Volume 40 Issue 2
Apr.  2021
Turn off MathJax
Article Contents
Yintao Lu, Xiwu Luan, Boqing Shi, Weimin Ran, Fuliang Lü, Xiujuan Wang, Quanbin Cao, Xiaoyong Xu, Hui Sun, Genshun Yao. Migrated hybrid turbidite-contourite channel-lobe complex of the late Eocene Rovuma Basin, East Africa[J]. Acta Oceanologica Sinica, 2021, 40(2): 81-94. doi: 10.1007/s13131-021-1750-1
Citation: Yintao Lu, Xiwu Luan, Boqing Shi, Weimin Ran, Fuliang Lü, Xiujuan Wang, Quanbin Cao, Xiaoyong Xu, Hui Sun, Genshun Yao. Migrated hybrid turbidite-contourite channel-lobe complex of the late Eocene Rovuma Basin, East Africa[J]. Acta Oceanologica Sinica, 2021, 40(2): 81-94. doi: 10.1007/s13131-021-1750-1

Migrated hybrid turbidite-contourite channel-lobe complex of the late Eocene Rovuma Basin, East Africa

doi: 10.1007/s13131-021-1750-1
Funds:  The China-ASEAN Maritime Cooperation Fund Project under contract No. 12120100500017001; the National Natural Science Foundation of China under contract Nos 42076219, 92055211 and 42006067.
More Information
  • Corresponding author: E-mail: xluan@qnlm.ac
  • Received Date: 2019-08-27
  • Accepted Date: 2020-05-25
  • Available Online: 2021-04-02
  • Publish Date: 2021-04-02
  • Analysis of 3D seismic data and well log data from the Rovuma Basin in East Africa reveals the presence of a late Eocene channel-lobe complex on its slope. The first two channels, denoted as channel-1 and channel-2, are initiated within a topographic low on the slope but come to a premature end when they are blocked by a topographic high in the northwest region of the basin. New channels migrate southeastward from channel-1 to channel-6 due to the region’s sufficient sediment supply and stripping caused by bottom currents. The primary factors controlling the development of the channel complex include its initial paleo-topographic of seafloor, the property of gravity flows, the direction of the bottom current, and the stacking and expansion of its levees. The transition zone from channel to lobe can also be clearly identified from seismic sections by its pond-shaped structure. At a certain point, thest systems record a transiton from erosive features to sedimentary features, and record a transition from a confined environment to an open environment. Channels and lobes can be differentiated by their morphologies: thick slump-debris flows are partly developed under channel sand sheets, whereas these slump-debris flows are not very well developed in lobes. Well log responses also record different characteristics between channels and lobes. The interpreted shale volume throughout the main channel records a box-shaped curve, thereby implying that confined channel complexes record high energy currents and abundant sand supply, whereas the interpreted shale volume throughout the lobe records an upward-fining shape curve, thereby indicating the presence of a reduced-energy current in a relatively open environment. Within the Rovuma Basin of East Africa, the average width of the Rovuma shelf is less than 10 km, the width of the slope is only approximately 40 km, and the slope gradient is 2°–4°. Due to this steep slope gradient, the sand-rich top sheet within the channel also likely contributes to the straight feature of the channel system. It is currently unclear whether the bottom current has any effect on its sinuosity.
  • loading
  • [1]
    Abreu V, Sullivan M, Pirmez C, et al. 2003. Lateral accretion packages (LAPs): an important reservoir element in deep water sinuous channels. Marine and Petroleum Geology, 20(6–8): 631–648
    [2]
    Bain H A, Hubbard S M. 2016. Stratigraphic evolution of a long-lived submarine channel system in the Late Cretaceous Nanaimo Group, British Columbia, Canada. Sedimentary Geology, 337: 113–132
    [3]
    Barnes N E, Normark W R. 1985. Diagnostic parameters for comparing modern submarine fans and ancient turbidite systems. In: Bouma A H, Normark W R, Barnes N E, eds. Submarine Fans and Related Turbidite Systems. New York: Springer-Verlag, 13–14
    [4]
    Bassias Y. 1992. Petrological and geochemical investigation of rocks from the Davie fracture zone (Mozambique Channel) and some tectonic implications. Journal of African Earth Sciences, 15(3–4): 321–339
    [5]
    Bird D. 2001. Shear margins: Continent-ocean transform and fracture zone boundaries. The Leading Edge, 20(2): 150–159
    [6]
    Bouma A H. 1962. Sedimentology of Some Flysch Deposits: A Graphic Approach to Facies Interpretation. Amsterdam: Elsevier
    [7]
    Bouma A H, Normark W R, Barnes N E. 1985. Submarine Fans and Related Turbidite Systems. New York: Springer
    [8]
    Bowen A J, Normark W R, Piper D J W. 1984. Modelling of turbidity currents on Navy Submarine Fan, California Continental Borderland. Sedimentology, 31(2): 169–185
    [9]
    Breitzke M, Wiles E, Krocker R, et al. 2017. Seafloor morphology in the mozambique channel: evidence for long-term persistent bottom-current flow and deep-reaching eddy activity. Marine Geophysical Research, 38(3): 241–269
    [10]
    Callow R H T, Kneller B, Dykstra M, et al. 2014. Physical, biological, geochemical and sedimentological controls on the ichnology of submarine canyon and slope channel systems. Marine and Petroleum Geology, 54: 144–166
    [11]
    Civitelli G. 1988. The Meso-Cenozoic sedimentary sequence of the Cabo Delgado Province, Mozambique. Journal of African Earth Sciences, 7(4): 629–639
    [12]
    Clark J D, Kenyon N H, Pickering K T. 1992. Quantitative analysis of the geometry of submarine channels: Implications for the classification of submarine fans. Geology, 20(7): 633–636
    [13]
    Clark J D, Pickering K T. 1996. Architectural elements and growth patterns of submarine channels: Application to hydrocarbon exploration. AAPG Bulletin, 80(2): 194–220
    [14]
    Coffin M F, Rabinowitz P D. 1987. Reconstruction of Madagascar and Africa: Evidence from the Davie Fracture Zone and Western Somali Basin. Journal of Geophysical Research: Solid Earth, 92(B9): 9385–9406
    [15]
    Coffin M F, Rabinowitz P D. 1992. The Mesozoic East African and Madagascan conjugate continental margins: Stratigraphy and tectonics. In: Watkins J S, Feng C C, McMillen K J, eds. Geology and Geophysics of Continental Margins. AAPG Memoir, 53: 207–240
    [16]
    Covault J A, Graham S A. 2010. Submarine fans at all sea-level stands: Tectono-morphologic and climatic controls on terrigenous sediment delivery to the deep sea. Geology, 38(10): 939–942
    [17]
    Covault J A, Normark W R, Romans B W, et al. 2007. Highstand fans in the California borderland: The overlooked deep-water depositional systems. Geology, 35(9): 783–786
    [18]
    Cronin B T, Çelik H, Hurst A, et al. 2005. Mud prone entrenched deep-water slope channel complexes from the Eocene of Eastern Turkey. In: Hodgson D M, Flint S S, eds. Submarine Slope Systems: Processes and Products. London: The Geological Society of London, 224: 155–180
    [19]
    Daszinnies M C, Jacobs J, Wartho J A, et al. 2009. Post Pan-African thermo-tectonic evolution of the north Mozambican basement and its implication for the Gondwana rifting. Inferences from 40Ar/39Ar hornblende, biotite and titanite fission-track dating. In: Lisker F, Ventura B, Glasmacher U A, eds. Thermochronological Methods: from Palaeotemperature Constraints to Landscape Evolution Models. London: The Geological Society of London, 324: 261–286
    [20]
    Deptuck M E, Piper D J W, Savoye B, et al. 2008. Dimensions and architecture of late Pleistocene submarine lobes off the northern margin of East Corsica. Sedimentology, 55(4): 869–898
    [21]
    Deptuck M E, Sylvester Z, Pirmez C, et al. 2007. Migration-aggradation history and 3-D seismic geomorphology of submarine channels in the Pleistocene Benin-major Canyon, western Niger Delta slope. Marine and Petroleum Geology, 24(6–9): 406–433
    [22]
    Emmel B, Kumar R, Ueda K, et al. 2011. Thermochronological history of an orogen-passive margin system: An example from northern Mozambique. Tectonics, 30(2): TC2002
    [23]
    Falivene O, Arbués P, Gardiner A, et al. 2006. Best practice stochastic facies modeling from a channel-fill turbidite sandstone analog (the Quarry outcrop, Eocene Ainsa basin, northeast Spain). AAPG Bulletin, 90(7): 1003–1029
    [24]
    Flores G M, Blant G T. 1973. The Cretaceous and Tertiary sedimentary basins of Mozambique and Zululand. In: Blan G T, ed. Sedimentary Basins of the African Coasts. Part II. Paris: Association of African Geology Surveys, 81–111
    [25]
    Fonnesu F. 2013. The Mamba complex supergiant gas discovery (Mozambique): An example of turbidite fans modified by deepwater tractive bottom currents. In: The 12th PESGB/HGS Conference on African E&P. London: PESGB Conferences Ltd.
    [26]
    Fonnesu M, Palermo D, Galbiati M, et al. 2020. A new world-class deep-water play-type, deposited by the syndepositional interaction of turbidity flows and bottom currents: The giant Eocene Coral Field in northern Mozambique. Marine and Petroleum Geology, 111: 179–201
    [27]
    Förster R. 1975. The geological history of the sedimentary basin of southern Mozambique, and some aspects of the origin of the Mozambique Channel. Palaeogeography, Palaeoclimatology, Palaeoecology, 17(4): 267–287
    [28]
    Fuhrmann A, Kane I A, Clare M A, et al. 2020. Hybrid turbidite-drift channel complexes: An integrated multiscale model. Geology, 48(6): 562–568
    [29]
    Gutscher M A, Malod J, Rehault J P, et al. 2002. Active subduction beneath the Gibraltar arc. In: EGS XXVII General Assembly. Nice: European Geosciences Union
    [30]
    Hancox P J, Brandt D, Edwards H. 2002. Sequence stratigraphic analysis of the Early Cretaceous Maconde Formation (Rovuma basin), northern Mozambique. Journal of African Earth Sciences, 34(3–4): 291–297
    [31]
    Hofstra M, Hodgsona D M, Peakall J, et al. 2015. Giant scour-fills in ancient channel-lobe transition zones: Formative processes and depositional architecture. Sedimentary Geology, 329: 98–114
    [32]
    Jacobs J, Thomas R J. 2004. Himalayan-type indenter-escape tectonics model for the southern part of the Late Neoproterozoic-Early Paleozoic East African–Antarctic orogen. Geology, 32(8): 721–724
    [33]
    Jegou I, Savoye B, Pirmez C, et al. 2008. Channel-mouth lobe complex of the recent Amazon Fan: The missing piece. Marine Geology, 252(1–2): 62–77
    [34]
    Kenyon N H. 1992. Deep sea siliciclastic systems: a plan view perspective. In: Sequence Stratigraphy of European Basins. Dijon: CNRS-IFP, 458–459
    [35]
    Kenyon N H, Klaucke I, Millington J, et al. 2002. Sandy submarine canyon-mouth lobes on the western margin of Corsica and Sardinia, Mediterranean Sea. Marine Geology, 184(1–2): 69–84
    [36]
    Key R M, Smith R A, Smelror M, et al. 2008. Revised lithostratigraphy of the Mesozoic-Cenozoic succession of the onshore Rovuma Basin, northern coastal Mozambique. South African Journal of Geology, 111(1): 89–108
    [37]
    Kolla V. 2007. A review of sinuous channel avulsion patterns in some major deep-sea fans and factors controlling them. Marine and Petroleum Geology, 24(6–9): 450–469
    [38]
    Kolla V, Posamentier H W, Wood L J. 2007. Deep-water and fluvial sinuous channels—Characteristics, similarities and dissimilarities, and modes of formation. Marine and Petroleum Geology, 24(6–9): 388–405
    [39]
    König M, Jokat W. 2006. The Mesozoic breakup of the Weddell Sea. Journal of Geophysical Research, 111: B12102
    [40]
    Lewis K B, Pantin H M. 2002. Channel-axis, overbank and drift sediment waves in the southern Hikurangi trough, New Zealand. Marine Geology, 192(1–3): 123–151
    [41]
    Lin Yu, Wu Shenghe, Wang Xing, et al. 2013. Research on architecture model of deepwater turbidity channel system: a case study of a deepwater research area in Niger Delta Basin, West Africa. Geological Review (in Chinese), 59(3): 510–520
    [42]
    Lin Yu, Wu Shenghe, Wang Xing, et al. 2014. Research on reservoir architecture models of deep-water turbidite lobes. Natural Gas Geoscience (in Chinese), 25(8): 1197–1204
    [43]
    Lowe D R. 1982. Sediment gravity flows: II, depositional models with special reference to the deposits of high-density turbidity currents. Journal of Sedimentary Research, 52(1): 279–297
    [44]
    Lu Yintao, Li Wei, Wu Shiguo, et al. 2018. Morphology, architecture, and evolutionary processes of the Zhongjian Canyon between two carbonate platforms, South China Sea. Interpretation, 6(4): SO1–SO15
    [45]
    Mahanjane E S, Franke D. 2014. The Rovuma Delta deep-water fold-and-thrust belt, offshore Mozambique. Tectonophysics, 614: 91–99
    [46]
    Mayall M, Jones E, Casey M. 2006. Turbidite channel reservoirs—key elements in facies prediction and effective development. Marine and Petroleum Geology, 23(8): 821–841
    [47]
    Mayall M, Lonergan L, Bowman A, et al. 2010. The response of turbidite slope channels to growth-induced seabed topography. AAPG Bulletin, 94(7): 1011–1030
    [48]
    McHargue T, Pyrcz M J, Sullivan M D, et al. 2011. Architecture of turbidite channel systems on the continental slope: Patterns and predictions. Marine and Petroleum Geology, 28(3): 728–743
    [49]
    Migeon S, Savoye B, Babonneau N, et al. 2004. Processes of sediment-wave construction along the present Zaire deep-sea meandering channel: Role of meanders and flow stripping. Journal of Sedimentary Research, 74(4): 580–598
    [50]
    Mulder T, Gonthier E, Lecroart P, et al. 2009. Sediment failures and flows in the Gulf of Cadiz (eastern Atlantic). Marine and Petroleum Geology, 26(5): 660–672
    [51]
    Nairn A E M, Lerche I, Iliffe J E. 1991. Geology, basin analysis, and hydrocarbon potential of Mozambique and the Mozambique Channel. Earth-Science Reviews, 30(1–2): 81–123
    [52]
    Normark W R. 1970. Growth patterns of deep-sea fans. AAPG Bulletin, 54(11): 2170–2195
    [53]
    Normark W R. 1978. Fan valleys, channels, and depositional lobes on modern submarine fans: Characters for recognition of sandy turbidite environments. AAPG Bulletin, 62(6): 912–931
    [54]
    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. Special Paper of the Geological Society of America, 370: 175–190
    [55]
    Normark W R, Piper D J W, Hess G R. 1979. Distributary channels, sand lobes, and mesotopography of Navy Submarine fan, California Borderland, with applications to ancient fan sediments. Sedimentology, 26(6): 749–774
    [56]
    Normark W R, Piper D J W, Hiscott R N. 1998. Sea level controls on the textural characteristics and depositional architecture of the Hueneme and associated submarine fan systems, Santa Monica Basin, California. Sedimentology, 45(1): 53–70
    [57]
    Palermo D, Galbiati M, Famiglietti M, et al. 2014. Insights into a new super-giant gas field - sedimentology and reservoir modeling of the coral reservoir complex, offshore northern Mozambique. In: Offshore Technology Conference-Asia. Kuala Lumpur: OTC Asia
    [58]
    Palermo D, Galbiati M, Mezzapesa D, et al. 2015. Sequence stratigraphy, sedimentology and reservoir modelling of the Coral reservoir, offshore northern Mozambique. In: Offshore Mediterranean Conference and Exhibition. Ravenna: OMC
    [59]
    Paull C K, Caress D W, Ussler W, et al. 2011. High-resolution bathymetry of the axial channels within Monterey and Soquel submarine canyons, offshore central California. Geosphere, 7(5): 1077–1101
    [60]
    Payton C E. 1977. Seismic Stratigraphy—Applications to Hydrocarbon Exploration. Tulsa, OK, USA: The American Association of Petroleum Geologists
    [61]
    Peakall J, Amos K J, Keevil G M, et al. 2007. Flow processes and sedimentation in submarine channel bends. Marine and Petroleum Geology, 24(6–9): 470–486
    [62]
    Peakall J, Sumner E J. 2015. Submarine channel flow processes and deposits: A process-product perspective. Geomorphology, 244: 95–120
    [63]
    Peakall J, Wells M G, Cossu R, et al. 2013. Global (latitudinal) variation in submarine channel sinuosity: REPLY. Geology, 41(5): e288
    [64]
    Pickering K T, Hiscott R N, Hein F J. 1989. Deep Marine Environments: Clastic Sedimentation and Tectonics. London: Unwin Hyman
    [65]
    Pickering K T, Hiscott R N, Kenyon N H, et al. 1995. Atlas of Deep Water Environments: Architectural Style in Turbidite Systems. Dordrecht: Springer
    [66]
    Pinna P. 1995. On the dual nature of the Mozambique Belt, Mozambique to Kenya. Journal of African Earth Sciences, 21(3): 477–480
    [67]
    Posamentier H W. 2003. Depositional elements associated with a basin floor channel-levee system: case study from the Gulf of Mexico. Marine and Petroleum Geology, 20(6–8): 677–690
    [68]
    Prather B E. 2003. Controls on reservoir distribution, architecture and stratigraphic trapping in slope settings. Marine and Petroleum Geology, 20(6–8): 529–545
    [69]
    Rabinowitz P D, Coffin M F, Falvey D. 1983. The separation of Madagascar and Africa. Science, 220(4592): 67–69
    [70]
    Raillard S. 1990. Les marges de L’Afrique de l’est et les zones de fracture associées: Chaine Davie et ride du Mozambique, Champagne MD-60/MACA MO-11 [dissertation]. Paris: Universite Pierre et Marie Curie
    [71]
    Reading H G, Richards M. 1994. Turbidite systems in deep-water basin margins classified by grain size and feeder system. AAPG Bulletin, 78(5): 792–822
    [72]
    Reeves C V, de Wit M J, Sahu B K. 2004. Tight reassembly of Gondwana exposes Phanerozoic shears in Africa as global tectonic players. Gondwana Research, 7(1): 7–19
    [73]
    Reimchen A P, Hubbard S M, Stright L, et al. 2016. Using sea-floor morphometrics to constrain stratigraphic models of sinuous submarine channel systems. Marine and Petroleum Geology, 77: 92–115
    [74]
    Roberts E M, Stevens N J, O’Connor P M, et al. 2012. Initiation of the western branch of the East African Rift coeval with the eastern branch. Nature Geoscience, 5: 289–294
    [75]
    Salazar M U, Baker D, Francis M, et al. 2013. Frontier exploration offshore the Zambezi Delta, Mozambique. First Break, 31(6): 135–144
    [76]
    Saller A, Werner K, Sugiaman F, et al. 2008. Characteristics of Pleistocene deep-water fan lobes and their application to an upper Miocene reservoir model, offshore East Kalimantan, Indonesia. AAPG Bulletin, 92(7): 919–949
    [77]
    Saller A H, Noah J T, Ruzuar A P, et al. 2004. Linked lowstand delta to basin-floor fan deposition, offshore Indonesia: An analog for deep-water reservoir systems. AAPG Bulletin, 88(1): 21–46
    [78]
    Salman G, Abdula I. 1995. Development of the Mozambique and Ruvuma sedimentary basins, offshore Mozambique. Sedimentary Geology, 96(1–2): 7–41
    [79]
    Sansom P. 2018. Hybrid turbidite–contourite systems of the Tanzanian margin. Petroleum Geoscience, 24: 258–276,
    [80]
    Sapri D H, Mahmud O A, Chen H W W. 2013. Sequence stratigraphic study of Areas 3&6, Rovuma Basin, Mozambique. In: International Petroleum Technology Conference. Beijing: European Association of Geoscientists & Engineers
    [81]
    Scrutton R A. 1978. Davie fracture zone and the movement of Madagascar. Earth and Planetary Science Letters, 39(1): 84–88
    [82]
    Shanmugam G. 1996. High-density turbidity currents: Are they sandy debris flows?. Journal of Sedimentary Research, 66(1): 2–10
    [83]
    Shanmugam G. 1997. The Bouma sequence and the turbidite mind set. Earth-Science Reviews, 42(4): 201–229
    [84]
    Shanmugam G. 2003. Deep-marine tidal bottom currents and their reworked sands in modern and ancient submarine canyons. Marine and Petroleum Geology, 20(5): 471–491
    [85]
    Shanmugam G. 2008. The constructive functions of tropical cyclones and tsunamis on deep-water sand deposition during sea level highstand: Implications for petroleum exploration. AAPG Bulletin, 92(4): 443–471
    [86]
    Shanmugam G. 2013. Modern internal waves and internal tides along oceanic pycnoclines: Challenges and implications for ancient deep-marine baroclinic sands. AAPG Bulletin, 97(5): 799–843
    [87]
    Shanmugam G. 2016. Submarine fans: A critical retrospective (1950–2015). Journal of Palaeogeography, 5(2): 110–184
    [88]
    Shanmugam G, Bloch R B, Mitchell S M, et al. 1995. Basin-floor fans in the North Sea: Sequence stratigraphic models vs. sedimentary facies. AAPG Bulletin, 79(4): 477–511
    [89]
    Shanmugam G, Moiola R J. 1982. Eustatic control of turbidites and winnowed turbidites. Geology, 10(5): 231–235
    [90]
    Shanmugam G, Moiola R J. 1985. Submarine fan models: Problems and solutions. In: Bouma A H, Normark W R, Barnes N E, eds. Submarine Fans and Related Turbidite Systems. New York: Springer-Verlag, 29–35
    [91]
    Shanmugam G, Moiola R J. 1995. Reinterpretation of depositional processes in a classic flysch sequence (Pennsylvanian Jackfork Group), Ouachita Mountains, Arkansas and Oklahoma. AAPG Bulletin, 79(5): 672–695
    [92]
    Shepard F P. 1981. Submarine canyons: Multiple causes and long-time persistence. AAPG Bulletin, 65(6): 1062–1077
    [93]
    Smelror M, Key R M, Smith R A, et al. 2008. Late Jurassic and cretaceous palynostratigraphy of the onshore Rovuma Basin, Northern Mozambique. Palynology, 32(1): 63–76
    [94]
    Stow D A V, Mayall M. 2000. Deep-water sedimentary systems: New models for the 21st century. Marine and Petroleum Geology, 17(2): 125–135
    [95]
    Sylvester Z, Pirmez C, Cantelli A. 2011. A model of submarine channel-levee evolution based on channel trajectories: Implications for stratigraphic architecture. Marine and Petroleum Geology, 28(3): 716–727
    [96]
    Sylvester Z, Pirmez C, Cantelli A, et al. 2013. Global (latitudinal) variation in submarine channel sinuosity: COMMENT. Geology, 41(5): e287
    [97]
    Thiéblemont A, Hernández-Molina F J, Miramontes E, et al. 2019. Contourite depositional systems along the Mozambique channel: The interplay between bottom currents and sedimentary processes. Deep Sea Research Part I: Oceanographic Research Papers, 147: 79–99,
    [98]
    Vail P R, Audemard F, Bowman S A, et al. 1991. The stratigraphic signatures of tectonics, eustacy and sedimentology—an overview. In: Einsele G, Ricken W, Seilacher A, eds. Cycles and Events in Stratigraphy. Berlin: Springer-Verlag, 617–659
    [99]
    Wang Xingxing, Wang Yingmin, He Min, et al. 2017. Genesis and evolution of the mass transport deposits in the middle segment of the Pearl River canyon, South China Sea: Insights from 3D seismic data. Marine and Petroleum Geology, 88: 555–574
    [100]
    Weimer P, Link M H. 1991. Seismic Facies and Sedimentary Processes of Submarine Fans and Turbidite Systems. New York: Springer
    [101]
    Weimer P, Slatt R M, Bouroullec R, et al. 2006. Introduction to the petroleum geology of deepwater setting. AAPG Studies in Geology, 57: 171–175
    [102]
    Wonham J P, Jayr S, Mougamba R, et al. 2000. 3D sedimentary evolution of a canyon fill (Lower Miocene-age) from the Mandorove Formation, offshore Gabon. Marine and Petroleum Geology, 17(2): 175–197
    [103]
    Wynn R B, Cronin B T, Peakall J. 2007. Sinuous deep-water channels: Genesis, geometry and architecture. Marine and Petroleum Geology, 24(6–9): 341–387
    [104]
    Wynn R B, Kenyon N H, Masson D G, et al. 2002. Characterization and recognition of deep-water channel-lobe transition zones. AAPG Bulletin, 86(8): 1441–1462
    [105]
    Zaragosi S, Auffret G A, Faugères J C, et al. 2000. Physiography and recent sediment distribution of the Celtic Deep-Sea Fan, Bay of Biscay. Marine Geology, 169(1–2): 207–237
    [106]
    Zhang Jiajia, Wu Shenghe, Fan Ting’en, et al. 2016a. Research on the architecture of submarine-fan lobes in the Niger Delta Basin, offshore West Africa. Journal of Palaeogeography, 5(3): 185–204
    [107]
    Zhang Lei, Li Zhenhai, Zhang Xuejuan, et al. 2015. Lithofacies classification and development rule of gravity flows deposits. Journal of China University of Petroleum (in Chinese), 39(1): 17–24
    [108]
    Zhang Wenbiao, Duan Taizhong, Liu Zhiqiang, et al. 2016b. Application of multi-point geostatistics in deep-water turbidity channel simulation: A case study of Plutonio oilfield in Angola. Petroleum Exploration and Development (in Chinese), 43(3): 403–410
    [109]
    Zhou Zongying, Tao Ye, Li Shujun, et al. 2013. Hydrocarbon potential in the key basins in the East Coast of Africa. Petroleum Exploration and Development, 40(5): 582–591
    [110]
    Zitellini N, Chierici F, Sartori R, et al. 1999. The tectonic source of the 1755 Lisbon earthquake and tsunami. Annals of Geophysics, 42(1): 49–55
  • 加载中

Catalog

    通讯作者: 陈斌, bchen63@163.com
    • 1. 

      沈阳化工大学材料科学与工程学院 沈阳 110142

    1. 本站搜索
    2. 百度学术搜索
    3. 万方数据库搜索
    4. CNKI搜索

    Figures(11)

    Article Metrics

    Article views (2219) PDF downloads(219) Cited by()
    Proportional views
    Related

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return