Subglacial deformation and water-pressure cycles as a key for understanding ice stream dynamics: evidence from the Late Ordovician succession of the Djado Basin (Niger)

Denis, Michaël; Guiraud, Michel; Konaté, Moussa; Buoncristiani, Jean‐François

doi:10.1007/s00531-009-0455-z

Cited by 73 publications

(60 citation statements)

References 91 publications

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“…This occurs during or shortly after deposition and prior to consequent diagenesis (Van Loon, 2009;. SSD has been documented for subaqueous clastic sediments from the mud to coarse sand range (Van Loon, 2009;, including turbidites (Moretti et al, 2001), subglacial environments (Ghienne, 2003;Denis et al, 2010;Douillet et al, 2012;Pisarska-Jamroży and Weckwerth, 2013), carbonates (Ettensohn et al, 2011;Chen and Lee, 2013), and volcanic ash (Gibert et al, 2011). In subaerial environments, SSD is documented from earthquake-triggered liquefaction and can form sand blows and dykes.…”

Section: Soft-sediment Deformationmentioning

confidence: 97%

Syn-eruptive, soft-sediment deformation of deposits from dilute pyroclastic density current: triggers from granular shear, dynamic pore pressure, ballistic impacts and shock waves

Douillet¹,

Taisne

Tsang-Hin-Sun

et al. 2015

Solid Earth

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Section: Soft-sediment Deformationmentioning

confidence: 97%

Syn-eruptive, soft-sediment deformation of deposits from dilute pyroclastic density current: triggers from granular shear, dynamic pore pressure, ballistic impacts and shock waves

Douillet¹,

Taisne

Tsang-Hin-Sun

et al. 2015

Solid Earth

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“…The deformation structures within and under the GA are the best diagnosis to identify the glacial erosion surfaces. The deformation is marked by, sheath folds, intraformational shear planes, and step fractures (Figures 7 and 8a; Denis et al, 2010). The sheath folds are extremely good indicators of the ice flow direction.…”

Section: ) Preglacial Deposits (Ash Shaybiyatmentioning

confidence: 99%

Glacial sedimentology interpretation from borehole image log: Example from the Late Ordovician deposits, Murzuq Basin (Libya)

Moreau

Joubert²

2016

Interpretation

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In the Murzuq Basin, the Late Ordovician glaciogenic succession forms a very complex clastic reservoir system. Although the structural setting is simple, the architecture of the stratigraphic succession is particularly intricate, and conventional wireline logs display rather homogeneous signatures. However, when exposed, the glaciogenic sedimentary succession indicates a very large range of depositional environments and clear stratigraphic changes. Based on high-quality processing and interpretation of wireline microresistivity image logs over a single well, our method allows the precise recognition of the internal sedimentary structures and supports the interpretation of the depositional environments within the Late Ordovician succession. During interpretation, it is possible to draw a descriptive sedimentological log, similar to a standard log from cores or outcrops. The image log is interpreted like a regular sedimentary log and compared to an outcrop analog from the nearby outcrop area of Ghat. The success of the well analysis resides in the quality of the borehole image log, permitting the recognition of sandstone grain sizes, textures (facies), and sorting. In addition, crucial information is extracted from the identification of glacial surface and ice-flow orientations, which, combined with the recognition of major transgressive events, allows the recognition and correlation of glacial-type stratigraphy. As in the modern Pleistocene glaciation, stadial/interstadial and glacial/interglacial stages are identified from resistivity imaging of the Libyan Ordovician succession. In addition to the unprecedented potential of correlation between wells within the basin, the sedimentary information extracted from the borehole image log provides important insights on the paleogeographic context of the basin and thus on the exploration potential of the prolific Ordovician-Silurian petroleum system. IntroductionWell petrophysical data interpretations are crucial in petroleum exploration and production. They are routinely conducted and provide essential insights on the quality of the rocks involved in the petroleum system. However, in some sedimentary environments, the acoustic and the petrophysical measurements are not able to provide sufficient diagnostic information to characterize reservoir properties and geometries. The limits of the use of standard logs arise from (1) the possible confusion between formations with similar sand/shale ratios (e.g., basal lag with large shaley clasts formations and sandrich debris flow) and (2) the limited resolution and the smearing effect of standard logs, which do not provide any detailed sedimentological information of the penetrated strata. On the contrary, bed thickness, bed contacts, or postdepositional events, which are important

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“…Micromorphology is increasingly being used by glaciologists and Quaternary geologists as a primary tool for the analysis of diamictons deposited in different sedimentary environments (van der Meer 1987;Harris 1998;Lachniet et al, 1999;Carr et al, 2000;Carr 2001;Lachniet et al, 2001;Menzies and Zaniewski 2003;Carr et al, 2006;Phillips 2006;Menzies et al, 2006;Reinardy and Lukas 2009;Kilfeather et al, 2010), as an aid to understanding the processes occurring beneath glaciers (Menzies and Maltman 1992;van der Meer 1997;Menzies et al, 1997;Khatwa and Tulaczyk 2001;van der Meer et al, 2003;Roberts and Hart 2005;Hiemstra et al, 2005;Baroni and Fasano 2006;Larsen et al, 2006;Hart 2007;Larsen et al, 2007), to *Manuscript Click here to view linked References help unravel the often complex deformation histories recorded by glacigenic sequences (van der Meer 1993;Phillips and Auton 2000;van der Wateren et al, 2000;Phillips et al, 2007;Lee and Phillips 2008;Denis et al, 2010), and investigate the role played by pressurised pore-water/melt water during these deformation events (Hiemstra and van der Meer 1997;Phillips and Merritt 2008;van der Meer et al, 2009;Denis et al, 2010). In the majority of these published studies the terminology used to describe the various microtextures in thin section follows that proposed by van der Meer (1987van der Meer ( ,...…”

Section: Introductionmentioning

confidence: 99%

“…In a number of studies of polydeformed glacial sediments (e.g. Phillips and Auton 2000;van der Wateren et al, 2000;Phillips et al, 2007;Denis et al, 2010) the successive generations of plasmic fabrics, folds, rotational structures and faults present in thin section have been distinguished by applying the methodologies and nomenclature normally used in structural geological studies (e.g. F1 earliest folds to Fn latest, S1 earliest fabric to Sn latest).…”

Section: Introductionmentioning

confidence: 99%

A new ‘microstructural mapping’ methodology for the identification, analysis and interpretation of polyphase deformation within subglacial sediments

Phillips

Meer

Ferguson

2011

Quaternary Science Reviews

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Although integrated clast macro-and microfabric studies have been used to provide evidence of palaeo-ice flow directions, to discriminate between diamictons deposited in differing sedimentary environments, and to model the response of tills to subglacial deformation, such studies have typically only examined the "bulk" fabric developed within the diamicton, largely ignoring the potential for several phases of fabric development within these typically polydeformed deposits. We present a new graphical method for the identification, description and analysis of clast microfabrics in polydeformed tills. This method utilises high resolution digital scans of orientated thin sections imported into a standard computer graphics package to measure the orientation of long axes of detrital (skeleton) grains included within the till. These data are then used to identify the main clast microfabrics present within the till, allowing the delineation of clast microfabric domains in which elongate grains share a similar preferred orientation. This process leads to the identification, characterisation and, most importantly, the interrelationships between the various generations of microfabrics. The relationships between these clast microfabrics and other microstructures (e.g. plasmic fabrics, turbate structures, shears, folds, faults…etc) can also be examined, providing a detailed microfabric-microstructural map of the thin section. Clast long axis orientation data collected for different parts of a thin section are plotted on a series of rose diagrams allowing the variation in clast microfabric orientation to be displayed graphically. A new set of terminology for the description of clast microfabrics in tills, which is based upon the system used by metamorphic petrologists, is also presented. Three case studies of the fabrics present within subglacial sediments of Pleistocene age as well as the present are used as examples of how to apply this methodology. IntroductionMicromorphology is increasingly being used by glaciologists and Quaternary geologists as a primary tool for the analysis of diamictons deposited in different sedimentary environments (van der

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Subglacial deformation and water-pressure cycles as a key for understanding ice stream dynamics: evidence from the Late Ordovician succession of the Djado Basin (Niger)

Cited by 73 publications

References 91 publications

Syn-eruptive, soft-sediment deformation of deposits from dilute pyroclastic density current: triggers from granular shear, dynamic pore pressure, ballistic impacts and shock waves

Syn-eruptive, soft-sediment deformation of deposits from dilute pyroclastic density current: triggers from granular shear, dynamic pore pressure, ballistic impacts and shock waves

Glacial sedimentology interpretation from borehole image log: Example from the Late Ordovician deposits, Murzuq Basin (Libya)

A new ‘microstructural mapping’ methodology for the identification, analysis and interpretation of polyphase deformation within subglacial sediments

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