Steady-state forms of channel profiles shaped by debris flow and fluvial processes

IF 2.8 2区 地球科学 Q2 GEOGRAPHY, PHYSICAL Earth Surface Dynamics Pub Date : 2023-11-09 DOI:10.5194/esurf-11-1117-2023
Luke A. McGuire, Scott W. McCoy, Odin Marc, William Struble, Katherine R. Barnhart
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引用次数: 4

Abstract

Abstract. Debris flows regularly traverse bedrock channels that dissect steep landscapes, but our understanding of bedrock erosion by debris flows and their impact on steepland morphology is still rudimentary. Quantitative models of steep bedrock channel networks are based on geomorphic transport laws designed to represent erosion by water-dominated flows. To quantify the impact of debris flow erosion on steep channel network form, it is first necessary to develop methods to estimate spatial variations in bulk debris flow properties (e.g., flow depth, velocity) throughout the channel network that can be integrated into landscape evolution models. Here, we propose and evaluate two methods to estimate spatial variations in bulk debris flow properties along the length of a channel profile. We incorporate both methods into a model designed to simulate the evolution of longitudinal channel profiles that evolve in response to debris flow and fluvial processes. To explore this model framework, we propose a general family of debris flow erosion laws where erosion rate is a function of debris flow depth and channel slope. Model results indicate that erosion by debris flows can explain the occurrence of a scaling break in the slope–area curve at low-drainage areas and that upper-network channel morphology may be useful for inferring catchment-averaged erosion rates in quasi-steady landscapes. Validating specific forms of a debris flow incision law, however, would require more detailed model–data comparisons in specific landscapes where input parameters and channel morphometry can be better constrained. Results improve our ability to interpret topographic signals within steep channel networks and identify observational targets critical for constraining a debris flow incision law.
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泥石流和河流作用形成的河道剖面的稳态形式
摘要泥石流有规律地穿过基岩通道,剖析陡峭的地貌,但我们对泥石流对基岩的侵蚀及其对陡地形态的影响的了解仍处于初级阶段。陡峭基岩河道网络的定量模型是基于旨在表示水主导流侵蚀的地貌运输规律。为了量化泥石流侵蚀对陡坡河道网络形态的影响,首先需要开发估算整个河道网络中大块泥石流特性(如流深、流速)的空间变化的方法,并将其纳入景观演化模型。在这里,我们提出并评估了两种方法来估计沿通道剖面长度的大块泥石流特性的空间变化。我们将这两种方法合并到一个模型中,该模型旨在模拟响应泥石流和河流过程而演变的纵向河道剖面的演变。为了探索这一模型框架,我们提出了一系列泥石流侵蚀规律,其中侵蚀速率是泥石流深度和河道坡度的函数。模型结果表明,泥石流侵蚀可以解释低排水区坡面面积曲线上的尺度断裂现象,而在准稳定景观中,上层网络河道形态可能有助于推断流域平均侵蚀速率。然而,要验证泥石流切割规律的特定形式,需要在特定景观中进行更详细的模型数据比较,在这些景观中,输入参数和通道形态可以得到更好的约束。研究结果提高了我们在陡峭河道网络中解释地形信号的能力,并确定了对限制泥石流切口规律至关重要的观测目标。
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来源期刊
Earth Surface Dynamics
Earth Surface Dynamics GEOGRAPHY, PHYSICALGEOSCIENCES, MULTIDISCI-GEOSCIENCES, MULTIDISCIPLINARY
CiteScore
5.40
自引率
5.90%
发文量
56
审稿时长
20 weeks
期刊介绍: Earth Surface Dynamics (ESurf) is an international scientific journal dedicated to the publication and discussion of high-quality research on the physical, chemical, and biological processes shaping Earth''s surface and their interactions on all scales.
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