DOCSLIB.ORG

Załączniki 6

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Załączniki 6 Zał ącznik 6. Sprawozdanie z XXXII Wyprawy Antarktycznej PAN dr Marek Gola Wydział geologii UW, oraz dr Szymon Ostrowski Prince Charles Mountains, E Antarctica . Russian Polish joint geologic and geomorphologic expedition. Prince Charles Mountains, Mac Robertson Land, East Antarctica. December 2007 - March 2008 53 RAE Autors Szymon Ostrowski, geologist, Polish Academy of Science Marek Gola, geologist, Polish Academy of Science 1. The aim of expedition Prince Charles Mountains are unique, and only East Antarctica area, where sedimentary rocks of Late Paleozoic to Early Mesozoic (Amery Group - Mond 1972) are outcropping. Moreover, Cenozoic deposits (Pagodroma Group - Hambrey and McKelvey 2000) are well developed and preserved in this area. Record of Cenozoic deglaciation, as well as rocks of post-glacial Perm and Triassic sedimentary basin can be clearly recognized (fig. 1). Fig. 1. Area of operation Although many expeditions, Russian and Australian, were held in the area of Prince Charles Mountains, sedimentary rocks of Amery Group and Pagodroma Group, were of marginal interests. Detailed sedimentological studies on Amery Group rocks, combined with geochemical researches of coal deposits, allow to reconstruct changes of sedimentary regimes, climatic impact and regional tectonic regimes in, supposedly post-glacial, sedimentary basin of Lambert Graben, - the prominent structural feature of southern Gondwana (Federov et al. , 1982). Sratigraphy of the Amery Group is based mainly on lithostratigraphic division so far, thus the attempt to establish biostratigraphic time scale will be made, on the basis of samples collected. Systematic studies of different subdivisions of Cenozoic Pagodroma Group will contribute to recognize glacial history of Antarctica during Cenozoic. Most sediments of Pagodroma Group are of glacimarine origin (Bardin 1982; Hambrey and McKelvey 2000), and their thicknesses are substantial. Main aim of the study is to establish chronology of Pagodroma Group, which might be subsequently correlated with chronology of glacial history already recognized on Antarctic Peninsula. Fragments of fauna detritus will be used for biostratigraphic and possibly geochronologic dating. Sedimentologic observations were held to recognize minute changes of glaciomarine environments. Preliminary researches held on Larsemann Hills were concentrated on thin, contemporary sedimentary cover and diminutive geomorphologic processes. Researches of this cover were neglected as far, and scientific questions aroused, might be the basis of further investigations. In addition, samples of stomach oil, from snow petrel ( Pagodroma nivea ) abandoned nests were collected in all visited sites. Geochemical dating of the layered, relatively thick beds of stomach oil, may allow to estimate the time of settling nests, which corresponds to deglaciation of the area. 2. Area of operation Fisher Massif Fisher Massif is isolated, uplifted mountain block in the central Prince Charles Mountains (Mac. Robertson Land). It extends from north-east to south-west, is 30 km long and 13 km wide. The massif is composed of Proterozoic metamorphic rocks with substantial Cenozoic cover (Laiba and Pushina, 1997). Amery Oasis The Amery Oasis is an ice-free area in northernmost part of the Prince Charles Mountains. Amery Oasis is located on the western side of Lambert Glacier and is composed of numerous massifs. The basement of Amery Oasis is composed of Proterozoic metamorphic rocks, which are covered by Permian and Triassic and Neogene sediments. Larsemann Hills Larsemann Hills are the cluster of ice free peninsulas and islands on the Ingrid Christensen Coast in Prydz Bay. Larsemann Hills basement is composed of Precambrian metamorphic rocks - metasedimentary gneisses and Paleozoic intrusive rocks - granite (Stüwe et al. , 1989). Quaternary deposit cover is thin and patchy. 3. Methods In all sites visited, detailed sections of sedimentary rocks were made. Sedimentary and lithologic observations were completed. Parallel sections of the same interval of deposits allowed to recognize lateral facies changes. All sections were sampled for further petrographic and geochemical analysis. Paleonthologic samples were collected for possible biostratigraphic dating. 4. Sections 4.1 Cenozoic sections Cenozoic deposits from Prince Charles Mountains are referred as Pagodroma Group (Hambrey and McKelvey 2000). It is believed that deposits are of glaciomarine origin (Laiba and Pushina 1997; Hambrey and McKelvey 2000, McKelvey et .al . 2001) and are composed mainly of unconsolidated or unconsolidated diamictites and subordinary tillites. The Pagodroma Group is divided into four formations. Fisher Bench Formation and Mount Johnston Formation are outcropping on Fisher Massif, Bardin Bluffs Formation and Battye Glacier Formation, outcropping on the Amery Oasis. Stratigraphic range of Pagodroma Group is not precisely defined. Some microfossils found, are suggesting Miocene for Fisher Bench Formation (Laiba and Pushina 1997) and from Lower Miocene or Oligocene for Mt. Johnston Formation to Pliocene for Battye Formation (McKelvey et .al . 2001) 4.1.1 Fisher Bench Formation Fisher Bench Formation outcrops along the southeastern edge of Fisher Massif (fig. 2). Altitude of its base is slightly descending to northeast along the Massif. It is ranging from nearly 350 m asl on the south to less than 100 m asl on the central and north part of the Massif. Thickness of deposits is reaching up to 370 m. Fig. 2. Schematic map of Fisher Massif Five sections of Fisher Bench Formation were researched. Four of them in the south- eastern part of Fisher Massif (sections over Skaly Jugo-vastotshnyje ) and one on north-eastern part of the Massif (attachment 1). Sections can be hardly correlated with each other, even on short distances. Sediments composing Fisher Bench Formation are unsorted, poorly consolidated or unconsolidated diamictites, sandy and aleuritic (fig. 3). Subordinate layers of sand, aleurites and gravel can be found. In general, clasts derived from Fisher Massif (mostly dark metabazites) are poorly rounded, while clasts of rocks absent on the massif are moderately, or seldom well rounded. Layering of sediments is insignificant, or absent. Sedimentary structures are strongly obscured by slope processes. Only sedimentary structures noticed in diamictites, were horizons of flat, horizontally oriented cobbles (residual?) in finer grained diamictites (fig. 4), and horizons of well sorted, densely packed gravel with shell detritus. Fig. 3. Outcrops of Fisher Bench Formation Fig. 4. Horizon of flat, horizontally oriented cobbles in finer grained diamictites A set of sedimentary structures can be found in sand and aleurite horizons. Low angle cross lamination, channel cross lamination and subordinate ripplemark lamination are noticed in sand horizons in the basal parts of sections. Aleurite horizons are massif or horizontally laminated. Lamination is centimeter scale and is manifested by following dark and light-grey layers. Individual example of diminutive flow erosion structure (whirl erosion) was found in aleurite facies. Siderite concretions were found in one of the sections within aleuritic facies. Insignificant, 30-meter scale alternations of diamictites of sandy and aleuritic matrix were recognized in one of the sections. Interpretation of these alternations as fining upward cycles is tempting, however no distinctive boundaries of them can be found. Thus such interpretation can not be properly supported. Sections of Fisher Bench Formation are hardly corelatable, even on short distances. Neither diamictite sets, nor aleuritic parts of sections can be followed on distances bigger than 100-200 meters. Thus mentioned sets must be regarded as lenses. Boulder horizons continuing for over 0,5 km were noticed. Sand layers are located in the bottom of sections. Distribution of sand, its thickness is varying laterally The thickest sand horizon has been found in the section D, located in front of the mouth of small valley eroded in basement (Dolina Parallelnaja ). The thickness of the sand horizon is gradually decreasing southward. Sand content in diamictitesets reveal the same regularity. It might be suggested, that Paralelnaja valley was the source of sand material during the deposition of Fisher Bench Formation. The change of angularity of bigger grains was noticed along the outcrops. Mean angularity of clasts is decreasing on southern part of outcrop, where basement rocks forming step edge (paleorelief) close to the outcrop. 4.1.2. Mount Johnston ( Nadkarovaja ) Formation Mount Johnston Formation outcrops on the southern slope of Nadkarovaja Mt. on Fisher Massif. Outcrops are laterally distributed along the edge of Kar Bolshoy, about 2 km from east to west. The deposits are horizontal and their thickness do not exceed 100 m. Basis of the formation is on the altitude of 1360 m asl and erosional top is on 1450 m asl. One section researched, located to the east of Mt. Nadkarovaja top, covers whole formation depositional record (attachment 2). Sediments composing Mt Johnston Formation are unsorted, unconsolidated diamictites of sandy matrix. Clasts are moderately to well rounded, up to 30 cm in diameter, composed mainly of felsitic igneous rocks and gneisses. Clasts of locally derived, unrounded rocks are predominant only in the vicinity of the top of Nadkarovaja Mt (erosional relict of basement). Layering of the deposits is hardly visible. Finer grained diamictites are absent in the section. Only one horizon
Load more

Recommended publications
  • Glacio-Lacustrine Aragonite Deposition, Meltwater Evolution And
    Antarctic Science 19 (3), 365–372 (2007) & Antarctic Science Ltd 2007 Printed in the UK DOI: 10.1017/S0954102007000466 Glacio-lacustrine aragonite deposition, meltwater evolution and glacial history during isotope stage 3 at Radok Lake, Amery Oasis, northern Prince Charles Mountains, East Antarctica IAN D. GOODWIN1 and JOHN HELLSTROM2 1Environmental and Climate Change Research Group, School of Environmental and Life Sciences, University of Newcastle, Callaghan, NSW 2308, Australia 2School of Earth Sciences, University of Melbourne, Parkville, VIC 3010, Australia [email protected] Abstract: The late Quaternary glacial history of the Amery Oasis, and Prince Charles Mountains is of significant interest because about 10% of the total modern Antarctic ice outflow is discharged via the adjacent Lambert Glacier system. A glacial thrust moraine sequence deposited along the northern shoreline of Radok Lake between 20–10 ka BP, overlies a layer of thin, aragonite crusts which provide important constraints on the glacial history of the Amery Oasis. The modern Radok Lake is fed by the terminal meltwaters of the alpine Battye Glacier. The aragonite crusts were deposited in shallow water of ancestral Radok Lake 53 ka BP,during the A3 warm event in Isotope Stage 3. Oxygen isotope (d18O) analysis of the last glacial-age aragonite crusts 18 indicates that they precipitated from freshwater with a d OSMOW composition of -36%, which is 8% more depleted than the present water (-28%) in Radok Lake. A regional oxygen isotope (d18O) and elevation relationship for snow is used to determine the source of meltwater and glacial ice in Radok Lake during the A3 warm event.
    [Show full text]
  • Boeckella Poppei and Gladioferens Antarcticus I.A.E
    View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by University of Tasmania Open Access Repository Antarctic Science 15 (4): 439–448 (2003) © Antarctic Science Ltd Printed in the UK DOI: 10.1017/S0954102003001548 Taxonomy, ecology and zoogeography of two East Antarctic freshwater calanoid copepod species: Boeckella poppei and Gladioferens antarcticus I.A.E. BAYLY1,2, J.A.E. GIBSON3,4*, B. WAGNER5 and K.M. SWADLING4 1School of Biological Sciences, Monash University, VIC 3800, Australia 2501 Killiecrankie Rd, Flinders Island, TAS 7255, Australia 3Institute of Antarctic and Southern Ocean Studies, University of Tasmania, Private Bag 77, Hobart, TAS 7001, Australia 4School of Zoology, University of Tasmania, Private Bag 5, Hobart, TAS 7001, Australia 5Institute for Geophysics and Geology, Faculty for Physics and Geoscience, University Leipzig, Talstrasse 35, D-04103 Leipzig, Germany *corresponding author: [email protected] Abstract: New populations of the two species of calanoid copepods known to inhabit freshwater lakes in East Antarctica, Boeckella poppei (Mrázek, 1901) and Gladioferens antarcticus Bayly, 1994, have recently been discovered. The morphology of the populations of B. poppei showed significant differences, notably a reduction in the armature of the male fifth leg, when compared with typical specimens from the Antarctic Peninsula and South America. Gladioferens antarcticus had previously been recorded from a single lake in the Bunger Hills, but has now been recorded from three further lakes in this region. A recent review of Antarctic terrestrial and limnetic zooplankton suggested that neither of these species can be considered an East Antarctic endemic, with B.
    [Show full text]
  • New Zircon U∓Pb and Hf∓Nd Isotopic Constraints on the Timing of Magmatism, Sedimentation and Metamorphism in the N
    Precambrian Research 299 (2017) 15–33 Contents lists available at ScienceDirect Precambrian Research journal homepage: www.elsevier.com/locate/precamres New zircon U–Pb and Hf–Nd isotopic constraints on the timing of magmatism, sedimentation and metamorphism in the northern Prince Charles Mountains, East Antarctica ⇑ Xiaochun Liu a, , Yue Zhao a, Hong Chen a, Biao Song b a Institute of Geomechanics, Chinese Academy of Geological Sciences, Beijing 100081, China b Beijing SHRIMP Centre, Institute of Geology, Chinese Academy of Geological Sciences, Beijing 100037, China article info abstract Article history: The northern Prince Charles Mountains (PCM) in East Antarctica represent the largest continuously Received 17 April 2017 exposed section of the Rayner Complex and may provide important insights into the tectonic evolution Revised 10 July 2017 of the Rayner orogen. We present new U–Pb and Hf isotopic data for zircons from felsic orthogneisses, Accepted 13 July 2017 mafic granulites, paragneisses and charnockites and additional Nd isotopic data for the former two rock Available online 15 July 2017 types from the Beaver Lake area in the northern PCM. Zircons from the felsic orthogneisses document protolith ages of ca. 1170–1070 Ma, with Hf and Nd model ages of 1.99–1.74 Ga, suggesting the genera- Keywords: tion of the felsic magmas by partial melting of crustal rocks that were extracted from the mantle during Zircon the Paleoproterozoic. Detrital zircons from one paragneiss sample yield a major age population at ca. Magmatic age Depositional age 1480–1140 Ma and three subordinate populations at ca. 2130–1850, 1780–1620 and 1010–860 Ma, Metamorphic age whereas those from another paragneiss sample produce a major age population at ca.
    [Show full text]
  • Boeckella Poppei and Gladioferens Antarcticus I.A.E
    Antarctic Science 15 (4): 439–448 (2003) © Antarctic Science Ltd Printed in the UK DOI: 10.1017/S0954102003001548 Taxonomy, ecology and zoogeography of two East Antarctic freshwater calanoid copepod species: Boeckella poppei and Gladioferens antarcticus I.A.E. BAYLY1,2, J.A.E. GIBSON3,4*, B. WAGNER5 and K.M. SWADLING4 1School of Biological Sciences, Monash University, VIC 3800, Australia 2501 Killiecrankie Rd, Flinders Island, TAS 7255, Australia 3Institute of Antarctic and Southern Ocean Studies, University of Tasmania, Private Bag 77, Hobart, TAS 7001, Australia 4School of Zoology, University of Tasmania, Private Bag 5, Hobart, TAS 7001, Australia 5Institute for Geophysics and Geology, Faculty for Physics and Geoscience, University Leipzig, Talstrasse 35, D-04103 Leipzig, Germany *corresponding author: [email protected] Abstract: New populations of the two species of calanoid copepods known to inhabit freshwater lakes in East Antarctica, Boeckella poppei (Mrázek, 1901) and Gladioferens antarcticus Bayly, 1994, have recently been discovered. The morphology of the populations of B. poppei showed significant differences, notably a reduction in the armature of the male fifth leg, when compared with typical specimens from the Antarctic Peninsula and South America. Gladioferens antarcticus had previously been recorded from a single lake in the Bunger Hills, but has now been recorded from three further lakes in this region. A recent review of Antarctic terrestrial and limnetic zooplankton suggested that neither of these species can be considered an East Antarctic endemic, with B. poppei being listed as a recent anthropogenic introduction and G. antarcticus a ‘marine interloper’. We conclude differently: B. poppei has been present in isolated populations in East Antarctica for significant lengths of time, possibly predating the current interglacial, while G.
    [Show full text]
  • Early Diagenetic Siderite in the Panorama Point Beds (Radok Conglomerate, Early to Middle Permian), Prince Charles Mountains, East Antarctica
    vol. 31, no. 2, pp. 169–194, 2010 doi: 10.4202/ppres.2010.10 Early diagenetic siderite in the Panorama Point Beds (Radok Conglomerate, Early to Middle Permian), Prince Charles Mountains, East Antarctica Krzysztof P. KRAJEWSKI 1,3*, Nikolai A. GONZHUROV 2, Anatoly A. LAIBA2 and Andrzej TATUR3 1 Instytut Nauk Geologicznych PAN, Twarda 51/55, 00−818 Warszawa, Poland <[email protected]> *corresponding author 2 Polar Marine Geological Research Expedition, Pobedy 24, 198412 St. Petersburg, Russia 3 Zakład Biologii Antarktyki PAN, Ustrzycka 10/12, 02−141 Warszawa, Poland Abstract: The Panorama Point Beds represent a subfacies of the Early to Middle Permian Radok Conglomerate, which is the oldest known sedimentary unit in the Prince Charles Mountains, MacRobertson Land, East Antarctica. This unit records clastic sedimentation in fresh−water depositional system during the early stages of development of the Lambert Graben, a major structural valley surrounded by crystalline highlands in the southern part of Gondwana. It contains common siderite precipitated through early diagenetic processes in the swamp, stagnant water, and stream−flow environments. There are two types of siderite in the Panorama Point Beds: (1) disseminated cement that occurs throughout the sedimentary suc− cession; and (2) concretions that occur at recurrent horizons in fine−grained sediments. The cement is composed of Fe−depleted siderite (less than 90 mol % FeCO3) with an elevated con− d13 tent of magnesium, and trace and rare earth elements. It has negative CVPDB values (−4.5 to −1.5‰). The concretions are dominated by Fe−rich siderite (more than 90 mol % FeCO3), with d13 positive CVPDB values (+1 to +8‰).
    [Show full text]
  • Glacio-Lacustrine Aragonite Deposition, Meltwater Evolution And
    Antarctic Science 19 (3), 365–372 (2007) & Antarctic Science Ltd 2007 Printed in the UK DOI: 10.1017/S0954102007000466 Glacio-lacustrine aragonite deposition, meltwater evolution and glacial history during isotope stage 3 at Radok Lake, Amery Oasis, northern Prince Charles Mountains, East Antarctica IAN D. GOODWIN1 and JOHN HELLSTROM2 1Environmental and Climate Change Research Group, School of Environmental and Life Sciences, University of Newcastle, Callaghan, NSW 2308, Australia 2School of Earth Sciences, University of Melbourne, Parkville, VIC 3010, Australia [email protected] Abstract: The late Quaternary glacial history of the Amery Oasis, and Prince Charles Mountains is of significant interest because about 10% of the total modern Antarctic ice outflow is discharged via the adjacent Lambert Glacier system. A glacial thrust moraine sequence deposited along the northern shoreline of Radok Lake between 20–10 ka BP, overlies a layer of thin, aragonite crusts which provide important constraints on the glacial history of the Amery Oasis. The modern Radok Lake is fed by the terminal meltwaters of the alpine Battye Glacier. The aragonite crusts were deposited in shallow water of ancestral Radok Lake 53 ka BP,during the A3 warm event in Isotope Stage 3. Oxygen isotope (d18O) analysis of the last glacial-age aragonite crusts 18 indicates that they precipitated from freshwater with a d OSMOW composition of -36%, which is 8% more depleted than the present water (-28%) in Radok Lake. A regional oxygen isotope (d18O) and elevation relationship for snow is used to determine the source of meltwater and glacial ice in Radok Lake during the A3 warm event.
    [Show full text]
  • Prydz Bay Region, East Antarctica J.M
    Antarctic Science 18 (1), 83–99 (2006) © Antarctic Science Ltd Printed in the UK DOI: 10.1017/S0954102006000083 A review of the Cenozoic stratigraphy and glacial history of the Lambert Graben–Prydz Bay region, East Antarctica J.M. WHITEHEAD1*, P.G. QUILTY2, B.C. MCKELVEY3 and P.E. O’BRIEN4 1Institute of Antarctic and Southern Ocean Studies, University of Tasmania, Private Bag 77, Hobart, TAS 7001, Australia 2School of Earth Sciences University of Tasmania, Private Bag 79, Hobart, TAS 7001, Australia 3Division of Earth Sciences, University of New England, Armidale, NSW 2351, Australia 4Geoscience Australia, GPO Box 378, Canberra, ACT 2601, Australia *[email protected] Abstract: 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. Received 1 December 2004, accepted 15 July 2005 Key words: glaciation, ice sheet, Milankovitch, Prince Charles Mountains Introduction Study area In recent years there has been considerable investigation of This paper reviews the Cenozoic stratigraphy of the the Cenozoic geology of the Lambert Graben and Prydz Antarctic continent and margin from 60°E to 80°E.
    [Show full text]
  • Glacio-Lacustrine Aragonite Deposition
    Antarctic Science 19 (3), 365–372 (2007) & Antarctic Science Ltd 2007 Printed in the UK DOI: 10.1017/S0954102007000466 Glacio-lacustrine aragonite deposition, meltwater evolution and glacial history during isotope stage 3 at Radok Lake, Amery Oasis, northern Prince Charles Mountains, East Antarctica IAN D. GOODWIN1 and JOHN HELLSTROM2 1Environmental and Climate Change Research Group, School of Environmental and Life Sciences, University of Newcastle, Callaghan, NSW 2308, Australia 2School of Earth Sciences, University of Melbourne, Parkville, VIC 3010, Australia [email protected] Abstract: The late Quaternary glacial history of the Amery Oasis, and Prince Charles Mountains is of significant interest because about 10% of the total modern Antarctic ice outflow is discharged via the adjacent Lambert Glacier system. A glacial thrust moraine sequence deposited along the northern shoreline of Radok Lake between 20–10 ka BP, overlies a layer of thin, aragonite crusts which provide important constraints on the glacial history of the Amery Oasis. The modern Radok Lake is fed by the terminal meltwaters of the alpine Battye Glacier. The aragonite crusts were deposited in shallow water of ancestral Radok Lake 53 ka BP,during the A3 warm event in Isotope Stage 3. Oxygen isotope (d18O) analysis of the last glacial-age aragonite crusts 18 indicates that they precipitated from freshwater with a d OSMOW composition of -36%, which is 8% more depleted than the present water (-28%) in Radok Lake. A regional oxygen isotope (d18O) and elevation relationship for snow is used to determine the source of meltwater and glacial ice in Radok Lake during the A3 warm event.
    [Show full text]
  • Limnology and Sedimentary Record of Radok Lake, Amery Oasis, East Antarctica
    Published in: Fütterer, D K, Damaske, D, Kleinschmidt, G, Miller, H & Tessensohn, F (eds.), Antarctica: contributions to global earth sciences, Springer, Berlin, Heidelberg, New York, 45-54 http://dx.doi.org/10.1007/3-540-32934-X The original publication is available at http://www.springerlink.com see http://dx.doi.org/10.1007/3-540-32934-X_57 Data are available at: http://dx.doi.org/10.1594/PANGAEA.605211 Limnology and Sedimentary Record of Radok Lake, Amery Oasis, East Antarctica 1 2 Bernd Wagner & Holger Cremer 1 University of Leipzig, Institute for Geophysics and Geology, Talstraße 35, 04103 Leipzig, Germany, <[email protected]> 2 Utrecht University, Department of Palaeoecology, Laboratory of Palaeobotany and Palynology, Budapestlaan 4, 3584 CD Utrecht, The Netherlands Present address: Netherlands Organization of Applied Scientific Research TNO, Core area Built Environment and Geosciences, Geological Survey of the Netherlands, Princetonlaan 6, 3584 CB Utrecht, The Netherlands, <[email protected]> Abstract. Radok Lake in Amery Oasis, East Antarctica, has a water depth of ca. 360 m, making it the deepest non-subglacial lake in Antarctica. Limnological analyses revealed that the lake had, despite a 3 m thick ice cover, a completely mixed water column during austral summer 2001/2002. High oxygen contents, low ion concentrations, and lack of planktonic diatoms throughout the water column indicate that Radok Lake is ultra- oligotrophic today.The late glacial and postglacial lake history is documented in a succession of glacial, glaciolimnic, and limnic sediments at different locations in the lake basin. The sediments record regional differences and past changes in allochthonous sediment supply and lake productivity.
    [Show full text]
  • Cryptic Diversity of a Glossopteris Forest: the Permian Prince Charles Mountains Floras, Antarctica
    CRYPTIC DIVERSITY OF A GLOSSOPTERIS FOREST: THE PERMIAN PRINCE CHARLES MOUNTAINS FLORAS, ANTARCTICA by Ben James Slater A thesis submitted to the University of Birmingham for the degree of DOCTOR OF PHILOSOPHY School of Geography, Earth and Environmental Sciences College of Life and Environmental Sciences University of Birmingham September 2013 University of Birmingham Research Archive e-theses repository This unpublished thesis/dissertation is copyright of the author and/or third parties. The intellectual property rights of the author or third parties in respect of this work are as defined by The Copyright Designs and Patents Act 1988 or as modified by any successor legislation. Any use made of information contained in this thesis/dissertation must be in accordance with that legislation and must be properly acknowledged. Further distribution or reproduction in any format is prohibited without the permission of the copyright holder. ABSTRACT The Toploje Member chert is a Roadian to Wordian autochthonous– parautochthonous silicified peat preserved within the Lambert Graben, East Antarctica. It preserves a remarkable sample of terrestrial life from high-latitude central Gondwana prior to the Capitanian mass extinction event from both mega- and microfossil evidence that includes cryptic components rarely seen in other fossil assemblages. The peat layer is dominated by glossopterid and cordaitalean gymnosperms and contains sparse herbaceous lycophytes, together with a broad array of dispersed organs of ferns and other gymnosperms. The peat also hosts a wide range of fungal morphotypes, Peronosporomycetes, rare arthropod remains and a diverse coprolite assemblage. The fungal and invertebrate-plant interactions associated with various organs of the Glossopteris plant reveal the cryptic presence of a ‘component community’ of invertebrate herbivores and fungal saprotrophs centred around the Glossopteris organism, and demonstrate that a multitude of ecological interactions were well developed by the Middle Permian in high-latitude forest mires.
    [Show full text]
  • Neoproterozoic Deformation in the Radok Lake Region of the Northern Prince Charles Mountains, East Antarctica; Evidence for a Single Protracted Orogenic Event
    Precambrian Research 104 (2000) 1–24 www.elsevier.com/locate/precamres Neoproterozoic deformation in the Radok Lake region of the northern Prince Charles Mountains, east Antarctica; evidence for a single protracted orogenic event S.D. Boger a,*, C.J. Carson b, C.J.L. Wilson a, C.M. Fanning c a School of Earth Sciences, The Uni6ersity of Melbourne, Park6ille, Vic. 3010, Australia b Department of Geology and Geophysics, Yale Uni6ersity, New Ha6en, CT 06511, USA c Research School of Earth Sciences, The Australian National Uni6ersity, Canberra, ACT. 0200, Australia Received 7 May 1999; accepted 14 April 2000 Abstract Ion microprobe dating of structurally constrained felsic intrusives indicate that the rocks of the northern Prince Charles Mountains (nPCMs) were deformed during a single, long-lived Neoproterozoic tectonic event. Deformation evolved through four progressively more discrete phases in response to continuous north–south directed compression. In the study area (Radok Lake), voluminous granite intrusion occurred at 990 Ma, contemporaneous with regionally extensive magmatism, peak metamorphism, and sub-horizontal shearing and recumbent folding. Subse- quent upright folding and shear zone development occurred at 940 Ma, while new zircon growth at 900 Ma constrains a final phase of deformation that was accommodated along low-angle mylonites and pseudotachylites. This final period of deformation was responsible for the allochthonous emplacement of granulites over mid-amphibolite facies rocks in the nPCMs. The age constraints placed on the timing of deformation by this study preclude the high-grade reworking of the nPCMs as is postulated in some of the recent literature. Furthermore, 990–900 Ma orogenesis in the nPCMs is at least 50 Myr younger than that recognised in other previously correlated Grenville aged orogenic belts found in Australia, east Africa and other parts of the Antarctic.
    [Show full text]
  • USGS Open-File Report 2007-1047, Extended Abstract 216, 5 P
    U.S. Geological Survey and The National Academies; USGS OF-2007-1047, Extended Abstract 216 A new view of the stratigraphy and geological framework of the Amery Group, Radok and Beaver Lake area, northern Prince Charles Mountains, East Antarctica Pavel I. Lunev, Andrew I. Pogorelsky, and Vladimir F. Ilyin Polar Marine Geological Research Expedition, Pobedy str. 24, Lomonosov, Saint-Petersburg, Russian Federation. ([email protected]) Summary This paper reviews new information on the stratigraphy and distribution of the Permian-Triassic Amery Group strata based on field mapping between 2002 and 2006 by Russian Antarctic Expeditions. The conducted research allowed us to find out new information about the stratigraphy and the character of the relations between the stratigraphic units of the Amery Group. The total thickness of these strata lies between 2865 and 3015 m. The distribution of formations and their members is shown in the accompanying map. Citation: Lunev, P.I., A.I. Pogorelsky and V.F. Ilyin (2007), A new alternative view on the stratigraphy and the geological framework of the Permian-Triassic deposits of the Amery Group, Radok and Beaver Lake area, northern Prince Charles Mountains, East Antarctica; in Antarctica: A Keystone in a Changing World – Online Proceedings of the 10th ISAES, edited by A.K. Cooper and C.R. Raymond et al., USGS Open-File Report 2007-1047, Extended Abstract 216, 5 p. Introduction Gently dipping sedimentary rocks in the area of the Beaver Lake were first described by Crohn in 1957. He reported a thick sedimentary succession of arkosic sandstones with coal beds and a Permian palynoassemblage as the Amery Formation.
    [Show full text]