Kinematics of Submarine Channels in Response to Bank Failures

IF 2.8 2区地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY

Basin Research Pub Date : 2025-01-05 DOI:10.1111/bre.70013

Massine Bouchakour, Xiaoming Zhao, Davide Gamboa, Crina Miclăuș, Adam D. McArthur, Shuchun Cao, Li Yang

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Abstract

Submarine channel systems play a crucial role in the delivery of clastic sediments, organic carbon and pollutants across continental margins, and help define the stratigraphic architecture of deep-sea fans and their associated reservoirs. These systems generate complex lateral migration dynamics and resulting sedimentary architectures, which are often overprinted by a variety of local factors. For example, the debris from channel-wall collapses may block or restrict channel flow, thereby influencing the kinematics of stacking elements and the sinuosity of channels. Here, we investigate the responses of submarine channels to bank failures, using quantitative approaches from the Niger Delta Fulani Channel. Using 3D seismic data, we introduce a novel approach to interpreting the structural framework of channels, referred to as the structural gradient, which quantifies the relationship between sedimentary architecture and underlying structures. Bank failure mass transport deposits (MTDs) were characterised by downstream changes of cross-sectional area and the proportion of collapsed material deposited. These parameters were used to correlate the responses of channel width, thickness, aspect ratio and lateral migration, as well as the channel planform parameters (i.e., sinuosity and meander amplitude) to the occurrence of flanking MTDs. Our results demonstrate that bank failures significantly influence channel sinuosity by causing localised swings in channel pathways, impacting the overall channel morphology and stratigraphic evolution. The relationships between all channel parameters depend on the ratios of bank failures, and locations of channel-wall failures. The combined effects of bank failure confinement and structural growth control channel element stacking patterns, resulting in vertical stacks related to compensational relationships between adjacent channel complexes. Significant confinements by MTD emplacement led to rapid channel infill linked to progressive flow relaxation promoting progressive lateral mobility. Channel migration is limited by MTD accumulation to a maximum width of 1700 m. Channel lateral shift reacts to channel-wall collapses, resulting in limited lateral mobility at regional scale. We show for the first time how the kinematics of submarine channels evolved in terms of the constraints of channel-wall collapses and active structural deformation.

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海底通道对河岸破坏的运动学响应

海底通道系统在碎屑沉积物、有机碳和污染物跨越大陆边缘的输送中起着至关重要的作用，并有助于确定深海扇及其相关储层的地层结构。这些系统产生了复杂的横向运移动力学和沉积结构，这些结构通常是由各种局部因素叠加而成的。例如，通道壁崩塌产生的碎屑可能阻塞或限制通道流动，从而影响堆积单元的运动学和通道的弯曲度。在这里，我们使用尼日尔三角洲富拉尼海峡的定量方法研究海底通道对银行倒闭的反应。利用三维地震数据，我们引入了一种新的方法来解释河道的构造框架，即构造梯度，它量化了沉积构造与下伏构造之间的关系。崩落体输运沉积物（MTDs）的特征是横截面积的下游变化和崩塌物质的沉积比例。这些参数被用来关联河道宽度、厚度、纵横比、横向迁移以及河道平台参数（即弯曲度和曲流振幅）对侧翼MTDs发生的响应。我们的研究结果表明，河岸崩溃通过引起河道路径的局部波动，从而影响河道的整体形态和地层演化，从而显著影响河道的弯曲度。所有通道参数之间的关系取决于河岸失效的比例和通道壁失效的位置。河岸破坏约束和结构生长的共同作用控制了河道单元的叠加模式，导致了与相邻河道复合体之间的补偿关系相关的垂直叠加。MTD就位造成的严重限制导致通道快速填充，与进行性流动松弛有关，促进了进行性横向流动。受MTD积累的限制，通道迁移的最大宽度为1700米。在区域尺度上，河道横向移动与河道壁崩塌反应，导致了有限的横向移动。我们首次展示了海底通道的运动学是如何在通道壁崩塌和主动构造变形的约束下演变的。

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来源期刊

Basin Research 地学-地球科学综合

CiteScore

7.00

自引率

9.40%

发文量

审稿时长

>12 weeks

期刊介绍： Basin Research is an international journal which aims to publish original, high impact research papers on sedimentary basin systems. We view integrated, interdisciplinary research as being essential for the advancement of the subject area; therefore, we do not seek manuscripts focused purely on sedimentology, structural geology, or geophysics that have a natural home in specialist journals. Rather, we seek manuscripts that treat sedimentary basins as multi-component systems that require a multi-faceted approach to advance our understanding of their development. During deposition and subsidence we are concerned with large-scale geodynamic processes, heat flow, fluid flow, strain distribution, seismic and sequence stratigraphy, modelling, burial and inversion histories. In addition, we view the development of the source area, in terms of drainage networks, climate, erosion, denudation and sediment routing systems as vital to sedimentary basin systems. The underpinning requirement is that a contribution should be of interest to earth scientists of more than one discipline.