印度河扇水道堤岸外侧更新世沉积物波发育特征与形成过程分析<sup>*</sup>

doi:10.7605/gdlxb.2022.02.039

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Abstract Architecture of the turbidity current sediment waves exhibit intricate morphologies and patterns on Indus fan channel levee back. The sediment waves are present on the channel levee of Pleistocene age in the study area,and their formation process is poorly understood. Through high-resolution seismic data and seismic interpretation technology, the difference between sediment wave and sediment deformation characteristics is expounded,and the distinguishing mark of the two sediments are summarized;the distribution law of sediment wave on the slope of the channel levee backslope and the regional slope is summarized;on this basis,the formation mechanism of the sediment wave is discussed,and the controlling factors and the formation process of sediment wave are analyzed. At last,the formation mode of sediment wave in Indus fan are established. The research result shows that: (1)The average wave length of the sediment wave in the study area is 486.84 m,and the maximum wavelength is 1473 m;the sediment wave height is between 10 m and 66 m,with an average of 30 m. (2)The morphology of sediment wave is symmetric and asymmetric,and its migration pattern include upslope migration type,aggregative type and downslope migration type. the sediment wave is mainly developed on the channel levee back,a small amount of sediment waves are also developed on the regional slope. The trends of these two types of sediment waves are very different. The sediment waves on the channel levee backslope are mainly distributed on the levee backslope in concave bank of the channel. The farther away from the channel,the smaller the dimension of sediment waves(wave length and wave height),and its trend is close to the NE-SW direction,parallel or oblique to the channel trend. The trend of sediment waves on the regional slope is mostly NW-SE,which is parallel to the trend of the regional slope,and its dimension is larger the farther away from the source area. (3)The sediment waves on the channel levee backslope is formed by the channel-type turbidity current overflowing the levee of the concave bank of the channel under the action of centrifugal force and depositing on the levee backslope outside the bank. The angle of the levee backslope have less effects on the dimension of the sediment waves. The intensity of turbidity current and the amount of sand conveying have a great influence on its dimension. The sediment waves developed on the regional slopes are formed by the non-channelized turbidity currents and are deposited along the slope,and it was considered that the undulating landforms caused by slump deformation,and the existence of early sediment waves all affect the development of later sediment waves.

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	Articles by authors
	Ehsan ul Haq
	Ji You-Liang
	Zhang Sheng-Jiu
	Liu Yan-Xin
	Khurram Shahzad
	Saad Ahmed Mashwani
	Liu Xiao-Yu
	Jiang Yan

Key words： sediment waves channel levee backslope Pleistocene turbidity currents

Received: 23 January 2022

ZTFLH:

P512.2

Fund:the National Natural Science Foundation of China(Nos. 42072115,41672098)

Corresponding Authors: Ji You-Liang,born in 1962,Ph.D.,is a professor and doctoral supervisor in China University of Petroleum(Beijing). His research interests are reservoir geology and sequence stratigraphy. E-mail: jiyouliang@cup.edu.cn。

About author: Ehsan ul Haq,born in 1987,Pakistani,is a Ph.D. candidate of China University of Petroleum(Beijing). E-mail: ehsaanarif@gmail.com。

Cite this article:

Ehsan ul Haq,Ji You-Liang,Zhang Sheng-Jiu et al. Analysis on characteristics and formation process of sediment waves on the Pleistocene channel levee backslope of Indus fan[J]. JOPC, 2022, 24(2): 389-404.

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http://journal09.magtechjournal.com/gdlxb/EN/10.7605/gdlxb.2022.02.039 OR http://journal09.magtechjournal.com/gdlxb/EN/Y2022/V24/I2/389

[1] 刘杰,孙美静,高红芳,李学杰. 2019. 台湾东部海域沉积物波特征及其成因探讨. 沉积学报,37(1):155-162.
[Liu J,Sun M J,Gao H F,Li X J. 2019. Sediment waves characteristics and origin of Taitung Canyon in eastern waters of Taiwan Island. Acta Sedimentlogica Sinica, 37(1): 155-162]
[2] 张兴阳. 2000. 深水牵引流形成的床形单元组合. 古地理学报, 2(2): 28-37.
[Zhang X Y. 2000. Bedform units assemblages formed by deep-water tractive current origin. Journal of Palaeogeography(Chinese Edition), 2(2): 28-37]
[3] 张兴阳,何幼斌,罗顺社,别必文. 2002. 内波单独作用形成的深水沉积物波. 古地理学报, 4(1): 83-89.
[Zhang X Y,He Y B,Luo S S,Bie B W. 2002. Deep-water sediment waves formed by the action of internal waves. Journal of Palaeogeography(Chinese Edition), 4(1): 83-89]
[4] Carter L,Carter R M,Nelson C S,Fulthorpe C S,Neil H L. 1990. Evolution of Pliocene to recent abyssal sediment waves on Bounty Channel levees,New Zealand. Marine Geology, 95(2): 97-109. doi.org/10.1016/0025-3227(90)90043-J.
[5] Christensen D F,Brinkkemper J,Ruessink G,Aagaard T. 2019. Field observations of intra-wave sediment suspension and transport in the intertidal and shallow subtidal zones. Marine Geology 413: 10-26.
[6] Clift P D,Shimizu N,Layne G D,Blusztajn J S,Gaedicke C,Schluter H U,Amjad S. 2001. Development of the Indus Fan and its significance for the erosional history of the Western Himalaya and Karakoram. Geological Society of America Bulletin, 113(8): 1039-1051.
[7] Clift P D,Gaedicke C,Edwards R,Lee J Ⅰ,Hildebrand P,Amjad S,Schlüter H U. 2002. The stratigraphic evolution of the Indus Fan and the history of sedimentation in the Arabian Sea. Marine Geophysical Researches, 23(3): 223-245. doi.org/10.1023/A:1023627123093
[8] Damuth J E. 1980. Use of high frequency(3.5-12kHz)echograms in the study of near-bottom sedimentation processes in the deep-sea: a review. Marine Geology, 38(1-3): 51-75. doi.org/10.1016/0025-3227(80)90051-1.
[9] Dmitrii Borisov,Dmitry Frey,Oleg Levchenko. 2020. Sediment waves on the Santa Catarina Plateau(western South Atlantic). Journal of South American Earth Sciences, 102: 1-9.
[10] Edwards R A,Minshull T A,Flueh E R, Kopp C. 2008. Dalrymple Trough: an active oblique-slip ocean-continent boundary in the northwest Indian Ocean. Earth and Planetary Science Letters, 272: 437-445.
[11] Ercilla G,Alonso B,Wynn R B,Baraza J. 2002. Turbidity current sediment waves on irregular slopes: Observations from the Orinoco sediment-wave field. Marine Geology, 192(1-3): 171-187. doi.org/10.1016/S0025-3227(02)00554-6
[12] Faugères J C,Stow D A. 1993. Bottom-current-controlled sedimentation: a synthesis of the contourite problem. Sedimentary Geology, 82(1-4): 287-297. doi.org/10.1016/0037-0738(93)90127-Q.
[13] Flood R D. 1994. Abyssal bedforms as indicators of changing bottom current flow: examples from the US East Coast continental rise. Paleoceanography, 9(6): 1049-1060. doi.org/10.1029/94PA01801.
[14] Gaedicke C,Schlüter H U,Roeser H A,Prexl A,Schreckenberger B,Meyer H,Amjad S. 2002. Origin of the northern Indus Fan and Murray Ridge,Northern Arabian Sea: Interpretation from seismic and magnetic imaging. Tectonophysics, 355(1-4): 127-143. doi.org/10.1016/S0040-1951(02)00137-3.
[15] Gong C,Wang Y,Peng X,Li W,Qiu Y,Xu S. 2012. Sediment waves on the South China Sea Slope off southwestern Taiwan: implications for the intrusion of the Northern Pacific Deep Water into the South China Sea. Marine and Petroleum Geology, 32(1): 95-109. doi.org/10.1016/j.marpetgeo.2011.12.005.
[16] Gong C,Wang Y,Xu S,Pickering K,Peng X,Li W,Qiu Y. 2015. The northeastern South China Sea margin created by the combined action of down-slope and along-slope processes: processes,products and implications for exploration and paleoceanography. Marine and Petroleum Geology, 64(1): 233-249.
[17] Howe J A. 1996. Turbidite and contourite sediment waves in the northern Rockall Trough,North Atlantic Ocean. Sedimentology, 43(2): 219-234. doi.org/10.1046/j.1365-3091.1996.d01-1.x.
[18] Hsu H H,Liu C S,Chen T T,Hung H T. 2020. Stratigraphic framework and sediment wave fields associated with canyon-levee systems in the Huatung Basin offshore Taiwan Orogen. Marine Geology, 433: 1-16.
[19] Huang S Y,Yen J Y,Wu B L,Shih N W. 2020. Field observations of sediment transport across the rocky coast of east Taiwan: impacts of extreme waves on the coastal morphology by Typhoon Soudelor.Marine Geology, 421: 1-18.
[20] Kolla V,Ravindranathan R,Gupta P,Mathur M,Sinha N. 2021. Distribution,characteristics,and processes of formation of sediment waves along the Indian north-eastern continental margin. Marine Geology, 441: 1-14.
[21] Lee H J,Syvitski J P,Parker G,Orange D,Locat J,Hutton E W,Imran J. 2002. Distinguishing sediment waves from slope failure deposits: field examples,including the‘Humboldt slide',and modelling results. Marine Geology, 192(1-3): 79-104. doi.org/10.1016/S0025-3227(02)00550-9.
[22] Lee S H,Chough S K. 2001. High-resolution(2-7kHz)acoustic and geometric characters of submarine creep deposits in the South Korea Plateau,East Sea. Sedimentology, 48(3): 629-644. doi.org/10.1046/j.1365-3091.2001.00383.x.
[23] 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.
[24] Liu Z X,Xia D X,Berne S,Wang K Y,Marsset Tang Y X,Bourillet J F. 1998. Tidal deposition systems of China's continental shelf,with special reference to the eastern Bohai Sea. Marine Geology, 145(3-4): 225-253. doi.org/10.1016/S0025-3227(97)00116-3.
[25] Marta Ribo,Pere Puig,Maria Gomez Ballesteros. 2016. Morphobathymetric analysis of the large fine-grained sediment waves over the Gulf of Valencia continental slope(NW Mediterranean). Geomorphology, 253: 22-37.
[26] McCave I N. 2017. Formation of sediment waves by turbidity currents and geostrophic flows: a discussion. Marine Geology, 390(4): 89-93.
[27] Mishra A,Srivastava D C,Shah J. 2013. Late Miocene-Early Pliocene reactivation of the Main Boundary Thrust: evidence from the seismites in southeastern Kumaun Himalaya,India.Sedimentary Geology,289:148-158.
[28] 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.Marine Geology, 147: 25-41.
[29] Naini B R,Kolla V. 1982. Acoustic character and thickness of sediments of the Indus Fan and the continental margin of western India. Marine Geology, 47(3-4):181-195.
[30] Nakajima T,Satoh M. 2001. The formation of large mudwaves by turbidity currents on the levees of the Toyama deep-sea channel,Japan Sea. Sedimentology, 48(2): 435-463.
[31] Normark W R,Hess G R,Stow D A V,Bowen A J. 1980. Sediment waves on the Monterey Fan levee: a preliminary physical interpretation. Marine Geology, 37(1-2): 1-18.
[32] Normark W R,Piper D J,Posamentier H,Pirmez C,Migeon S. 2002. Variability in form and growth of sediment waves on turbidite channel levees. Marine Geology, 192(1-3): 23-58.
[33] Ologe O,Bankole A S,Oke A S. 2014. Hydrocarbon Prospecting over‘OK'field,Niger Delta using petrophysical and seismic attributes analysis. Nigerian Journal of Technology, 33(3): 401-408. doi.org/10.4314/njt.v33i3.19.
[34] Posamentier H W,Kolla V. 2003. Seismic geomorphology and stratigraphy of depositional elements in deep-water settings. Journal of Sedimentary Research, 73(3): 367-388. doi.org/10.1306/111302730367.
[35] Rea D K. 1992. Delivery of Himalayan sediment to the northern Indian Ocean and its relation to global climate,sea level,uplift,and seawater strontium. Synthesis of Results from Scientific Drilling in the Indian Ocean, 70(5): 387-402.
[36] Wynn R B,Stow D A. 2002. Classification and characterization of deep-water sediment waves. Marine Geology, 192(1-3): 7-22.
[37] Wynn R B,Weaver P P,Ercilla G,Stow D A,Masson D G. 2000. Sedimentary processes in the Selvage sediment-wave field,NE Atlantic: new insights into the formation of sediment waves by turbidity currents. Sedimentology, 47(6): 1181-1197.
[38] Zhou W,Chiarella D,Zhuo H T,Wang Y M,Tang W,Zou M J,Xu Q. 2021. Genesis and evolution of large-scale sediment waves in submarine canyons since the Penultimate Glacial Maximum(ca. 140 ka),northern South China Sea margin. Marine and Petroleum Geology, 134: 1-18.