Remotely sensed land-cover change and floodplain disturbance following upstream-migrating river avulsions in tropical rainforests

IF 1.7 4区环境科学与生态学 Q4 ENVIRONMENTAL SCIENCES

River Research and Applications Pub Date : 2024-02-18 DOI:10.1002/rra.4256

Riley T. Henson, Douglas A. Edmonds, Eli D. Lazarus

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引用次数: 0

Abstract

The displacement of a river to a new position within its adjacent floodplain is called avulsion, and here we examine how a newly recognized style, called retrogradational avulsion, affects the surrounding floodplain in tropical rainforests using remote sensing. Retrogradational avulsions begin with a channel blockage that causes self-propagating upstream dechannelization and flooding. While this flooding results in vegetation die-off and floodplain sedimentation, few quantitative measurements of disturbance by retrogradational avulsions exist. Here, we first focus on land-cover change following a single retrogradational avulsion in Papua New Guinea from 2012 to 2021. During the avulsion, the river dechannelized 892 m upstream, and the parent channel width doubled. Using maximum likelihood image classification, we observed healthy vegetation fluctuated around 4.3 km², vegetation regrowth peaked in 2017 at 3.2 km², dead vegetation peaked in 2013 at 2.1 km², and visible extent of deposited sediment was greatest in 2015 at 0.44 km². We also examined 19 other retrogradational avulsions in Papua New Guinea and South America using NDVI. The area of floodplain disturbance (i.e., vegetation die-off and possible sedimentation) for each avulsion ranged from <1 to >13 km² and scaled with the dechannelization area. Comparing our plan-view disturbance results with FABDEM digital-elevation data and ICESat-2 surface elevation measurements, we hypothesize floodplain disturbance extent is a function of topographic relief. Our results also suggest that retrogradational avulsions, on average, perturb larger areas of forest compared to blowdowns, suggesting this might be an important disturbance regime that influences gap-filling regeneration in tropical rainforests.

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遥感土地覆盖物变化和热带雨林上游迁移河流崩塌后的洪泛区扰动

河流在其邻近洪泛平原上向一个新位置的位移被称为河道撕裂，在此，我们利用遥感技术研究了一种新认识到的河道撕裂方式，即逆行撕裂，是如何影响热带雨林周围的洪泛平原的。逆行崩塌始于河道堵塞，造成上游自蔓延的去河道化和洪水。虽然洪水会导致植被枯死和洪泛区沉积，但很少有对逆行崩塌造成的干扰进行定量测量的方法。在此，我们首先关注 2012 年至 2021 年巴布亚新几内亚发生的一次逆向崩塌后的土地覆盖物变化。在崩塌过程中，河流在上游 892 米处去渠化，母河道宽度增加了一倍。利用最大似然图像分类法，我们观察到健康植被的面积在 4.3 平方公里左右波动，植被重新生长在 2017 年达到顶峰，为 3.2 平方公里，死亡植被在 2013 年达到顶峰，为 2.1 平方公里，沉积泥沙的可见范围在 2015 年达到最大，为 0.44 平方公里。我们还使用 NDVI 对巴布亚新几内亚和南美洲的其他 19 处逆退崩塌进行了研究。每处崩塌的洪泛区扰动面积（即植被枯死和可能的沉积）从 1 平方公里到 13 平方公里不等，并与退渠区成比例。将我们的平面视图扰动结果与 FABDEM 数字高程数据和 ICESat-2 地表高程测量结果进行比较，我们假设洪泛区扰动范围是地形起伏的函数。我们的研究结果还表明，与崩塌相比，逆行崩塌平均扰动的森林面积更大，这表明这可能是影响热带雨林间隙填充再生的一种重要扰动机制。

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

River Research and Applications 环境科学-环境科学

CiteScore

4.60

自引率

9.10%

发文量

158

审稿时长

6 months

期刊介绍： River Research and Applications , previously published as Regulated Rivers: Research and Management (1987-2001), is an international journal dedicated to the promotion of basic and applied scientific research on rivers. The journal publishes original scientific and technical papers on biological, ecological, geomorphological, hydrological, engineering and geographical aspects related to rivers in both the developed and developing world. Papers showing how basic studies and new science can be of use in applied problems associated with river management, regulation and restoration are encouraged as is interdisciplinary research concerned directly or indirectly with river management problems.