Time-varying drainage basin development and erosion on volcanic edifices

IF 2.8 2区地球科学 Q2 GEOGRAPHY, PHYSICAL

Earth Surface Dynamics Pub Date : 2024-05-08 DOI:10.5194/esurf-12-709-2024

Daniel O'Hara, Liran Goren, Roos M. J. van Wees, Benjamin Campforts, Pablo Grosse, Pierre Lahitte, Gabor Kereszturi, Matthieu Kervyn

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Abstract

Abstract. The erosional state of a landscape is often assessed through a series of metrics that quantify the morphology of drainage basins and divides. Such metrics have been well explored in tectonically active environments to evaluate the role of different processes in sculpting topography, yet relatively few works have applied these analyses to radial landforms such as volcanoes. We quantify drainage basin geometries on volcanic edifices of varying ages using common metrics (e.g., Hack's law, drainage density, and number of basins that reach the edifice summit, as well as basin hypsometry integral, length, width, relief, and average topographic slope). Relating these measurements to the log-mean age of activity for each edifice, we find that drainage density, basin hypsometry, basin length, and basin width quantify the degree of erosional maturity for these landforms. We also explore edifice drainage basin growth and competition by conducting a divide mobility analysis on the volcanoes, finding that young volcanoes are characterized by nearly uniform fluvial basins within unstable configurations that are more prone to divide migration. As basins on young volcanoes erode, they become less uniform but adapt to a more stable configuration with less divide migration. Finally, we analyze basin spatial geometries and outlet spacing on edifices, discovering an evolution in radial basin configurations that differ from typical linear mountain ranges. From these, we present a novel conceptual model for edifice degradation that allows new interpretations of composite volcano histories and provides predictive quantities for edifice morphologic evolution.

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随时间变化的排水盆地发育和火山造物上的侵蚀作用

摘要地貌的侵蚀状态通常是通过一系列量化排水盆地和分水岭形态的指标来评估的。这些指标在构造活跃的环境中得到了很好的应用，以评估不同过程在雕刻地形中的作用，但将这些分析应用于火山等径向地貌的工作相对较少。我们使用通用指标（如哈克定律、排水密度、到达火山顶的盆地数量，以及盆地吸水率积分、长度、宽度、地形起伏和平均地形坡度）量化了不同年代火山建筑物上的排水盆地几何形状。将这些测量值与每个建筑物的对数平均活动年龄联系起来，我们发现，排水密度、盆地湿度、盆地长度和盆地宽度可以量化这些地貌的侵蚀成熟程度。我们还通过对火山进行分水岭移动性分析来探讨火山口排水盆地的增长和竞争，发现年轻火山的特点是在不稳定的构造中形成几乎均匀的河流盆地，更容易发生分水岭移动。随着年轻火山上盆地的侵蚀，它们变得不那么均匀，但适应了更稳定的构造，减少了分水岭的迁移。最后，我们分析了造山运动上的盆地空间几何形状和出口间距，发现了不同于典型线性山脉的径向盆地构造的演变。由此，我们提出了一个新颖的火山口退化概念模型，该模型可以对复合火山历史做出新的解释，并提供火山口形态演变的预测量。

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

Earth Surface Dynamics GEOGRAPHY, PHYSICALGEOSCIENCES, MULTIDISCI-GEOSCIENCES, MULTIDISCIPLINARY

CiteScore

5.40

自引率

5.90%

发文量

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.