The origin of planar lamination in fine‐grained sediment deposited by subaqueous sediment gravity flows

IF 1.9 3区 地球科学 Q1 GEOLOGY
Omar N. Al‐Mufti, R. William C. Arnott
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Abstract

Abstract Planar lamination is a ubiquitous component of modern and ancient fine‐grained sediments deposited by subaqueous sediment gravity flows. These sediments commonly exhibit alternating sub‐millimetre‐thick, sharply bounded silt‐rich and clay‐rich layers that change little in thickness or sediment texture over lateral distances that range up to at least several tens of metres. Silt‐rich layers are moderately to well‐sorted and a few tens to hundreds of microns to a single silt‐grain thick. In contrast, clay‐rich layers are more poorly sorted, and a few tens to hundreds of microns thick. The thickness and regular alternation of these texturally differentiated interlayers, in addition to the absence of features suggesting transport bypass or deposition by migrating rugged bed forms, suggest alternating physical processes and related modes of deposition in the near‐bed region immediately above the bed. Previous interpretations have focussed on clay flocculation, which is difficult to reconcile with the high fluid shear conditions in the near‐bed region. Here it is suggested that in the millimetre to sub‐millimetre‐thick viscous sublayer at the base of a hydraulically smooth turbulent flow, a combination of high fluid shear and sediment concentration initially leads to shear thinning and enhanced mobility in the lower part of the flow, and for silt to continue settling to the bed forming a well‐sorted silt lamina. As silt settles and clay‐size sediment increases in concentration, hydrodynamic lubrication forces strengthen and reduce mobility of the near‐bed part of the flow. This condition is then perturbed by a bedward‐directed outer flow disturbance that dramatically increases frictional stresses and effective fluid viscosity and ultimately shear jamming that causes gelling and deposition of a poorly sorted clay‐rich layer. This process is then repeated multiple times to build up a deposit composed of alternating silt‐rich and clay‐rich laminae overlain by structureless mud deposited directly from suspension.
水下重力流沉积的细粒沉积物中平面层叠的成因
平面层积是现代和古代水下重力流沉积的细粒沉积物中普遍存在的组成部分。这些沉积物通常表现为亚毫米厚的交替分布,富淤泥层和富粘土层界限分明,在至少几十米的横向距离上,厚度或沉积物质地变化不大。富粉砂层分选适度,厚度在几十到几百微米之间,为一粒粉砂。相比之下,富含粘土的层分选得更差,厚度只有几十到几百微米。这些结构上分化的夹层的厚度和有规律的交替,加上没有表明运输绕道或通过迁移的崎岖床型沉积的特征,表明在床上方的近床区域有交替的物理过程和相关的沉积模式。以前的解释主要集中在粘土絮凝上,这很难与近床区高流体剪切条件相协调。这表明,在水力平滑湍流底部的毫米至亚毫米厚粘性亚层中,高流体剪切和沉积物浓度的结合最初导致水流下部剪切变薄和流动性增强,并且泥沙继续沉降到河床形成分选良好的粉砂层。随着粉砂沉降和黏土泥沙浓度的增加,流体动力润滑力增强并降低了近河床部分的流动性。然后,这种情况会受到向前方向的外部流动扰动的干扰,这种扰动会极大地增加摩擦应力和有效流体粘度,最终导致剪切干扰,导致富粘土层的凝胶化和沉积。这一过程重复多次,形成了一个沉积物,由富粉砂和富粘土层交替组成,上覆由悬浮直接沉积的无结构泥浆。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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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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