Turbidites and mass movements in deep water continental slopes. Current issues and laboratory experiments approach.

Styliani Iosif Vouta

Turbidites and mass movements in deep water continental slopes. Current issues and laboratory experiments approach.

Styliani Iosif Vouta

Περίληψη

Νο

Πλήρες Κείμενο:

PDF

Αναφορές

7. Bibliography

Shanmugam, G. (2000). 50 years of the turbidite paradigm (1950s-1990s): deep- water processes and facies models- a critical perspective (pp. 285-342). Marine and petroleum geology.

Sanders, J. E. (1965). Primary sedimentary structures formed by turbidity currents and related resedimentation mechanisms. In G. V. Middleton, Primary sedimentary structures and their hydrodynamic interpretation (pp. 192-219), Society of Economic Paleontologists and Mineralogists Special Publication, Vol. 12.

Middleton. G. V., & Hampton, M. A. (1973). Sediment gravity flows: mechanics of flow and deposition. Proceedings of Pacific Section Society of Economic Paleontologists and Mineralogists, Los Angeles G. V. Middleton, & A. H. Bouma, Turbidites and deep- water sedimentation,1-38.

Dott Jr, R. H. (1963). Dynamics of subaqueous gravity depositional processes. American Association of Petroleum Geologists Bulletin, 47, 104-128.

Bagnold, R. A. (1962). Auto-suspension of transported sediment; turbidity currents. Royal Society of London Proceedings, Series A, 265, 315-319.

Shanmugam, G. (1996a). High-density turbidity currents: Are they sandy debris flows? Journal of Sedimentary Research, 66, 2-10.

Shanmugam, G.(1996b). Perception vs reality in deep-water exploration. World Oil, 217, 37-41.

Shanmugam, G. (1997a). The Bouma Sequence and the turbidite mind set. Earth-Science Reviews, 42, 201-229.

Shanmugam, G. (1997b). Slope turbidite packets in a fore-arc basin fill sequence of the Plio-Pleistocene Kakegawa Group: Their formation and sea-level changes_ Discussion. Sedimentary Geology, 112, 297-300.

Shanmugam, G. (1997c). Deep-water exploration: Conceptual models and their uncertainties. NAPE (Nigerian Association of Petroleum Explorationsists) Bulletin, 12/01, 11-28.

Enos, P. (1977). Flow regimes in debris flow. Sedimentology, 24, 133-142.

Pierson, T. C., & Costa, J. E. (1987). A rheologic classi_cation of subaerial sediment-water flows. In J. E. Costa, & G. F. Wieczorek, Debris flows/ avalanches: process, recognition and mitigation, vol. VII (pp. 1-12)., Geological Society of America Reviews in Engineering Geology.

Philips, C. J., & Davies, T. R. H. (1991). Determining rheological parameters of debris flow material. Geomorphology, 4, 101-110.

Middleton, G. V. & Wilcock, P. R. (1994). In Mechanics in the earth and environmental sciences (pp.459). Cambridge, UK: Cambridge University Press.

Lowe, D. R. (1979). Sediment gravity flows: their classification and some problems of application to natural flows and deposits. In L. J. Doyle, & O. H. Pilkey, Geology of Continental Slopes (pp. 75-82), Society of Economic Paleontologists and Mineralogists Special Publication, Vol 27.

Nardin, T. R., Hein, F. J., Gorsline, D. S. & Edwards, B. D. (1979). A review of mass movement processes, sediment and acoustic characteristics and contrasts in slope and base of slope systems versus canyon fan basin floor systems. In L. J. Doyle, & Pilkey, Geology of continental slopes (pp. 61-73), Economic Paleontologists and Mineralogists Special Publication, Vol. 27.

Oakeshott, J. M. (1989). Aspects of depositional mechanisms of high concentration sediment gravity flows. Unpublished Ph. D. thesis, Keele, University of Keele, 502 pp.

Middleton, G. V. (1993). Sediment deposition from turbidity currents. Annual Review Earth Planetary Sciences, 21, 89-114.

Pickering, K. T., Hiscott, R. N. & Hein, F. J. (1989). In Deep-marine environments (pp. 416). London: Unwin Hyman.

Assier-Rzadkiewicz, S., 1997. Etude nume ́rique et expe ́rimentale d’un glissement de se ́diments le long d’une pente sous-marine et des vagues ge ́ne ́re ́es. The`se de doctorat, Univ. Montpellier II.

Hay, A.E., 1987. Turbidity currents and submarine channel formation in Rupert Inlet, British Columbia 2. The roles of continuous and surge-type flow. J. Geophys. Res. 92, 2883–2900.

Komar, P.D., 1977. Computer simulation of turbidity current flow and the study of deep-sea channels and fan sedimentation. In: Goldberg, E.D., McCave, I.N., O’Brien, J.J., Steele, J.H. (Eds.), The Sea, v.6, Marine Modelling. John Wiley, New York, pp. 603–621.

Bowen, A.J., Normark, W.R., Piper, D.J.W., 1984. Modelling of turbidity currents on Navy Submarine Fan, California Continental Borderland. Sedimentology 31, 169-185.

Middleton, G.V., 1966b. Experiments on density and turbidity currents: II. Uniform flow of density currents. Can. J. Earth Sci. 3, 627–637.

Beghin, P., 1979. Etude des bouffe ́es bidimensionnelles de densite ́ en e ́coulement sur pente avec application aux avalanches de neige poudreuse. The`se de doctorat, Universite ́ Scientifique et Me ́dicale de Grenoble et Institut National Polytechnique de Grenoble, 120pp.

Hinze, J. O., 1960. On the hydrodynamics of turbidity currents. Geol. Mijnbouw 39, 18-25.

Plapp, J. R., Mitchell, J. P., 1960. A hydrodynamic theory of turbidity currents. J. Geophys. Res. B. 65 (3), 983-992.

Naaim, M., 1995. Modelisation numerique des avalances aerosols. Houille Blanche 6 (5), 56-62.

D’ Ambrosio, D., Di Georgio, S., Iovine, G., 2003. Simulating debris flows through a hexagonal Cellular Automata model: Sciddica S3-hex. Nat. Hazards Earth Syst. Sci. 3, 545-559.

Piper, D. J. W., Savoye, B., 1993. Process of late Quaternary turbidity current flow and deposition on the Var deep-sea fan, north-west Mediterranean Sea. Sedimentology 40, 557-583.

Nisbet, E. G., Piper, D. J. W., 1998. Giant submarine landslides: Slumps, megaturbidites and their impact. Nature 392, 329-330.

Piper, D. J. W., Asku, A. E., 1987. The source and origin of the 1929 Grand Banks turbidity current inferred from sediment burgets. Geo-Mar. Lett. 7, 177-182.

Piper, D. J. W., Normark, W. R., 2009. Process that initiate turbidity currents and their influence on turbidites: A marine geology perspective. J. Sediment. Res. 79 (5), 347-362.

Flood, R. D., Damuth, J. E., 1987. Quantitative characteristics of sinuous distributary channels on the Amazon deep-sea fan. Geol. Soc. Am. Bull. 98, 728-738.

Flood, R. D., Manley, P. L., Kowsmann, R. O., Appi, C. J., Pirmez, C., 1991. Seismic facies and late Quaternary growth of Amazon submarine fan. In: Weimer, P., Link, M. H. (Eds.), Sesmic Facies and Sedimentary Process of Modern and Ancient Submarine Fans and turbidite systems. Frontiers in sedimentary geology. Springer-Verlag, New York Inc., 415-433.

Cirac, P., Bourillet, J.-F., Griboulard, R., Normand, A., Mulder, T., The ITSAS Shipboard Scientific Party, 2001. Le canyon de Capbreton: Nouvelles approaches morphostructurales et morphosedimentaires Premiers resultats de la campagne Itsas. C. R. Acad. Sci. Paris 332, 447-455.

Gaudin, M., Mulder, T., Cirac, P., Berne, S., Imbert, P., 2006b. Past and present sedimentary activity in the Capbreton Canyon, southern Bay of Biscay. In: Mulder, T. (Ed.), Geo-Marine Letters, vol. 26 (6), 331-345 Secial Issue on ‘ Deep-Sea Turbidite Systems on French Margins’.

Shepard, F. P., Dill, R. F., 1966. Submarine Canyons and other Sea-Valleys. Rand McNally, Chicago, IL381pp.

Rigaut, F., 1997. Analyse et evolution recente d’un systeme turbiditique meandriforme: l’ eventail profound du Zaire. Unpubl. Ph. D. thesis, Univ. Bretagne Occidentale., 209pp.

Shepard, F. P., 1981. Submarine canyons: multiple causes and long-time persistence. Am. Assoc. Pet. Geol. Bull. 65, 1062-1077.

Gaudin, M., 2006. Processus et enregistrements sedimentaires dans les canyons sour-marins Bourcart et de Capbreton Durant le dernier cycle clymatique. Unpubl. Ph. D. thesis, Univ. Bordeaux 1, no. 3122, 296pp.

Normark, W. R., Carlson, P. R., 2003. Giant submarine canyons: Is size any clue to their importance in the rock record. In: Chan, M. A., Archer, A. W. (Eds.), Extreme Depositional Environments: Mega end members in Geologic time, Geological Society of America, Special Paper, 1-15.

Clauzon, G., 1978. The Messinian Var Canyon (Provence, southern France). Paleogeographic implications. Mar. Geol. 27 (3/4), 231-246.

Guillocheau, F., Pautot, G., Auzende, J.-M., 1983. Les canyons du Var et du Paillon (marge des Alpes meridionales-Mediterranee occidentale): une origine quaternaire par glissement. C. R. Acad. Sci. Paris 296, 91-96.

Mulder, T., Cirac, P., Gaudin, M., Bourillet, J.-F., Tranier, J., Normand, A., et al., 2004. Understanding continent-ocean sediment transfer. EOS American Geophysical Union Transaction 257, 261-262.

Pratson, L. F., & Haxby, W. F. (1996). What is the slope of the US continental slope. Geology, 24, 3-6.

Mulder, T., Zaragosi, S., Razin, P., Grelaud, K., Lanfumey, V., Bavoil, F., 2009b. A new conceptual model for the deposition process of homogenite: Application to a Cretaceous megaturbidite of the western Pyrenees (Basque region, SW France). Sediment. Geol. 222, 263-273.

Gennesseaux, M., Guibout, M., Lancombe, H., 1971. Enregistrement de courants de turbidite dans la vallee sous-marine du Var (Alpes-Maritimes). C. R. Acad. Sci. Paris D 273, 2456-2459.

Inman, D. L., 1970. Strong currents in submarine canyons. Abstr. Trans. Am. Geophys. Union 51, 319.

Shepard, F. P., McLoughlin, P. A., Marshall, N. F., Sullivan, G. G., 1977. Current-meter recordings of low-speed turbidity currents. Geology 5, 297-301.

Shepard, F. P., Marshall, N. F., McLoughlin, P. A., Sullivan, G. G., 1979. Currents in submarine canyons and other sea valleys. American Association of Petroleum Geologists, Studies in Geology, No. 8, 173pp.

Pratson, L. F., Ryan, W. B. F., Mountain, G. S., Twichell, D. C., 1994. Submarine canyon initiation by downslope-eroding sediment flows: evidence in late Cenozoic strata on the New Jersey continental slope. Geol. Soc. Am. Bull. 106, 395-412.

Palanques, A., Guillen, J., Puig, P., Durrieu de Madron, X., 2008. Storm-driven shelf-to-canyon suspended sediment transport at the southwestern Gulf of Lions. Cont. Shelf Res. 28 (15), 1947-1956.

Porebski, S. J., Steel, R. J., 2003. Self-margin deltas: their stratigraphic significance and relation to deep water sands. Earth Sci. Rev. 62 (3-4), 283-326.

Posamentier, H., Allen, G. P., James, D. P., Tesson, M., 1992. Forced regression in a sequence stratigraphic framework: Concepts, examples and exploration significance. Am. Assoc. Pet. Geol. Bull. 76, 1687-1709.

Rouillard, P., 2010. Modele architectural et lithologique du systeme de Rosetta (Delta du Nil, Mediterranee Orientale): Implications pour un analogue actuel de reservoir petrolier. Unpubl. Ph. D. thesis, Universite de Nice Sophia-Antipolis, 375pp.

Sydow, J., Roberts, H. H., 1994. Stratigraphic framework of Late Pleistocene shelf-edge delta, northeast Gulf of Mexico. Am. Assoc. Pet. Geol. Bull. 78, 1276-1312.

Coleman, J. M., Prior, D. B., Lindsay, J. F., 1983. Deltaic influences on shelf edge instability process. In: Stanley, D. J., Moore, G. T. (Eds.), The Shelf break, Critical Interface on Continental Margins, 121-137.

Babonneau, N., 2002. Mode de fonctionnement d’un chenal turbiditique meandriforme: cas du systeme turbiditique actuel du Zaire. Unpubl. Ph. D., Univ. Bordeaux 1, 308pp.

Babonneau, N., Savoye, B., Cremer, M., Bez, M., 2004. Multiple terraces within the deep incised Zaire Valley (ZaiAngo Project): Are they confined levees. In: Lomas, S., Joseph, P., (Eds.), Confined Turbidite Systems, Geological Society, London, Special Publication, 222, 91-114.

Garlan, T., 2004. Apports de la modelisation dans l’ etude de la sedimentation marine recente. Memoire d’ Habilitation a Diriger les Recherches, Universite des Sciences et Techniques de Lille 158pp.

Ferry, J.-N., 2004. Developpement et geometrie des corps sableux de pente, de glacis et du basin profound, sur le prisme sedimentaire progradant (Oligocene Pliocene) de la marge oust africaine entre le Sud-Gabon et l’ Angola. Unpubl. Ph. D. thesis, Univ. Bordeaux 1, 482pp.

Beaubouef, R. T., Friedmann, S. J., 2000. High resolution seismic/sequence stratigraphic framework for the evolution of Pleistocene intra slope basins, Western Gulf of Mexico: Depositional models and reservoir analogs. In: Weimer, P., Slatt, R. M., Coleman, J., Rosen, N. C., Nelson, H., Bouma, A. H., Styzen, M. J., Lawrence, D. T. (Eds.), Deep-water reservoirs of the world. GCSSEPM Foundation 20th Annual research conference, Dec. 3-6, Houston, Gulf Coast Section-SEPM Special Publication, pp, 40-60.

Pirmez, C., Flood, R. D., 1995. Morphology and structure of Amazon Channel. Proceedings of the Ocean Drilling Program, Initial Reports 155, 23-45

Pirmez, C., Beaubouef, R. T., Friedmann, S. J., Mohrig, D. C., 2000. Equilibrium profile and baselevel in submarine channels: Examples from Late Pleistocene systems and implications for the architecture of deep-water reservoir. In: Weimer, P., Slatt, R. M., Coleman, J., Rosen, N. C., Nelson, H., Bouma, A. H., Styzen, M. J., Lawrence, D. T. (Eds.), Deep-water reservoirs of the world, GCSSEPM, Foundation 20th Annual research conference, Dec. 3-6, Houston, Gulf Coast Section-SEPM Special Publication, pp, 782-805.

Bonnel, C., 2005. Mise en place des lobes distaux dans les systemes turbiditiques actuels: Analyse compare des systemes du Zaire, Van et Rhone. Unpubl. Ph. D. thesis, Univ. Bordeaux 1, 293pp.

Damuth, J. E., Flood, R. D., 1985. Amazon fan, Atlantic Ocean. In: Bouma, A., Normark, W., Barnes, N. (Eds.), Submarine fans and related turbidite systems. Springer-Verlag, New York, pp. 97-106.

Cremer, M., 1983. Approches sedimentologiques et geophysiques des accumulations turbiditiques. L’ eventail profound du Cap-Ferret (Golfe de Gascogne), La serie des gres d’ Annot (Alpes de Hautes Provence). Unpubl. Thesis, Univ. Bordeaux 1, 334pp.

Piper, D. J. W., Stow, D. A. V., Normark, W. R., 1984. Laurentian Fan: Sohm abyssal plain. Geo-Mar. Lett. 3, 141-146.

Savoye, B., Piper, D. J. W., Droz, L., 1993. Plio-pleistocene evolution of the Var deep-sea fan on the French Riviera. Mar. Pet. Geol. 10, 550-571.

Klaucke, I., Hesse, R., Ryan, W. B. F., 1998. Seismic stratigraphy of the Northwest Atlantic Mid-Ocean channel: growth pattern of a mid-ocean channel-levee complex. Mar. Pet. Geol. 15, 575-585.

Piper, D. J. W., Hiscott, R. N., Normark, W. R., 199b. Outcrop scale acoustic facies analysis and latest Quaternary development of Hueneme and Dune submarine fans, offshore California. Sedimentology 46, 47-78.

Komar, P. D., 1969. The channelized flow of turbidity currents with application to Monterey deep sea Fan channel. J. Geophys. Res. B 74, 4544-4558.

Hiscott, R. N., Hall, F. R., Pirmez, C., 1997. Turbidity current overspill from the Amazon channel: texture of the silt/sand load, paleoflow from anisotropy of the magnetic susceptibility, and implications for flow processes. In: Flood, R. D., Piper, D. J. W., Klaus, A., Peterson, L. C. (Eds.), Proc. ODP, Sci. Results, 155, 53-78, College Station, TX.

Piper, D. J. W., Normark, W. R., 1983. Turbidite depositional patterns and flow characteristics. Navy Submarine fan, California Borderland, sedimentology 30, 681-694.

Masson, D. G., Kenyon, N. H., Gardner, J. V., Field, M. E., 1995. Monterey fan: Channel and overbank morphology. In: Pickering, K. T., Hiscott, R. N., Kenyon, N. H., Ricci, Luchi, Smith, R. D. A. (Eds.), Atlas of deep-water environments: Architectural style in turbidite systems. Chapman et Hall, London, pp. 74-79.

Piper, D. J. W., Deptuck, M., 1997. Fine-grained turbidites of the Amazon Fan: Facies characterization and interpretation. In: Flood, R. D., Piper, D. J. W., Klaus, A., Peterson, L. C. (Eds.), Proc. ODP, Sci. Results, 155, 79-108 College Station, TX.

Migeon, S., 2000. Dunes Geantes et levees Sedimentaires en domaine marin profound: approaches morphologique, sismique et sedimentologique. These, Universite Bordeaux I, 288pp.

Migeon, S., Savoye, B., Zanella, E., Mulder, T., Faugeres, J-C., Weber, O., 2001. Detailed sesmic-reflection and sedimentary study of turbidite sediment waves on the Var sedimentary Ridge (SE France): significance for sediment transport and deposition and for the mechanisms of sediment-waves construction. Mar. Pet. Geol. 18, 179-208.

Skene, K. I., 1998. Architecture of submarine channel levees. Unpubl. Ph. D. thesis, Dalhousie University, Halifax, 413pp.

Allen, J. R. L., 1982. Sedimentary structures: their characters and physical basis, in Developments in Sedimentology, v I and II. Elsevier, Amsterdam.

Flood, R. D., 1988. A lee wave model for deep-sea mudwave activity. Deep-Sea Res. 35, 973-983.

Kneller, B. C., Buckee, C., 2000. The structure and fluid mechanics of turbidity currents: a review of some recent studies and their geological implications. Sedimentology 57 (Suppl. 1), 62-94.

Deptuck, M. E., Sylvester, Z., Pirmez, C., O’Byrne, C., 2007. Migration-aggradation history and 3D seismic geomorphology of submarine channels in the Pleistocene Benin-major Canyon, western Niger Delta slope. Mar. Pet. Geol., 24, 406-433.

Berne, S., Loubrieu, B., THE CALMAR Shipboard Party, 1999. Canyons et processus sedimentaires recents sur la marge occidentale du Golfe du Lion. Premiers resultats de la campagne Calmar. C. R. Acad. Sci. Paris 328, 471-477.

Kenyon, N. H., Amir, A., Cramp, A., 1995. Geometry of the younger sediment bodies of the Indus Fan. In: Pickering, K. T., Hiscott, R. N., Kenyon, N. H., Lucchi, Ricci, Smith, R. D. A. (Eds.), Atlas of Deep-Water Environments: Architectural style in turbidite systems. Chapman et Hall, London, pp. 89-93.

Pichevin, L., Mulder, T., Savoye, B., Cremer, M., Piper, D. J. W., Gervais, A., 2003. The Golo submarine system (east-Corsica margin): turbidite system morphology and processes of terrace formation from high resolution seismic Boomer profiles. Geo-Mar. Lett. 23 (2), 117-124.

Tranier, J., 2002. Etude des processus sedimentaires dans la parties superieure du canyon de Capbreton. Origine des terrasses. Unpubl. Master thesis, Univ. Bordeaux 1, 31pp.

Hubsher, C., Spiess, V., Breitzke, M., Weber, M. E., 1997. The youngest channel-levee system of the Bengal Fan: results from digital sediment echosounder data. Mar. Geol. 141, 125-145.

Damuth, J. E., Flood, R. D., Kowsmann, R. O., Belderson, R. H., Gorini, M. A., 1988. Anatomy and growth pattern of Amazon deep-sea fan as related by long-range side-scan sonar (GLORIA) and high resolution seismic studies. Am. Assoc. Pet. Geol. Bull. 72 (8), 885-911.

Nakajima, T., Satoh, M., Okamura, Y., 1998. Channel-levee complexes, terminal deep-sea fan and sediment wave fields, associated with the Toyama Deep-Sea Channel system in the Japan Sea. Mar. Geol. 149, 24-41.

Mc Hargue, T., Webb, J. E., 1986. Internal geometry, seismic facies and petroleum potential of canyons and inner fan channels of the Indus Submarine fan. Am. Assoc. Pet. Geol. Bull. 70, 161-180.

Liu, C. S., Lundberg, N., Reed, D. L., Lu, H. Y., 1993. Morphological and seismic characteristics of the Kaoping submarine canyon. Mar. Geol. 111, 93-108.

Cramez, C., Jackson, M. P. A., 2000. Superposed deformation straddling the continental oceanic transition in deep-water Angola. Mar. Pet. Geol. 17, 1095-1109.

O’ Connel, S., McHugh, C., Ryan, W. B. F., 1995. Unique fan morphology in an entrenched Talweg channel on the Rhone fan. In: Pickering, K. T., Hiscott, R. N., Kenyon, N. H., Lucchi, Ricci, Smith, R. D. A. (Eds.), Atlas of Deep-Water environments; Architectural style in turbidite systems. Chapman et Hall, London, pp. 80-83.

Torres, J., Droz, L., Savoye, B., Terentieva, E., Cochonat, P., Kenyon, N. H., et al., 1997. Deep sea avulsion and morpho-sedimentary evolution of the Rhone Fan Valley and Neofan during the Late Quaternary (north-western Mediterranean Sea). Sedimentology 44, 457-477.

Hagen, R. A., Bergersen, D. D., Moberly, R., Coulbourn, W. T., 1994. Morphology of a large meandering submarine canyon system on the Peru- Chile forearc. Mar. Geol. 119, 7-38.

Von Rad, U., Tahir, M., 1997. Late Quaternary sedimentation on the outer Indus shelf and slope (Pakistan): evidence from high-resolution seismic data and coring. Mar. Geol. 138, 193-236.

Normark, W. R., 1970. Growth patterns of deep-sea fans. Am. Assoc. Pet. Geol. Bull. 54 (11), 2170-2195.

Normark, W. R., 1978. Fan valleys, channels and depositional lobes on modern submarine fans: characters for recognition of sandy turbidite environments. Am. Assoc. Pet. Geol. Bull. 62 (6), 912-931.

Gervais, A., 2002. Analyse multi-echelles de la morphologie, de la geometrie et de l’architecture d’un system turbitique sableux profound (systeme du Golo, marge est-Corse, mer Mediterranne). Unpubl. Ph. D. thesis, Univ. Bordeaux 1, 288pp.

Gervais, A., Savoye, B., Mulder, T., Piper, D. J. W., Cremer, M., Pichevin, L., 2004. Present morphology and depositional architecture of a sandy submarine system: The Golo turbidite system (Eastern margin of Corsica). In: Lomas, S., Joseph, P. (Eds.), Confined Turbidite Sistems, Geological Society, London, Special Publication, 222, 59-89.

Bouma, A., Normark, W., Barnes, N. (Eds.), 1985. Submarine fans and related turbidite systems. Springer-verlag, New York 351pp.

Jerou, I., 2088. Etude de la transition chenal/levee/lobe dans les systemes turbiditiques recents. Application a l’eventail turbidique de l’Amazone et au neofan du Petit-Rhone. Unpubl. Ph. D. thesis, Univ. Bretagne Occidentale 1, 351pp.

Wynn, R. B., Kenyon, N. H., Masson, D. G., Stow, D. A. V., Weaver, P. P. E., 2002. Characterization and recognition of deep water channel-lobe transition zones. Am. Assoc. Pet. Geol. Bull 86 (8), 1441-1446.

Normark, W. R., Piper, D. J. W., Hess, G. R., 1979. Distributary channels, sand lobes and mesotopography of navy submarine fan, California Borderland with application to ancient fan sediments. Sedimentology 26, 749-774.

Normark, W. R., Piper, D. J. W., Stow, D. A. V., 1983. Quanternary development of channels, levees and lobes on middle Laurentian Fan. Am. Assoc. Pet. Geol. Bull. 67 (9), 1400-1409.

Morris, W. R., Kenyon, N. H., Limonov, A., Alexander, J., 1998. Downstream changes of large scale bedforms in turbidites around the Valencia channel mouth, north west Mediterranean: implications for paleoflow reconstruction. Sedimentology 45 (2), 365-377.

Savoye, B., Cochonat, P., Apprioual, R., Bain, O., Baltzer, A., Bellec, V., et al., 2000. Structure and recent evolution of the Zaire deep sea fan: preliminary results of the Zaiango 1&2 cruises (Angola- Congo margin). C. R. Acad. Sci. IIA 331 (3), 211-220.

Twitchell, D. C., Kenyon, N. H., Parsons, L. M., Mc Gregor, B. A., 1991. Depositional patterns of the Mississippi fan surface: Evidence from GLORIA II and high resolution seismic profiles. In: Link, M. L. (Ed.), Seismic facies and sedimentary process of submarine fans and turbidite systems. Springer-Verlac New York, pp. 349-363.

Mutti, E., Ricci Lucchi, F., 1972. Le torbiditi dell’ Appennino settentrionale: introduction all’ analisi de facies. Mem. Soc. Geol. It. 11, 161-199.

Gardner, J. V., Bohannon, R. G., Field, M. E., Masson, D. G., 1996. The morphology, process and evolution of Monterey Fan: a revisit. In: Gardner, J. V., Field, M. E., Twichell, D. G., (Eds.), Geology of United States seafloor. The view from GLORIA. Cambridge University Press, Cambridge, UK, pp. 193-220.

Jerou, I., Savoy, B., Primez, C., Droz, L., 2008. Channel mouth lobe complex of the recent Amazon fan: the missing piece. Mar. Geol. 252, 62-77.

Deptuck, M. E., Piper, D. J. W., Savoye, B., Gervais, A., 2008. Dimensions and architecture of late Pleistocene submarine lobes off the northern margin of East Corsica. Sedimentology 926, 1-32.

Prelat, A., Hodgson, D. M., Flint, S. S., 2009. Evolution, architecture and hierarchy of distributary deep water deposits: a high resolution outcrop investigation from the Permian Karoo Basin, South Africa, Sedimentology 56, 2132-2154.

Mulder, T., Etienne, S., 2010. Lobes in deep sea turbidite systems State of the art. In: Mulder, T. (Ed.), Sedimentary Geology 211, 75-80 Special Issue on Lobes in Deep Sea Turbidite Systems.

Gervais, A., Mulder, T., Savoye, B., 2006. Sandy modern turbidite lobes: a new insight from high resolution seismic data. Mar. Pet. Geol. 23, 485-502.

Posamentier, H. W., Vail, P. R., 1988. Eustatic controls on classic deposition II sequence and systems tract madels. In: Wilgus, C., Hastings, B., Posamentier, H., Van Wagoner, J., Ross, C., Kendal, G., (Eds.), Sea level changes: An integrated approach, SEPM, special publication 42, 125-154.

Milliman, J. D., Syvitski, J. P. M., 1992. Geomorphic tectonic control of sediment discharge to the ocean: the importance of small mountainous rivers. J. Geol. 100, 525-544.

Schumm, S. A., 1963. Disparity between modern rates of denudation and orogeny, USGS Prof. Paper 454-H 13pp.

Jervey, M. T., 1988. Quantitative geological modelling of siliciclastic rock sequence and their seismic expression. In: Wilgus, C., Hastings, B., Posamentier, H., Van Wagoner, J., Ross, C., Kendall, G., (Eds.), Sea level changes: An intergraded approach, EEPM Spec. Publ., 42, 48-69.

Posamentier, H. W., Allen, G. P., 1999. Siliciclastic sequence stratigraphy concepts and appllications, SEPM concepts in sedimentology and Paleontology no. 7 210pp.

Homewood, P., Mauriaud, P., Lafont, F., 2000. Vade-Mecum de straitigraphie sequentielle, Elf EP editions Memoire, 25 81pp.

Ferry, J. N., Mulder, T., Parize, O., Raillard, S., 2005. Equilibrium profile in deep water turbidite systems: effects of local physiographic changes on deposits geometries and nature of sedimentary process. In: Hodgson, D. M., Flint, S. S., (Eds.), Submarine slope systems. Processes and products, Geol. Soc., London, Special Publication, 244, 181-193.

Mutti, E., 1985. Turbidite systems and their relations to depositional sequences. In: Zuffa, G. (Ed.), Provenance of anerites, D. Reidel Publishing Co, Dordrecht, Holland, 65-93.

Schumm, S. A., 1993. River response to base level change: implication for sequence stratigraphy. J. Geol. 101, 279-294.

Normark, W. R., Piper, D. J. W., Romans, B. W., Covault, J. A., Dartnell, P., Sliter, R. W., 2009. Submarine canyons and fan systems of the California Borderland. The Geol. Soc. America, Spec. Paper 454, pp.141-168.

Galay, V., 1987. In erosion and sedimentation in the Nepal Himalaya (pp. 10.11). Singapore: Kefford Press Pvt. Ltd.

Middleton, G. V. 1967. Experiments on density and turbidite currents III: deposition of sediment. Canadian Journal of Earth Sciences, 4, 475-505.

Middleton, G. V. 1966. Experiments on density and turbidite currents I: motion of the head. Canadian Journal of Earth Sciences, 3, 523-546.

Coussot, P., Meunier, M. 1996. Recognition, classification and mechanical description of debris flows. Earth –science Reviews, 40, 209-227.

Wallis, G. B. 1969. In one dimensional two phase flow (pp.408). New York: McGraw-Hill.

Lowe, D. R. 1982. Sediment gravity flows: II depositional models with special reference to the deposition of high density turbidity currents. Journal of sedimentary petrology, 52, 279-297.

Shultz, A. W. 1984. Subaerial debris flow deposition in the upper Paeozoic Cutler formation, western Colorado. Journal of sedimentary petrology, 54, 759-772.

Rodine, JD., Johnson, A. M. 1976. The ability of debris, heavily freighted with coarse clastic material to flow on flow on gentle slopes. Sedimentology, 23, 213-234.

Carey, S. N., Schneider, J. L., 2011. Volcaniclastic processes and deposits in the deep sea. In: Huneke, H., Mulder, T. (Eds.)., Deep sea sediments. Developments in sedimentology, Elsevier, Amsterdam, Vol. 63, pp. 457-515.

Mulder, T., Cochonat, P., 1996. Classification of offshore mass movements. J. Sediment. Res. 66, 46-57.

Stow, D. A. V., Reading, H. G., Collison, J D., 1996. Deep seas. In: Reading, H. G. (Ed), Sedimentary environments processes, facies and stratigraphy. Blackwell science, Oxford, pp. 395-453.

Gaudin, M., Berne, S., Jouanneau, J. M, Palanques, A., Puig, P., Mulder, T., et al., 2006a. massive sand beds attribute to deposition by dense water cascades in the Bourcart canyon head, Gulf of Lios (northwestern Mediterranean Sea). Mar. Geol. 234, 111-128.

Faugeres, J. C., Gonythier, E., Bodier, C., Griboulard, R. 1997. Tectonic control on sedimentary processes in the southern termination of the Barbados prism. Mar. Geol. 140, 117-140.

Skempton, A. W., Hutchinson, J. N., 1969. Stability of natural slopes and embankment foundations, State of the art report. In: Proc. 7th Int. Conf. SMFE, Mexico City, vol. 2291-335.

Mohrig, D., Whipple, K. X., Hondzo, M., Ellis, C., Parker, G., 1998. Hydroplaning of subaqueous debris flows. Geol. Soc. Am. Bull. 110 (3), 387-394.

Johnson, A. M., 1970. Physical process in geology, Cooper and Co., San Francisco, 577pp.

Johnson, A. M., 1984. Debris flow, In: Brunden, D., Prior, D. B. (Eds), Slope instability. Wiley, Toronto, pp.257-362.

Rodine, J. D., Johnson, A. M., 1976. The ability of debris, heavily freighted with coarse clastic materials, to flow on gentle slopes, sedimentology 23, 213-234.

Van Weerng, T. C. E., Nielsen, T., Kenyion, N. H., Akentieva, K., Kuijpers, A. H., 1998. Large submarine slides on the NE Faeroe continental margin. In: Stoker, M. S., Evans, D., Cramp, A. (Eds), Geological processes on continental margins: sedimentation, Mass- wasting and stability, Geol. Soc. London, Spec. Publ. 129, 5-17.

Hampton, M. A., 1972. The role of subaqueous debris flow in generating turbidity currents. J. Sediment. Petrol. 42, 775-793.

De Vries Klein, G., 1982. Sandstone depositional models for exploration for fossil fuels. Geological science series 209pp.

Warrick, J. A., Milliman, J. D. 2003. Hyperpycnal sediment discharge from semi-arid southern California rivers: implications for coastal sediments budgets. Eology 31 (9), 781-784.

Syvitski, J. P. M., Schafer, C. T., 1996.Evidence for an earthquake triggered basin collapse in

Hesse, R., Klauke, I., Ryan, W. B. F., Edwards, M. B., Piper, D. J. W., NAMOC study group, 1996. Imaging Laurentide ice sheet drainage into the deep sea: impact on sediments and bottom water. Geol. Soc. Am. Today 3-9.

Hesse, R., Khodabakhsh, S., 1998. Depositional facies of late Pleistocene Heinrich events in the Labrador Sea. Geology 26 (2), 103-106.

Schafer, C. T., Smith, J. N., 1987. Hypothesis for a submarine landslide and cohesionless sediment flows, resulting from a 17th century earthquake-triggered landslide in Quebec, Canada. Geo-Mar. Lett. 7, 31-37.

Wright, L. D., Yang, Z.-S., Bornhold, B. D., Keller, G. H., Prior, D. B., Wisenam Jr., W. J., 1986. Hyperpycnal flows and flow fronts over the Huanghe (Yellow River) delta front. Geo-Mar. Lett. 6, 97-105.

Wright, L. D., Wisenam Jr., W. J., Bornhold, B. D., Prior, D. B., Suhayda, J. N., Keller, G. H., et. al., 1988. Marine dispersal and deposition of Yellow River silts by gravity-driven underflows. Nature 332, 629-632.

Wright, L. D., Wisenam Jr., Yang, Z.-S., Bornhold, B. D., Keller, G. H., Prior, D. B., et. al., 1990. Processes of marine dispersal and deposition of suspended silts off the modern mouth of the Huanghe (Yellow River). Cont. Shelf Res. 10, 1-40.

Mulder, T., Syvitski, J. P. M., 1995. Turbidity currents generated at river mouths during exceptional discharges to the world oceans. J. Geol. 103, 285-299.

Myrow, P. M., Fisher, W., Goodge, J. W., 2002. Wave-modified turbidites: Combined-flow shoreline and shelf deposits, Cambrian, Antarctica. J. Sediment. Res. 72, 641-656.

Lamp, M. P., Myrow, P. M., Lukens, C., Houck, K., Strauss, J., 2008. Deposits from wave-influenced turbidity currents: Pennsylvanian Minturn Formation, Colorado, USA. J. Sediment. Res. 78, 480-498.

Hoyal, D. C., Bursik, M. I., Atkison, J. F., 1999. Settling driven convection: A mechanism of sedimentation from stratified fluids. J. Geophys. Res. 104, 7953-7966.

Chikita, K., 1991. Dynamic processes of sedimentation by river induced turbidity currents. II. Application of a two-dimensional, advective diffusion model. Jpn. Geomorphol. Union Trans 13-1, 1-18.

Parson, J. D., Bush, J., Syvitski, J. P. M., 2001. Hyperpycnal flow formation with small sediment concentrations. Sedimentology 48, 465-478.

Postma, G., Nemec, W., Zachariasse, W. J., 1988. Large floating clasts in turbidites: A mechanism for their emplacement. Sediment. Geol. 58, 47-61.

Lowe, D. R., 1982. Sediment gravity flows: II. Depositional models with special reference to the deposits of high-density turbidity currents. J. Sediment. Petrol. 52, 279-297.

Kuenen, P. H., 1950. Turbidity currents of high density. In: Geol. Congr., 18th, London, 1948, 44-52, rept. 8.

Fisher, R. V., 1983. Flow transformations in sediment gravity flows. Geology 11, 273-274.

Shanmugam 2000 Shanmugam (2000) 50 years of the turbidite paradigm (1950s–1990s): Deep-water processes and facies models—A critical perspective, Marine and Petroleum Geology 17: 285–342

Normark, W. R., Piper, D. J. W., 1991. Initiation processes and flow evolution of turbidity currents: Implications for the depositional record. SEPM Special Publication 46 pp. 207-229.

Bjerrum, L., 1971. Subaqueous slope failures in Norwegian fjords. Norge Geotech. Bull. No 88 pp. 1-8.

Prior, D. B., Suhayda, J. N., Lu, N.-Z., Bornhold, B. D., Keller, G. H., Wiseman, W. J., et. al., 1989. Storm wave reactivation of a submarine landslide. Nature 341, 47-50.

Mulder, T., Weber, O., Anschutz, P., Jorissen, F. J., Jouanneau, J.-M., 2001c. A few months-old storm-generated turbidite deposited in the Capbreton Canyon (Bay of Biscay, S-W France). Geo-Mar. Lett.21 (3), 149-156.

Klaucke, I., Masson, D. G., Kenyon, N. H., Gardner, J. V., 2004. Sedimentary processes of the lower Monterey Fan channel and channel-mouth lobe. Mar. Geol. 206 (1-4), 181-198.

Mosher, D. C., Piper, D. J. W., Campbell, D. C., Jenner, K., 2004. Near surface geology and sediment-failure geohazards of the central Scotian Slope. Am. Assoc. Pet. Geol. Bull. 88, 703-723.

Puig, P., Ogston, A. S., Mullenbach, B. L., Nittrouer, C. A., Sternberg, R. W., 2003. Shelf to canyon sediment-transport processes on the Eel continental margin (northen California). Mar. Geol. 193, 129-149.

Lamb, M. P., Parson, J. D., 2005. High-density suspensions formed under waves. J. Sediment. Res. 75, 386-397.

Bornhold, B. D., Ren, P., Prior, D. B., 1994. High-frequency turbidity currents in British Columbia fjords. Geo-Mar. Lett. 14, 238-243.

Beck, C., Schneider, J.-L., Cremer, M., MercierdeLepinay, B., Cagatay, N., Labeyrie, L., et. al., 2003. Late Pleistocene major sedimentary reworking event (homogeneite) in Marmara Sea Central Basin: Preliminary results of giant piston-coring and high-resolution seismic reflection. In: EGS-AGU joint meeting 6-11 April, 2003, Nice, France.

Giresse, P., Pauc, H., Deverchere, J., Savoye, B., The MARADJA Scientific Party, 2004. Gravity induced transport on the Algerian margin. In: EGU 1st meeting Nice, France, 25-30 April, 2004.

Singh, S. C., 2005. Sumatra earthquake research indicates why rupture propagated northward. EOS Trans. Am. Geophys. Union 86 (48), 497-502.

King, L. H., Mac Lean, B., 1970. Pockmarks on the Scotian shelf. Geol. Soc. Am. Bull. 81, 3141-3148.

Hovland, M., Judd, A. G., 1988. Seabed pockmarks and seepages. Graham and Trotman, London, 293pp.

Boe, R., Rise, L., Ottesen, D., 1998. Elongated depressions on the southern slope of the Norwegian Trench (Skagerrak): morphology and evolution. Mar. Geol. 146 (1-4), 191-203.

Le Moigne, M., 1999. Comprehansion des mecanismes de formation des pockmarks sur la pente du Golfe de Guinee. Unpubl. Master thesis, Univ. Sci. Tech Lille 1.

Josenhans, H. W., King, L. H., Fader, G. B., 1978. A side scan sonar mosaic of pockmarks on the Scotian Shelf. Can. J. Earth Sci. 15, 831-840.

Baraza, J., Ercilla, G., 1996. Gas-charged sediments and large pockmark like features on the Gulf of Cadiz slope (SW Spain). Mar. Pet. Geol. 13 (2), 253-261.

Dimitrov, L. I., 2002. Mud volcanoes the most important pathway for degassing deeply buried sediments. Earth Sci. Rev. 59 (1-4), 49-76.

Syvitski, J. P. M., 2003. Sediment fluxes and rates of sedimentation. In: Middleton, G. V. (Ed), Encyclopedia of sediments and sedimentary rocks. Kluwer Academic Publisher, Dordrecht, Netherlands, pp 600-606.

Bates, C. C., 1953. Rational theory of delta formation. Bull. Am. Assoc. Pet. Geol. 37 (9), 2119-2162.

Mulder, T., Alexander, J., 2001a. The physical character of sedimentary density currents and their deposits. Sedimentology 48, 269-299.

Rimoldi, B., Alexander, J., Morris, S. A., 1996. Experimental turbidity currents entering density stratified water: Analogues for turbidites in Mediterranean hypersaline basins. Sedimentology 43, 527-540.

Bates, C. C., 1953. Rational theory of delta formation. Bull. Am. Assoc. Pet. Geol. 37 (9), 2119-2162.

Mutti, E., Davoli, G., Tinterri, R., Zavala, C., 1996. The importance of ancient fluviodeltaic systems dominated by catastrophic flooding in tectonically active basins. Sci. Geol. Mem. 48, 233-291.

Mutti, E., Tinterri, R., di Biase, D., Fava, L., Mavilla, N., Angella, S., et. al., 2000. Delta front facies associations on ancient flood dominated fluvio deltaic systems. Rev. Soc. Geol. Espana 13 (2), 165-190.

Heezen, B. C., Ewing, M., 1952. Turbidity currents and submarine slumps and the 1929 Grand Banks earthquake. Am. J. Sci. 250, 849-873.

Komar, P. D., 1971. Hydraulic jumps in turbidity currents. Geol. Soc. Am. Bull. 82, 1477-1488.

Garcia, M. H., Parker, G., 1989. Experiments on hydraulic jumps in turbidity currents near a canyon- fan transition. Science 245, 393-396.

Mohrig, D., Elverhoi, A., Parker, G., 1999. Experiments on relative modify of muddy subaqueous and subaerial debris flows and their capacity to remobilize antecedent deposits. Mar. Geol. 154, 117-129.

Bates, R. L., Jckson, J. A., 1980. Glossary of Geology, second ed. American Geologicate institute, Falls Church, Virginia 751p.

Marr, J., Harff, P., Shanmugam, G., Parker, G. 1997. Experiments on subaqueous sandy debris flow. Supplement to EOS Transactions, AGU Fall Meeting, San Francisco, 78, Number 46, F 347.

Parker, G., 1982. Conditions for the ignition of catastrophically erosive turbidity currents. Mar. Geol. 46, 307-327.

Alexander, J., Morris, S., 1994. Observations on experimental, non-channelized, high concentration turbidity currents and variations in deposits around obstacles. J. Sediment. Res. A 64, 899-909.

Garcia, M. H., 1994. Depositional turbidity currents laden with poorly sorted sediment. J. Hydraul. Eng. 120, 1240-1263.

Mulder, T., Alexander, J., 2001b. Abrupt change in slope causes variation in the deposit thickness of concentrated particle driven density currents. Mar. Geol. 175, 221-235.

Ravenne, C., Beghin, P., 1983. Apport des experiences en canal a l’interpretation sedimentologyque des depots de cones detriques sous-marines. Rev. Inst. Fr. Petrol. 38, 279-297.

Pochat, S., 2003. Escarpement de faille syssedimentaire. Perturbation deseoulements gravitaires sous marins et determination de la cinetique des failles. Ph. D. Thesis, Univ. Rennes 1, Memoires Geosciences Rennes no. 105, 283 pp.

Lutjeharms, J. R. E., 1996. The exchange of water between the South Indian and South Atlantic oceans. In: Wefer, G., Berger, W. H., Siedler, G., Webb, D. J. (Eds). The south Atlantic: Presents and past circulation. Springer- Verlag, Berlin, Heidelberg, pp. 125-162.

Schmitz, W. J., 1996. On the world ocean circulation. The Pacific and Indian Oceans. A global Update. Technical report, WHOI-96-08, vol. II.

McCave, I. N., 1986. Local and global aspects of the bottom nepheloid layers in the world ocean. J. Sea Res. (Netherlands) 20 (2-3), 167-181.

Masse, L., Faugeres, J. C., Pujol, C., Pujos, A., Labeyrie, L. D., Bernat, M., 1996. Sediment flux distribution in the Southern Brazil Basin during the late Quaternary: The role of deep sea currents. Sedimentology 43, 115-132.

Biscaye, P. E., Eitreim, S. L., 1977. Suspended particulate loads and transport in the nepheloid layer of the abyssal Atlantic Ocean. Mar. Geol. 23, 155-172.

Ewing, M., Thorndike, E. M., 1965. Suspended matter in deep ocean water. Science 147, 1291-1294.

Jerlov, N. G., 1953. Particle distribution in the ocean. Rep. Swed. Deep sea Expedition 3, 73-97.

McCave, I. N., 1984. Erosion, transport and deposition of fine grained marine sediments. Geol. Soc. London, Sp. Pub. 15pp. 35-69.

Εισερχόμενη Αναφορά

Δεν υπάρχουν προς το παρόν εισερχόμενες αναφορές.