Evaluating Rare Earth Elements as Tracers of Fluvial Processes: Fine Sediment Transport and Deposition in a Small Stream

IF 1.4 4区农林科学 Q3 AGRICULTURAL ENGINEERING

Transactions of the ASABE Pub Date : 2021-01-01 DOI:10.13031/TRANS.14358

H. Govenor, W. Hession, T. Keys, C. N. Jones, R. Stewart, L. Krometis

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Abstract

HighlightsNatural sediments labeled with rare earth elements can effectively be used as tracers for quantifying fine sediment transport and deposition.Two artificial floods in a small stream (100 ha watershed, 1.5 year return flow of 515 L s-1) transported fine sediment 0 m to >850 m at a maximum flow rate of 55 L s-1.Sediment deposition per unit area was greater in the channel than in the near-channel floodplain.Use of two distinct tracers demonstrated resuspension extent during sequential high-flow events.Presence of large wood in the channel was associated with reduced streamflow rate, decreased suspended sediment transport velocity, increased channel sediment deposition, and reduced near-floodplain sediment deposition.Abstract. Effective sediment management requires an understanding of the lag time between best management practice implementation and observable changes in the target water body. To improve our understanding of sediment lag times, we tested a method to label locally sourced sediments with rare earth elements to quantify fine sediment flow-through and storage in fluvial systems. We injected sediments labeled with lanthanum and ytterbium into a small stream during two artificial flood events. During the floods, we collected and quantified suspended sediments and sediment deposition in the stream channel and floodplain at four cross-sections within our study reach. Two down-gradient (90 m and 850 m) time-integrated suspended sediment samplers evaluated total travel distance. Sediment tracer observations of particle transport distances ranged from 0 m to at least 850 m at a maximum flow rate of 55 L s-1 (stream 1.5 year flow was 515 L s-1). Sediment deposition per unit area was greater in the channel than in the floodplain. The majority of sediment tracer mass injected into the stream entered storage within the first 69 m of the reach. Some particles that deposited following the first flood were resuspended and either transported downstream or redeposited within the study reach. Our results support the further use of rare earth elements as sediment tracers to inform water quality and sediment transport models, and to provide estimates of lag times between management actions and downstream improvements. Keywords: Fine sediment, Flood, Fluvial geomorphology, Lag time, Large wood, Rare earth elements, Sediment deposition, Sediment transport, Tracer.

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评价稀土元素作为河流过程的示踪剂:细泥沙在小溪中的运移和沉积

用稀土元素标记的天然沉积物可以有效地作为示踪剂用于定量细沉积物的迁移和沉积。小流域(100 ha流域，1.5年回潮515 L s-1)两次人工洪水以55 L s-1的最大流量输沙0 ~ 850 m。河道内的单位面积泥沙淤积大于近河道洪泛平原。使用两种不同的示踪剂显示了连续高流量事件中的再悬浮程度。河道中大型木材的存在与河道流速降低、悬沙输运速度降低、河道泥沙淤积增加和近洪泛平原泥沙淤积减少有关。有效的沉积物管理需要了解最佳管理实践实施与目标水体可观察到的变化之间的滞后时间。为了提高我们对沉积物滞后时间的理解，我们测试了一种方法，用稀土元素标记当地来源的沉积物，以量化河流系统中细沉积物的流经和储存。我们在两次人工洪水期间向一条小溪注入了镧和镱标记的沉积物。在洪水期间，我们在研究范围内的四个断面上收集和量化了河道和洪泛区的悬浮沉积物和沉积物沉积。两个向下梯度(90米和850米)的时间积分悬浮沉积物采样器评估了总移动距离。在最大流量为55 L s-1时(河流1.5年流量为515 L s-1)，沉积物示踪观测颗粒输运距离在0 ~ 850 m之间。河道的单位面积泥沙淤积量大于河漫滩。注入河流的大部分沉积物示踪物质在河段的前69米内进入储存。在第一次洪水之后沉积的一些颗粒被重新悬浮起来，或者向下游输送，或者在研究范围内重新沉积。我们的研究结果支持进一步使用稀土元素作为沉积物示踪剂，为水质和沉积物运输模型提供信息，并提供管理行动与下游改善之间的滞后时间估计。关键词:细沙，洪水，河流地貌，滞后时间，大木材，稀土元素，泥沙沉积，泥沙运输，示踪剂

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来源期刊

Transactions of the ASABE AGRICULTURAL ENGINEERING-

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

6 months

期刊介绍： This peer-reviewed journal publishes research that advances the engineering of agricultural, food, and biological systems. Submissions must include original data, analysis or design, or synthesis of existing information; research information for the improvement of education, design, construction, or manufacturing practice; or significant and convincing evidence that confirms and strengthens the findings of others or that revises ideas or challenges accepted theory.