. Considerable differences in the mineralogical composition of surface sediments are determined on the continental shelf. Clay minerals as well as heavy minerals provide useful parameters to differentiate between sediments which originated from erosion of crystalline rocks and sediments originating from Permo-Triassic deposits. Consequently, mineralogical parameters can be used to reconstruct the provenance of current-transported and ice-rafted material. The investigated sediment cores cover the time intervals of the last 1.4 Ma (continental slope) and the last 12.8 cal. ka BP (MacRobertson shelf). The sediment deposits were mainly influenced by glacial and oceanographic processes and further by biological activity (continental shelf), meltwater input and possibly gravitational transport. Sediments from the continental slope document two major deglacial events: the first deglaciation is associated with the mid-Pleistocene warming recognized around the Antarctic. In Prydz Bay, the Lambert Glacier-Amery Ice Shelf retreated far to the south and high biogenic productivity commenced or biogenic remains were better preserved due to increased sedimentation rates. Thereafter, stable glacial conditions continued until 400 - 500 ka BP. Calving of icebergs was restricted to the western part of the Lambert Glacier. The deeper bathymetry in this area allows for floating ice shelf even during times of decreased sea-level. Between 400 - 500 ka BP and the last interglacial (marine isotope stage 5) the glacier was more dynamic. During or shortly after the last interglacial the LAIS retreated again due to sea-level rise of 6 - 9 m. Both deglacial events correlate with a reduction in the thickness of ice masses in the Prince Charles Mountains. It indicates that a disintegration of the Amery Ice Shelf possibly led to increased drainage of ice masses from the Prydz Bay hinterland. A new end-member modelling algorithm was successfully applied on sediments from the MacRobertson shelf used to unmix the sand grain size fractions sorted by current activity and ice transport, respectively. Ice retreat on MacRobertson Shelf commenced 12.8 cal. ka BP and ended around 5.5 cal. ka BP. During the Holocene, strong fluctuations of the bottomwater activity were observed, probably related to variations of sea-ice formation in the Cape Darnley polynya. Increased activity of bottom-water flow was reconstructed at transitions from warm to cool conditions, whereas bottom-water activity receded during the mid- Holocene climate optimum. It can be concluded that the Lambert Glacier-Amery Ice Shelf system was relatively stable in terms of climate variations during the Quaternary. In contrast, bottom-water formation due to polynya activity was very sensitive to changes in atmospheric forcing and should gain more attention in future research.
Die Antarktis spielt im globalen Umweltsystem eine tragende Rolle. Mit ihrem mächtigen Eispanzer ist sie nicht nur der größte Süsswasserspeicher auf der Erde, in ihren Schelfregionen wird auch ein Großteil der globalen Bodenwassermassen gebildet, welche die globale thermohaline Zirkulation antreiben. Hauptziel dieser Arbeit, welche einen deutschen Beitrag zum Internationalen Polarjahr 2007/ 2008 liefert, war es, neue Erkenntnisse hinsichtlich der Stabilität des Ostantarktischen Eisschildes während des Quartärs zu liefern. Weiterhin sollten Aussagen über Variationen in der Bildung von Antarktischem Bodenwasser und deren Ursachen getroffen werden. Dazu wurde im Rahmen der ‚Polarstern‘ Expedition ANT-XXIII/9 eine Beprobung glaziomariner Sedimente zwischen Prydz Bucht und Kerguelen Plateau durchgeführt. Diese Region eignet sich zur Untersuchung der Ostantarktischen Eisdynamik besonders gut, da hier der Lambert Gletscher, etwa 16% des Ostantarktischen Eispanzers drainiert. Er transportiert dabei Sediment nach Norden, das schließlich die Prydz Bucht erreicht und durch direkten Transport über kalbende Eisberge oder durch Umlagerung und Verteilung mithilfe von Meeresströmungen weiter verfrachtet wird. Der wissenschaftliche Ansatz dieser Arbeit besteht darin, über die Verteilung dieser Sedimente in Raum und Zeit, d.h. über Variationen des glaziomarinen Paläoregimes, die Reaktion des Lambert Gletschers und des vorgelagerten Amery Schelfeises auf Klimaschwankungen während des Quartärs zu rekonstruieren. Dabei werden sowohl sedimentologische Methoden unter Einbeziehung neuer statistischer Möglichkeiten angewandt, um Sedimentationsprozesse zu charakterisieren, als auch mineralogische und (bio)geochemische Parameter verwendet, um Aussagen über die Herkunft der Sedimente und Änderungen in der Produktivität im Oberflächenwasser treffen zu können. Die Altersbestimmung der Sedimentkerne erfolgte mittels Paläomagnetik, Paläointensitäten, Biostratigraphie und Radiokarbondatierungen. Die Oberflächensedimente im Untersuchungsgebiet zeigen deutliche Unterschiede sowohl hinsichtlich ihrer Tonmineral- als auch Schwermineralzusammensetzung. Beide mineralogischen Parameter zeigen die größten Differerenzen auf dem Schelf. Dort lassen sich deutlich Sedimente der Prydz Bucht von Sedimenten des MacRobertson Shelfes differenzieren. Sie stellen daher ein gutes Hilfsmittel dar, um sowohl die Herkunft von eis- als auch strömungstransportiertem Material zu rekonstruieren. Die untersuchten Sedimentkerne decken den Zeitraum der letzten 1,4 Millionen Jahre (Kontinentalhang) bzw. der letzten 12,8 tausend kal. Jahre v. H. ab (MacRobertson Schelf). Die abgelagerten Sedimente wurden i. W. durch glaziale und ozeanographische Einflüsse geprägt, aber auch durch Bioproduktion (Schelf) bzw. durch Schmelzwassereinträge und möglicherweise gravitative Prozesse (Kontinentalhang). In den Sedimenten des Kontinentalhangs sind zwei starke Enteisungsereignisse überliefert: Das erste Ereignis steht mit dem mittelpleistozänen Klimaoptimum in Verbindung, das auch in anderen antarktischen Regionen nachgewiesen wurde. Es führte in der Prydz Bucht zu einem weitreichenden Rückzug des Lambert Gletscher-Amery Schelfeises (LAIS) und gleichzeitig zu einer hohen Primärproduktion. Danach herrschten bis etwa 400 - 500 tausend Jahre v. H. stabile glaziale Bedingungen. Kalbung von Eisbergen war wahrscheinlich auf den westlichen Teil des Lambert Gletschers begrenzt, wo eine tiefere Bathymetrie auch bei niedrigerem globalen Meeresspiegel noch Aufschwimmen des Gletschereises erlaubt. Zwischen 400 - 500 tausend Jahren v. H. und vermutlich dem letzten Interglazial wurde der Gletscher schließlich wieder dynamischer, um mit oder kurz nach dem letzten Interglazial (Meeresspiegel etwa 6 - 9 m höher) eine weitere Phase deutlichen Rückzuges zu durchlaufen. Beide Ereignisse lassen sich mit Phasen der Eisreduktion in den Prinz Charles Bergen korrelieren, d.h. der Rückzug des Lambert Gletschers hatte möglicherweise ein erhöhtes Nachfließen von Eismassen aus dem Hinterland zur Folge. An den Sedimenten des Schelfkernes wurde ein neu entwickeltes Verfahren der Endmember-Modellierung erfolgreich getestet. Der Eisrückzug auf dem MacRobertson Schelf begann etwa 12,8 tausend kal. Jahre v. H. und war gegen 5,5 tausend kal. Jahre v. H. abgeschlossen. Während des Holozäns kam es zu starken Schwankungen in der Bodenwasseraktivität, die höchst wahrscheinlich mit der Neubildungsrate von Meereis in der Kap Darnley Polynia in Zusammenhang stehen. Besonders auffallend war eine erhöhte Bodenwasseraktivität am Übergang von Warm- zu Kaltphasen bzw. ihr extremer Rückgang während des Mittel-Holozänen Klimaoptimums. Insgesamt zeigen die Ergebnisse der Arbeit, dass sich das LAIS während des Quartärs relativ stabil gegenüber Klimaveränderungen verhalten hat. Die Bodenwasserproduktion in Polynien dagegen reagierte sehr empfindlich auf relative geringe atmosphärische Veränderungen und bedarf in Zukunft verstärkter Aufmerksamkeit.

Abstract This thesis examines the Mid-Pliocene climatic extreme ca. three million years ago (Ma) which was the latest longtime warm period. It is an important topic because the climate back then was warmer compared with the present. The bipolar regions are studied because they represent the largest areas that control the global climate. This study is based on clay mineral research that may significantly improve our knowledge of the Mid-Pliocene climate when combined with other palaeoenvironmental data. The paleoclimatological objectives of this study were: 1) to investigate how clay minerals reflect the Mid-Pliocene Global Warmth event, 2) to study ice sheet development at high latitudes, especially in East-Antarctica, and the history of ice rafting and sea ice, especially in the Arctic Ocean. This thesis deals with the clay mineral distribution and compositional analysis of the Pliocene-aged marine sediment sequences provided by the Ocean Drilling Program (ODP). The first studied site, Site 1165, is located at the continental rise of Prydz Bay, East Antarctica, and the second studied site, Site 911, is located at the Yermak Plateau, north of Svalbard, in the Arctic Ocean. The Pliocene smectite clay minerals at Site 1165 were mainly derived from Antarctic continental sources and transported to the site primarly by bottom currents related to warm events during the last 5 Ma. The evidence obtained in this study shows that the East Antarctic ice sheet may have been a dynamic ice sheet during the past 5 Ma, especially during the Mid-Pliocene. The results from the Mid-Pliocene possibly suggest a general warming trend. Based on the composition of the heavy minerals and clay minerals, at Site 911, the Pliocene smectite clay minerals were mainly transported within sea ice by the Siberian branch of the Transpolar Drift. The results indicate a warming trend at approximately 3 Ma after which they indicate a shift back to glacial conditions. Based on this study, the Mid-Pliocene Global Warmth can be observed in both the Arctic and Antarctic regions.