First results of soil and water bioengineering interventions to stabilise and control erosion processes in hydroelectric power plant reservoirs in Brazil

IF 3.9 2区环境科学与生态学 Q1 ECOLOGY

Ecological Engineering Pub Date : 2024-11-23 DOI:10.1016/j.ecoleng.2024.107458

Rita dos Santos Sousa , Junior Joel Dewes , Hans Peter Rauch , Fabrício Jaques Sutili , Stephan Hörbinger

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引用次数: 0

Abstract

Reservoir banks are highly susceptible to erosion processes that result in a loss of stability. The main factors that cause erosion on reservoir banks are wave action and the oscillation of the water level. The aim of this study was to investigate four different soil and water bioengineering measures to stabilise and control erosion processes on the banks of reservoirs. The selection of plant species must follow various technical and ecological criteria. The study area is located at Itá hydropower plant. The development of the techniques and the used plants were monitored over a period of 28 months. Permanent plots were installed to assess plant development and erosion. When combined with support structures, the plants used were able to develop well. The average diameter and height of the plants increased in all sections. For the average plant height after 5 months, the best results were obtained in section A (1.32 m), and after 28 months the plants in sections C and B had an average height of 2.05 m and 2.01 m respectively. The greatest deposition occurred within the intervention zone, ranging from −6.4 cm/year (section A) to −0.6 cm/year (section D). For the pins 3/7, the largest soil deposition occurred in section B (−3.4 cm/year), while a soil loss (0.1 cm/year) was measured in section C. This confirms the positive technical effect of inert structures in combination with plants. The structures combined with vegetation, creates a barrier effect that protects the shore and enables the deposition/retention of sediments.

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为稳定和控制巴西水电站水库的侵蚀过程而采取的水土生物工程干预措施的初步成果

水库堤岸极易受到侵蚀过程的影响而失去稳定性。造成水库堤岸侵蚀的主要因素是波浪作用和水位摆动。本研究旨在调查四种不同的水土生物工程措施，以稳定和控制水库堤岸的侵蚀过程。植物物种的选择必须遵循各种技术和生态标准。研究区域位于伊塔水电站。在 28 个月的时间里，对技术的发展和使用的植物进行了监测。为评估植物的生长和侵蚀情况，设置了永久性地块。在与支撑结构相结合的情况下，所使用的植物生长良好。所有地块的植物平均直径和高度都有所增加。5 个月后，A 区的植株平均高度为 1.32 米，效果最好；28 个月后，C 区和 B 区的植株平均高度分别为 2.05 米和 2.01 米。最大的沉积发生在干预区内，范围从-6.4 厘米/年（A 区）到-0.6 厘米/年（D 区）。对于销钉 3/7，最大的土壤沉积发生在 B 区（-3.4 厘米/年），而在 C 区测量到的土壤流失（0.1 厘米/年）。惰性结构与植被相结合，产生了保护海岸的屏障效应，使沉积物得以沉积/滞留。

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

Ecological Engineering 环境科学-工程：环境

CiteScore

8.00

自引率

5.30%

发文量

293

审稿时长

57 days

期刊介绍： Ecological engineering has been defined as the design of ecosystems for the mutual benefit of humans and nature. The journal is meant for ecologists who, because of their research interests or occupation, are involved in designing, monitoring, or restoring ecosystems, and can serve as a bridge between ecologists and engineers. Specific topics covered in the journal include: habitat reconstruction; ecotechnology; synthetic ecology; bioengineering; restoration ecology; ecology conservation; ecosystem rehabilitation; stream and river restoration; reclamation ecology; non-renewable resource conservation. Descriptions of specific applications of ecological engineering are acceptable only when situated within context of adding novelty to current research and emphasizing ecosystem restoration. We do not accept purely descriptive reports on ecosystem structures (such as vegetation surveys), purely physical assessment of materials that can be used for ecological restoration, small-model studies carried out in the laboratory or greenhouse with artificial (waste)water or crop studies, or case studies on conventional wastewater treatment and eutrophication that do not offer an ecosystem restoration approach within the paper.