Benthic biology influences sedimentation in submarine channel bends: Coupling of biology, sedimentation and flow

IF 1.9 3区 地球科学 Q1 GEOLOGY Depositional Record Pub Date : 2024-01-29 DOI:10.1002/dep2.265
M. Azpiroz-Zabala, E. J. Sumner, M. J. B. Cartigny, J. Peakall, M. A. Clare, S. E. Darby, D. R. Parsons, R. M. Dorrell, E. Özsoy, D. Tezcan, R. B. Wynn, J. Johnson
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Abstract

Submarine channels are key features for the transport of flow and nutrients into deep water. Previous studies of their morphology and channel evolution have treated these systems as abiotic, and therefore assume that physical processes are solely responsible for morphological development. Here, a unique dataset is utilised that includes spatial measurements around a channel bend that hosts active sediment gravity flows. The data include flow velocity and density, alongside bed grain size and channel-floor benthic macrofauna. Analysis of these parameters demonstrate that while physical processes control the broadest scale variations in sedimentation around and across the channel, benthic biology plays a critical role in stabilising sediment and trapping fines. This leads to much broader mixed grain sizes than would be expected from purely abiotic sedimentation, and the maintenance of sediment beds in positions where all the sediment should be actively migrating. Given that previous work has also shown that submarine channels can be biological hotspots, then the present study suggests that benthic biology probably plays a key role in channel morphology and evolution, and that these need to be considered both in the modern and when considering examples preserved in the rock record.

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底栖生物影响海底河道弯曲处的沉积作用:生物、沉积和水流的耦合
海底通道是向深水输送水流和营养物质的关键特征。以往对其形态和河道演变的研究都将这些系统视为非生物系统,因此认为形态发展完全是物理过程造成的。本文利用了一个独特的数据集,其中包括对沉积物重力流活跃的河道弯曲处进行的空间测量。这些数据包括流速和密度,以及河床粒度和河道底部大型底栖动物。对这些参数的分析表明,虽然物理过程控制着河道周围和两岸最广泛的沉积变化,但底栖生物在稳定沉积物和截留细粒方面起着至关重要的作用。这就导致了比纯非生物沉积作用所预期的要宽得多的混合粒度,并使沉积床保持在所有沉积物都应积极迁移的位置。鉴于之前的研究也表明,海底河道可能是生物热点,那么本研究就表明,底栖生物可能在河道形态和演化过程中起着关键作用,在现代和考虑岩石记录中保存的实例时,都需要考虑这些因素。
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来源期刊
CiteScore
4.10
自引率
16.70%
发文量
42
审稿时长
16 weeks
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Issue Information Issue Information The early–middle Cambrian siliciclastic tide-dominated succession in eastern Korea Preservation of groove mark striae formed by armoured mud clasts: The role of armour sediment size and bed yield stress Micritisation products in the inner ramp settings of the Abu Dhabi Lagoon
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