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The East Greenland Current and its contribution to the Denmark Strait overflow (2002)

Rudels, B. ; Fahrbach, Eberhard ; Meincke, J. ; [et al.]

In: EPIC3ICES Journal of Marine Science, 59, pp. 1133-1154

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Publication Date: 2019-07-17

Description: AbstractThe East Greenland Current is the main conduit for the waters of the Arctic Ocean and the Nordic Seas to the North Atlantic. In addition to low salinity Polar Surface Water and sea ice, the East Greenland Current transports deep and intermediate waters exiting the Arctic Ocean and Atlantic Water re-circulating in the Fram Strait. These water masses are already in the Fram Strait and are dense enough to contribute to the Denmark Strait overflow and to the North Atlantic Deep Water. On its route along the Greenland slope the East Greenland Current exchanges waters with the Greenland and Iceland Seas and incorporates additional intermediate water masses. In 1998 RV "Polarstern" and RV "Valdivia" occupied hydrographic sections on the Greenland continental slope from the Fram Strait to south of the Denmark Strait, crossing the East Greenland Current at nine different locations. The Arctic Ocean waters and the re-circulating Atlantic Water could be followed to just north of Denmark Strait, where the East Greenland Current encounters the northward-flowing branch of the Irminger Current. There strong mixing occurs both within the East Greenland Current and between the waters of the two currents. No distinct contribution from the Iceland Sea was observed in the Denmark Strait but the temperature reduction of the warm core of the East Greenland Current just north of the strait could partly have been caused by mixing with the colder Iceland Sea Arctic Intermediate Water. The overflow plume south of the sill was stratified and covered by a low salinity lid. Less saline overflow water was also observed on the upper part of the slope. The less saline part of the overflow was identified as Polar Intermediate Water and its properties were similar to those of the thermocline present in the East Greenland Current already in the Fram Strait. It is thus conceivable that its source is the upper (〈0) part of the Arctic Ocean thermocline. Copyright 2002 International Council for the Exploration of the Sea. Published by Elsevier Science Ltd. All rights reserved.Author Keywords: Arctic Ocean, Denmark Strait overflow, East Greenland Current, Nordic Seas, T-S analysis, water masses.

Repository Name: EPIC Alfred Wegener Institut

Type: Article , isiRev

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Understanding the variability of clear-sky outgoing long-wave radiation based on ship-based temperature and water vapour measurements (2006)

John, V. O. ; Buehler, S. A. ; Engeln, A. ; [et al.]

In: EPIC3Quarterly journal of the royal meteorological societyB(621), 132, pp. 1-17

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Publication Date: 2018-08-10

Repository Name: EPIC Alfred Wegener Institut

Type: Article , isiRev

Format: application/pdf

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Atlantic sources of the Arctic Ocean surface and halocline waters (2004)

Rudels, B. ; Jones, P. E. ; Schauer, Ursula ; [et al.]

In: EPIC3Polar Research, 23(2), pp. 181-208

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Publication Date: 2019-07-17

Repository Name: EPIC Alfred Wegener Institut

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Ground-Based Water Vapour Microwave Radiometry in the THESEO/WAVE Project (2000)

Lindner, K. ; Barry, B. ; Klein, U. ; [et al.]

In: EPIC3European Commission, Air pollution report 73, Stratospheric ozone 1999, Proc. of the fifth European symposium, 27 September to 1 October 1999, Saint Jean de Luz, France, EUR 19340, 2000, pp. 530-533

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Publication Date: 2019-07-17

Repository Name: EPIC Alfred Wegener Institut

Type: Conference , notRev

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5

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An overview of the geology of the Transvaal Supergroup dolomites (South Africa) (1998)

Eriksson, P. G. ; Altermann, W.

Springer

Environmental geology 36 (1998), S. 179-188

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ISSN: 1432-0495

Keywords: Key words Dolomite ; Limestone ; Karst ; Stromatolites ; Shallow marine ; Archaean ; Transvaal

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract In the Neoarchaean intracratonic basin of the Kaapvaal craton, between approximately 2640 Ma and 2516 Ma, two successive stromatolitic carbonate platforms developed. Deposition started with the Schmidtsdrif Subgroup, which is probably oldest in the southwestern part of the basin, and which contains stromatolitic carbonates, siliciclastic sediments and minor lava flows. Subsequently, the Nauga formation carbonates were deposited on peritidal flats located to the southwest and were drowned during a transgression of the Transvaal Supergroup epeiric sea, around 2550 Ma ago. This transgression led to the development of a carbonate platform in the areas of the preserved Transvaal and Griqualand West basins, which persisted for 30–50 Ma. During this time, shales were deposited over the Nauga Formation carbonates in the southwestern portion of the epeiric sea. A subsequent period of basin subsidence led to drowning of the stromatolitic platform and to sedimentation of chemical, iron-rich silica precipitates of the banded iron formations (BIF) over the entire basin. Carbonate precipitation in the Archaean was largely due to chemical and lesser biogenic processes, with stromatolites and ocean water composition playing an important role. The stromatolitic carbonates in the preserved Griqualand West and Transvaal basins are subdivided into several formations, based on the depositional facies, reflected by stromatolite morphology, and on intraformational unconformities; interbedded tuffs and available radiometric age data do not yet permit detailed correlation of units from the two basins. Thorough dolomitisation of most formations took place at different post-depositional stages, but mainly during early diagenesis. Partial silicification was the result of diagenetic and weathering processes. Karstification of the carbonate rocks was related to periods of exposure to subaerial conditions and to percolation of groundwater. Such periods occurred locally at the time of carbonate and BIF deposition. Main karstification, however, probably took place during an erosional period between approximately 2430 Ma and 2320 Ma.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s002540050334

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The economic mineral potential of the mid-Proterozoic Waterberg Group, northwestern Kaapvaal craton, South Africa (1997)

Eriksson, P. G. ; Reczko, B. F. F. ; Callaghan, C. C.

Springer

Mineralium deposita 32 (1997), S. 401-409

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ISSN: 1432-1866

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract The 1900–1700 Ma Waterberg Group in the main Waterberg fault-bounded basin consists of dominantly coarse siliciclastic red beds with minor volcanic rocks. The sedimentary rocks were deposited mainly by alluvial fans, fluvial braidplains and transgressive shallow marine environments, with lesser lacustrine and aeolian settings. Uplifted, largely granitic source areas were located along the Thabazimbi-Murchison lineament (TML) fault system in the south, and along the Palala shear zone in the northeast. Palaeoplacer titanomagnetite-ilmenite-zircon heavy mineral deposits, best developed in the Cleremont Formation in the centre of the basin, reflect initial fluvial reworking and subsequent littoral marine concentration. Coarse alluvial cassiterite placer deposits are found in the Gatkop area in the southwest of the basin, and appear to have been derived from stanniferous Bushveld Complex lithologies south of the TML. Hydrothermal zinc and U-Cu mineralisation in the Alma lithologies in the same area appears to be related to the TML fault system. Small manganese deposits and anomalous tungsten values occur in the south of the basin, where they are again closely spatially associated with the TML. Copper-barium mineralisation is found associated with dolerite dykes, and in stratigraphically controlled, inferred syngenetic settings. The most interesting of these apparently syngenetic occurrences is found within green coloured reduced mudrocks and inferred volcanic rocks, at an unconformity developed within the overall red bed sequence of the Waterberg Group, adjacent to the TML in the southwest of the basin. The most important potential mineralisation in the main Waterberg basin thus encompasses shoreline placer Ti and the possibility of substantial sediment-hosted copper deposits.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s001260050106

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7

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Pleistocene sediment-hosted uranium deposits at Henkries, South Africa: using settling tubes to delineate buried ore bodies (1997)

Eriksson, P. G.

Springer

Mineralium deposita 32 (1997), S. 419-422

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ISSN: 1432-1866

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract Sediment-hosted uranium ores at Henkries in northwest South Africa occur in fine-grained sands, carbonaceous muds and diatomaceous earth within late Pleistocene lake deposits. The lakes are linked by short fluvial channel reaches and these aqueous beds are encompassed in predominant aeolian dune deposits. The late Pleistocene fluvial-lacustrine-aeolian succession is succeeded by a Holocene dune cover. Textural characterisation of lacustrine, fluvial and aeolian sands was based on volume percentages observed in sediment settling tubes. Vortex action during Holocene dune migration contaminated these aeolian cover sands with small amounts of substrate material, whose presence could be detected in settling tube patterns of surface aeolian sediment samples. It was thus possible to map buried lacustrine ore bodies, which were shown, by a successful drilling programme, to be displaced downwind.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s001260050108

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8

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An overview of the geology of the Transvaal Sequence and Bushveld Complex, South Africa (1995)

Eriksson, P. G. ; Hattingh, P. J. ; Altermann, W.

Springer

Mineralium deposita 30 (1995), S. 98-111

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ISSN: 1432-1866

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract The Late Archaean-Early Proterozoic Transvaal Sequence is preserved within the Transvaal, Kanye and Griqualand West basins, with the 2050 Ma Bushveld Complex intrusive into the upper portion of the succession within the Transvaal basin. Both Transvaal and Bushveld rocks are extensively mineralized, the former containing large deposits of iron, manganese, asbestos, andalusite, gold, fluorine, lead, zinc and tin ores, and the latter some of the World's major occurrences of PGE, chromium and vanadium ores. Transvaal sedimentation began with thin, predominantly clastic sedimentary rocks (Black Reef-Vryburg Formations) which grade up into a thick package of carbonate rocks and BIF (Chuniespoort-Ghaap-Taupone Groups). These lithologies reflect a carbonate-BIF platform sequence which covered much of the Kaapvaal craton, in reaction to thermal subsidence above Ventersdorp-aged rift-related fault systems. An erosional hiatus was followed by deposition of the clastic sedimentary rocks and volcanics of the Pretoria-Postmasburg-Segwagwa Groups within the three basins, under largely closed-basin conditions. An uppermost predominantly volcanic succession (Rooiberg Group-Loskop Formation) is restricted to the Transvaal basin. A common continental rift setting is thought to have controlled Pretoria Group sedimentation, Rooiberg volcanism and the intrusion of the mafic rocks of the Rustenburg Layered Suite of the Bushveld Complex. The dipping sheets of the Rustenburg magmas cut across the upper Pretoria Group stratigraphy and lifted up the Rooiberg lithologies to form the roof to the complex. Subsequent granitic rocks of the Lebowa and Rashoop Suites of the Bushveld Complex intruded both upper Rustenburg rocks and the Rooiberg felsites.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00189339

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9

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Exploration initiatives in South Africa (1997)

Eriksson, P. G. ; Reczko, B. F. F.

Springer

Mineralium deposita 32 (1997), S. 309-311

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ISSN: 1432-1866

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s001260050097

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Some evidence for the base-metal potential of the Pretoria Group: stratigraphic targets, tectonic setting and REE patterns (1995)

Reczko, B. F. F. ; Eriksson, P. G. ; Snyman, C. P.

Springer

Mineralium deposita 30 (1995), S. 162-167

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ISSN: 1432-1866

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract The Timeball Hill and Silverton Formations of the 2.1–2.3 Ga Pretoria Group have regional lithological associations which are thought to have been favourable for the genesis of stratiform sulphide deposits. The observed association of carboniferous and pyritic black shales, tuffaceous material, stromatolitic carbonates and inferred turbidity current deposits is common in stratiform sulphide deposits of the sedimentary exhalative group. Massive sulphides in the Silverton Formation are compatible with a syngenetic brine discharge, probably related to deep fracture systems. The basal shales of the Timeball Hill Formation are significantly enriched in base-metals and Ba. Interlayered tuff beds at this stratigraphic level have PGE-contents of up to 1 g/t. The REE-geochemistry of Pretoria Group sedimentary rocks supports hydrothermal activity as an important factor in both stratigraphic units.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00189345

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