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The Ahlmannryggen group, western Dronning Maud Land, Antarctica.Perritt, Samantha. January 2001 (has links)
The Mesoproterozoic Ritscherflya Supergroup forms an extensive volcano-sedimentary cover succession on the Archaean Grunehogna Province of western Dromring Maud Land, Antarctica. The oldest:, predominantly sedimentary deposits of this cover succession are exposed across the Borgmassivet and southern Ahlmannryggen mountain ranges, and are collectively assigned to the Ahlmannryggen Group. A revised lithostratigraphy places exposures from these two regions in separate subdivisions, with three formations being recognised in the Ahlmannryggen (Pyramiden, Schumacherfjellet and Grunehogna Formations) and four formations being defined for the Borgmassivet (Veten, Framryggen, HogfOlma and Brapiggen Formations). Deposition of these successions occurred in a combination of fluvial braid-plain and braid-delta plain environments, with exposures in the Ahlmannryggen and Borgmassivet regions representing contemporaneous sedimentation in different portions of the same basin, under similar conditions. The development of the Ahlmannryggen Group basin is attributed to flexing associated with continental collision during the assembly of Rodinia. Collision and accretion of a continental island arc terrain (the Maudheim Province) along the southern margin of the Grunehogna Province is considered responsible for flexural snbsidence and the development of a peripheral foreland basin. The Ahlmannryggen Group represents 'molasse' stage infilling of this basin, with sedimentation being dominated by a combination of transverse and longitudinal drainage systems entering a depo-centre located to the east/southeast of the presently exposed succession. SAMANTIIA PERRlTT Detritus entering the basin was sourced either directly or indirectly from at least seven different terrains, aged ca. 1135Ma, ca. 1335Ma, ca. 1600-1700Ma, ca. 2000-2100, ca. 2645Ma, ca. 2400-2900Ma and ca 2900-3300Ma, according to UlPb detrital zircon SHRIMP analysis. The source terrains included the Maudheim Province, basement granites of the Grunehogna Province, an older sedimentary terrain dominated by a banded ironstone association, at least two further magmatic provinces and two metamorphic terrains. Of these source terrains, only the Maudheim Province and Grunehogna Province basement granites are presently exposed in western Dromring Maud Land The subsequent development of large-scale buckle folds and extensive brittle deformation within the Grunehogna Province cover rocks is attributed to the formation of a regionally extensive sinistral strike-slip system during NNW-SSE Pan-African compression, and can be correlated to structures exposed in the Maudheim Province and northern Mozambique. It is proposed that this strike-slip system developed in response to escape tectonics operating during a late stage of Gondwana amalgamation, as a result of the Ross Orogeny, and the suturing of East and West Antarctica / Thesis (Ph.D.)-University of Natal, Durban, 2001.
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Geological evolution of western H.U. Sverdrupfjella, Dronning Maud land, Antarctica.Grantham, Geoffrey Hugo. January 1992 (has links)
The oldest rocks of western H.U. Sverdrupfjella, the Jutulrora Formation, consist of
interlayered mafic to felsic ortho- and paragneisses thought to represent calc-alkaline volcanic
and clastic sedimentary rocks. These rocks are structurally overlain by the largely paragneissic,
carbonate- dominated Fuglefjellet Formation which may represent a miogeosynclinal shelf facies.
This sequence is structurally overlain by the dominantly para-gneissic Sveabreen Formation
which may comprise a eugeosynclinal facies.
Three granitic bodies, the Roerkulten, Jutulrora and Brekkerista Granites intrude the Jutulrora
Formation. The trace element chemistry of these granites suggest that accessory minerals
played significant roles during their generation and crystallization. Various mafic intrusions, now
discordant amphibolites, and a phase of diorite veining are present.
The Dalmatian Granite was emplaced syntectonically with the 470Ma Pan-African (or Ross)
orogeny during D3. This granite was generated by crustal anatexis at >5kb.
Jurassic age intrusions include alkaline complexes at Straumsvola and Tvora and numerous
dolerite dykes, some of which postdate the alkali intrusions.
Five episodes of deformation are recognised. The first two resulted in folds (F1 and F2) which
are co-planar and coaxial resulting in type 3 interference structures. Low angle thrust faulting
occurred during D2. Fold vergence and associated lineations suggest tectonic transport from the
southeast during D1 and D2,
D3 involved folding and reverse faulting. The orientations of the fault and axial planes of
these structures suggest transport from the west and north-west. D4 involved open dome and
basin folding.
D6 involved normal faulting and jointing, adjacent and parallel to the Jutulstraumen Glacier in
the west. The joints affect the Tvora Alkaline Complex.
Three phases of metamorphism, related to the deformation, are recognised. The dominant
mineral assemblages are typical of medium to high grade metamorphism and define S1 and S2
planar fabrics. Discordant mafic intrusions provide evidence of a long history of metamorphism.
M3 mineral development, commonly represented by biotite, is oriented axial planar to D3 folds.
Comparison of the geology of the area with that of southern Mozambique reveals many
similarities. These support reconstructions based on geophysical data which juxtapose Dronning
Maud Land and southern Africa prior to the break up of Gondwanaland. / Thesis (Ph.D.)-University of Natal, Pietermaritzburg, 1992.
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A Mass Balance Study of the West Antarctic Ice SheetSpikes, Vandy Blue January 2003 (has links) (PDF)
No description available.
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Surficial Geology and Geomorphology of the Western Olympus Range, Antarctica: Implications for Ice-sheet HistoryVandenHeuvel, Brett January 2002 (has links) (PDF)
No description available.
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The geological evolution of Neumayerskarvet in the Northern Kirwanveggen, Western Dronning Maud Land, AntarticaHarris, Philip David 15 August 2012 (has links)
D.Sc / Neumayerskarvet forms a continuous outcrop of high-grade gneiss within the northern Kirwanveggen in western Dronning Maud Land, Antarctica. A detailed geological study was carried out to obtain an evolutionary history for Neumayerskarvet. The work involved field mapping to provide a structural framework for further metamorphic and isotopic investigations. U-Pb zircon SHRIMP analysis, Rb-Sr, Sm-Nd and Ar-Ar mineral analysis were used to provide absolute time constraints on different tectono-metamorphic periods and cooling histories. Petrographic investigations, coupled with mineral chemistry on kyanite-bearing leucogneisses, provided information on the P-T conditions. An understanding of the crustal evolution of the high-grade gneisses was obtained through whole-rock geochemistry and isotope analysis. The dominant lithotectonic unit preserved at Neumayerskarvet is biotite-garnet migmatite gneiss, which is inter-fingered with quartzofeldspathic gneisses and banded quartz-feldspar gneisses. Several magmatic phases have intruded these sequences. Three tectonometamorphic cycles have been established for the region. The first two cycles are assigned to a period between 1390 Ma and 970 Ma while the third cycle is constrained between 650 Ma and 450 Ma. An age of ca. 1390 Ma for the biotite-gamet migmatite gneiss provides a maximum age for the first tectono-metamorphic cycle. Zircon growth and magmatism during this tectonometamorphic cycle constrains deformation (D1a) between ca. 1160 Ma and ca. 1110 Ma. Deformation is marked by the development of a penetrative planar foliation and isoclinal recumbent folding. High-pressure metamorphic conditions during this cycle have been suggested from previous investigations but are not confirmed in this investigation as the kyanite-bearing leucogneisses intruded during the second tectono-metamorphic cycle. It is possible that the first and second tectono-metamorphic cycles are part of a progressive deformational cycle. The second tectono-thermal cycle represents a major period of magmatism and tectonism constrained between ca. 1110 Ma and ca. 970 Ma. Major folding occurred during this tectonic episode, represented by isoclinal recumbent folds, sheath folds and re-folded fold interference patterns (D1b). The structural fabric elements produced a complicated relationship of transposed coplanar and colinear composite fabrics. Fabric geometries suggest NNW-SSE tectonic transport directions. Garnet-kyanite-muscovite-biotite-quartz assemblages (Mn+1 (nkv)) provide P-T estimates of 710-760 °C and 7.8-8.5 kb. Later metamorphic assemblages of sillimanite-muscovite-high Ca-garnet-biotite-quartz (Mn+2 (nkv)) provide P-T estimates of 630- 690 °C and 6.0-7.4 kb. The whole-rock isotope data indicate that material accreted during the second tectono-metamorphic cycle experienced a short crustal residence time. The third tectono-metamorphic cycle is constrained by isotopic ages between 650 Ma and 450 Ma. Deformation (D2) that re-works earlier tectonic fabrics may represent signatures of this cycle, but the exact nature of the deformation remains enigmatic. Tectonic fabric styles and geometries are similar to the more dominant D1 tectonic episode, making recognition of temporal relationships difficult. Diffusional P-T data from garnet-biotite rims (Mn+3 (nkv)) provide P-T cooling estimates of 560-570 °C and 4.4-4.6 kb. Re-working of the high-grade gneisses during the third tectono-metamorphic cycle, with no addition or accretion of new crustal material is indicated by the isotopic data. A final tectonic episode (D3) comprising late brittle deformation and uplift is equated to Gondwana break-up.
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Sedimentology and Stratigraphy of Miocene-Age Glacial Deposits, Friis Hills, AntarcticaSmith, Alexander Ryan January 2011 (has links)
The Friis Hills is an isolated plateau standing as much as 600 m above surrounding topography in the McMurdo Dry Valleys region or Antarctica.Preserved on the plateau surface is a sequence of early to middle Miocene-aged dritis. At the eastern edge of the plateau, these drifts fill a shallow paleovalley to a depth of at least 35 m. The drills are exposed in a natural cross-section where modern topography crosscuts the paleovalley. Establishing an age and an environmental interpretation for these deposits is important because Antarctic paleoclimate records are lacking from the Mid-Miocene Climate Optimum. Two drifts fill the ancient paleovalley in the eastern Friis Hills. The upper drift is here named Cavendish drift: the lower is here named Friis drift. Cavendish can be subdivided into three units, whereas Friis drift can be subdivided into two units. Each of these units is a horizontal bed that laps on paleovalley sidewalls. The lowest, Friis II, is a compact diamicton that is overlain by a nearly in-situ bedded volvanic ash. Based on [20]Ar/[39]Ar dating, the ash is 19.76 [plus/minus] 0.07 Ma old. A second diamicton, Friis I, conformably blankets Friis II and was discovered to hold fossileferous interbeds. Both Friis I and II contain erratic clasts and both are lodgemont tills deposited from small, locally derived, alpine glaciers. Bedrock striations show ice flow to the northeast at azimuths between 025? to 032?, parallel to the trend of the paleovalley axis. Above these, Cavendish I. II. and III were deposited when thick ice covered the Friis Hills. Where the Cavendish drift laps onto paleovalley sidewalls, bedrock striations show ice flow from 077? to 150?. Cavendish drift was deposited sometime alter 19.8 Ma but before 14 Ma. when the Dry Valleys glacial records show that regional glaciers became cold-based. Downcutting eventually isolated the Friis Hills plateau, resulting in the preservation of the drift sequence. This event was most likely associated with growth or the East Antarctic Ice Sheet 14 Ma ago. This age constraint means that the tills preserved in the Friis Hills date from a time just before the East Antarctic Ice Sheet expanded and became a permanent feature. Based on the age-dated stratigraphy presented in this thesis, future work focusing on fossiliferious interbeds could provide unique and important constraints on Miocene climate change. / North Dakota State University. Department of Geosciences
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Provenance Study of Reedy Glacier and West Antarctic Ice Stream TillsKramer, Katie L. 10 October 2008 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / In January 2007, 26 samples of till from 6 different moraines along the Reedy
Glacier, East Antarctica were collected with the goal of differentiating between these
samples and till collected from the base of the Whillans, Kamb, and Bindschadler Ice
Streams of West Antarctica. The ability to differentiate between East and West Antarctic
ice will allow us to constrain ice flow into the central Ross Sea during the Last Glacial
Maximum (LGM), which has implications for more accurate reconstructions of the Ross
Ice Sheet and its behavior.
Moraines sampled from the head of Reedy Glacier give insight to the geology
beneath the EAIS, and may be representative of what the glacier is eroding from its bed.
Samples along the trunk of the glacier capture representative rock types eroded along the
length of Reedy Glacier. At each moraine 3 replicate sub-sites were selected for
collection to represent the diversity of material within each moraine. Comparisons are
based on the composition of pebbles, particle size distributions, and sand petrography.
Analysis of the pebble fraction shows that each sub-site contains similar rock types,
however, the concentration of each rock type varies as much as 25-35%. Similar variation
is also seen within the sub-site sand fraction. Both the pebble and sand fraction reflect the
mapped bedrock geology. The dominant pebble types are coarse-grained felsic and
intermediate igneous rocks, as well as quartzite. Similarly felsic igneous grains, quartzite,
quartz, and feldspar characterize the sand fraction. Particle size analysis shows that
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Reedy Glacier till averages 85% sand. The subglacial West Antarctic samples contain
approximately 30% sand, and equal amounts of silt and clay, approximately 35% each.
An observation of the sand fraction from beneath the West Antarctic Ice Streams
shows composition similar to tills from Reedy Glacier. However, tills from the base of
the West Antarctic Ice Streams contain up to 75% polymict grains, and in contrast, these
grains are absent in the tills from Reedy Glacier. These sand-sized polymict grains
dominate material from the base of Whillans and Bindschadler Ice Streams, whereas
material from the base of Kamb Ice Stream contains grains of felsic igneous, quartz,
feldspar, and few to no polymict grains. In addition to the polymict grains, the sand
fraction in the ice stream cores contains trace fragments of sedimentary, and volcanic
rocks, both of which are absent from the Reedy Glacier sand fraction. However, polymict
grains are believed to represent a process occurring beneath the ice sheet, rather than
indicate provenance. It is difficult to differentiate between the two tills, as both contain
high concentrations of felsic-intermediate igneous lithics, quartz, and feldspar. The
central Ross Sea contains sediment similar in rock type and mineralogy as seen within
sediments from both Reedy Glacier, and the base of the ice streams of West Antarctica.
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Gravity analyses for the crustal structure and subglacial geology of West Antarctica, particularly beneath Thwaites GlacierDiehl, Theresa Marie, 1981- 15 October 2012 (has links)
The West Antarctic Ice Sheet (WAIS) is mostly grounded in broad, deep basins (down to 2.5 km below sea level) that are stretched between five crustal blocks. The geometry of the bedrock, being mostly below sea level, induces a fundamental instability in the WAIS through the possibility of runaway grounding line retreat. The crustal environment of the WAIS further influences the ice sheet’s fast flow through conditions at the ice-bedrock boundary. This study focuses on understanding the WAIS by examining the subglacial geology (such as volcanoes and sedimentary basins) at the icebedrock boundary and the continent’s deeper crustal structure- primarily using airborne gravity anomalies. The keystone of this study is a 2004-2005 aerogeophysical survey over one of the most negative mass balance glaciers on the continent: Thwaites Glacier (TG). The gravity anomalies derived from this dataset- as well as gravity-based modeling and spectral crustal boundary depth estimates- reveal a heterogeneous crustal environment beneath the glacier. The widespread Mesozoic rifting observed in the Ross Sea Embayment (RSE) of West Antarctica extends beneath TG, where the crust is ~27 km thick and cool. Adjacent to TG, spectrally-derived shallow Moho depths for the Marie Byrd Land (MBL) crustal block can be explained by thermal support from warm mantle. I assemble here new compilations of free-air and Bouguer gravity anomalies across West Antarctica (from both airborne and satellite datasets) and re-interpret the extents of West Antarctic crustal block and their boundaries with the rift system. Airy isostatic gravity anomalies reveal that TG is relatively sediment starved, in contrast to the sediment-rich RSE. TG’s fast flow velocities could be sustained in this sediment poor environment if higher heat flux in MBL was providing an ample source of subglacial melt water to the glacier. The isostatic anomalies also indicate that TG’s outlet rests on a bedrock sill that will impede future grounding line retreat (up to ~100 km) and temporarily stabilize the glacier. / text
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The characterisation of an openwork block deposit, northern buttress, Vesleskarvet, Dronning Maud Land, Antarctica.Hansen, Christel Dorothee January 2014 (has links)
Investigating openwork block accumulation has the potential to further our understanding of rock weathering, the control of geological structure on landforms, the production of substrates for biological colonisation and the impacts of climate change on landform development and dynamics. Various models for the development of these landforms have been proposed. This includes in situ weathering, frost heave and wedging. Furthermore, it has been suggested that cold-based ice has the potential to preserve these features rather than to obliterate them. Blocky deposits are also frequently used as proxy evidence for interpreting palaeoclimates. The morphology and processes acting on a blockfield located on the Northern Buttress of the Vesleskarvet Nunataks, Dronning Maud Land, Antarctica (2°W, 71°S) were investigated and characterised. Given block dimensions and orientations that closely resembled the parent material and only small differences in aspect related characteristics observed, the blockfield was found to be autochthonous with in situ block production and of a young (Holocene) age. Small differences in rock hardness measurements suggest some form of aspect control on rock weathering. South-facing sides of clasts were found to be the least weathered. In comparison, consistently low rock hardness rebound values for the north-facing aspects suggest that these are the most weathered sides. Additional indicators of weathering, such as flaking and pitting, support analyses conducted for rock hardness rebound values. Solar radiation received, slope gradients and snow cover were found to influence weathering of clasts across the study site. Furthermore, ambient temperatures and wind speed significantly influenced near-surface ground temperatures dynamics. However, the lack of a matrix and paucity of fine material in textural analyses suggest a limited weathering environment. It is suggested that the retreat of the Antarctic ice sheet during the last LGM led to unloading of the surface, causing dilatation and subsequent fracturing of the bedrock along pre-existing joints, leading to in situ clast supply. Subsequent weathering and erosion along other points or lines of weakness then yielded fines and slight edge rounding of clasts.
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Double dating detrital zircons in till from the Ross Embayment, AntarcticaWelke, Bethany Marie 21 May 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / U/Pb and (U-Th)/He (ZHe) dating of detrital zircons from glacial till samples in the Ross Embayment, Antarctica records cooling after the Ross/Pan-African orogeny (450-625 Ma) followed by a mid-Jurassic to mid-Cretaceous heating event in the Beacon basin. Zircons were extracted from till samples from heads of major outlet glaciers in East Antarctica, one sample at the mouth of Scott Glacier, and from beneath three West Antarctic ice streams. The Ross/Pan-African U/Pb population is ubiquitous in these Antarctic tills and many Beacon Supergroup sandstones, thus 83 grains were analyzed for ZHe to subdivide this population. Two ZHe age populations are evident in East Antarctic tills, with 64% of grains 115-200 Ma and 35% between 200-650 Ma. The older population is interpreted to be associated with the Ross/Pan-African orogeny including cooling of the Granite Harbour Intrusives and/or exhumation of the older basement rocks to form the Kukri Peneplain. The lag time between zircon U/Pb, ZHe and 40Ar/39Ar ages from K-bearing minerals show cooling over 200 My. Grains in East Antarctic tills with a ZHe age of 115-200 Ma likely reflects regional heating following the breakup of Gondwana from the Ferrar dolerite intrusions, subsidence within the rift basin, and a higher geothermal gradient. Subsequent cooling and/or exhumation of the Transantarctic Mountains brought grains below the closure temperature over a span of 80 My. This population may also provide a Beacon Supergroup signature as most of the tills with this age are adjacent to nunataks mapped as Beacon Supergroup and contain an abundance of
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Beacon pebbles within the moraine. Nine zircons grains from three Beacon Supergroup sandstones collected from moraines across the Transantarctic Mountains yield ages from 125-180 Ma. West Antarctic tills contain a range of ZHe ages from 75-450 Ma reflecting the diverse provenance of basin fill from East Antarctica and Marie Byrd Land. ZHe and U/Pb ages <105 Ma appear to be distinctive of West Antarctic tills. The combination of U/Pb, ZHe and 40Ar/39Ar analyses demonstrates that these techniques can be used to better constrain the tectonic evolution and cooling of the inaccessible subglacial source terrains beneath the Antarctic Ice Sheet.
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