Trade‐offs among road–stream crossing upgrade prioritizations based on connectivity restoration and erosion risk control

Lin, Hsien‐Yung; Robinson, Kelly; Walter, Lisa M.

doi:10.1002/rra.3593

Cited by 6 publications

(5 citation statements)

References 24 publications

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“…As one common way of transmitting runoff and sediment downstream of the road, the road drainage outlet will significantly increase the runoff and sediment content in the downhill direction [17,51]. As a result, the existence of the road not only affects the length of the confluence path, but also the confluence accumulation between the transport path and the stream, thereby changing the spatial distribution of the confluence accumulation in the catchment [26,28]. This phenomenon was further confirmed in this study.…”

Section: Convergence Processes Altered By Forest Roadssupporting

confidence: 76%

“…At the same time, the drainage networks will be extended to places previously not reached which will increase the possibility of runoff and sediment reaching the stream [23], ultimately increasing the sediment connectivity of the watershed [24,25]. In addition, a road-stream crossing affects the confluence characteristics by changing the natural properties of a stream network within a watershed [26], which has been shown to be the main way that sediment-loaded runoff is transferred from roads to streams through a direct path with the highest transmission efficiency [27,28].…”

Section: Introductionmentioning

confidence: 99%

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Response of Sediment Connectivity to Altered Convergence Processes Induced by Forest Roads in Mountainous Watershed

et al. 2022

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Forest roads significantly affect sediment connectivity in mountainous catchments by contributing to the production of and disturbing the confluence of sediment-loaded runoff. This study considered forest roads as pathways and sinks of sediment-loaded runoff to understand the effects of forest roads on the confluence characteristics and sediment connectivity in mountainous a catchment using a scenario simulation. In order to determine the contribution and spatial relationship between sediment connectivity and influencing factors, this study utilized buffer analysis, an extremely randomized tree model, and multiscale geographically weighted regression. The results show that the presence of forest roads significantly changes the transport process and connectivity of runoff and sediment in the mountainous catchment. Specifically, flow length increases, but flow accumulation, upslope contributing area, and topographic index decrease with increasing distance from roads and streams. Meanwhile, the effects of roads on convergence characteristics and sediment connectivity are mainly manifested within a certain threshold that varies with different confluence characteristics. Moreover, sediment connectivity increases when considering roads as pathways and sinks of sediment-loaded runoff, especially on the upper hillslopes intercepted by roads and at the road–stream crossings. In addition, the closer the distance to the roads, the greater the impact of road on the confluence characteristics and sediment connectivity. Change in flow length is the most important factor affecting the sediment connectivity among all of the other convergence, terrain, and spatial distance characteristics. The longer the flow length, the lower the sediment connectivity. In conclusion, this study demonstrates that the altered confluence processes by roads increases the possibility that sediment-loaded runoff will be transported to the catchment outlet, which is of significance for the proper management of forest roads in mountainous catchments.

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Section: Convergence Processes Altered By Forest Roadssupporting

confidence: 76%

Section: Introductionmentioning

confidence: 99%

Response of Sediment Connectivity to Altered Convergence Processes Induced by Forest Roads in Mountainous Watershed

et al. 2022

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“…These factors encompass the length, slope, and surface area of roads, vegetation coverage, and soil texture. Among these factors, the catchment area defines the upper and lower bounds of runoff and sediment yield in each erosion unit, while slope and length govern the variability within these bounds [53]. Generally, the larger the catchment area or the greater the road slope, the higher the eroded sediment yield.…”

Section: Factors Affecting Sediment Production Of Forest Road Erosionmentioning

confidence: 99%

A Review of the Sediment Production and Transport Processes of Forest Road Erosion

Yu,

Zhao,

et al. 2024

Forests

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Forest roads are a common land use feature with a significant impact on sediment yield and the water sediment transport processes within a watershed, seriously disrupting the safety and stability of the watershed. Previous studies have focused on the sediment production processes within the road prism. However, there has been limited attention given to the transport processes of road-eroded sediment at various scales, which is crucial for understanding the off-site effects of road erosion. This paper reviews research conducted on forest road erosion over the past two decades. It summarizes the mechanisms of sediment production from road erosion and provides a detailed analysis of the transport mechanisms of eroded sediments from roads to streams at the watershed scale. The paper also examines the ecological and hydrological effects, research methods, and control measures related to sediment transport caused by forest road erosion. It identifies current research limitations and outlines future research directions. The findings of this review highlight several key points: (1) Most research on forest road erosion tends to be specific and unilateral, often neglecting the broader interaction between roads and the watershed in terms of water–sediment dynamics. (2) Various research methods are employed in the study of forest road erosion, including field monitoring, artificial simulation experiments, and road erosion prediction models. Each method has its advantages and disadvantages, but the integration of emerging technologies like laser scanning and fingerprint recognition remains underutilized, hindering the simultaneous achievement of convenience and accuracy. (3) The transport processes of forest road-eroded sediment, particularly on road–stream slopes, are influenced by numerous factors, including terrain, soil, and vegetation. These processes exhibit significant spatial and temporal variability, and the precise quantification of sediment transport efficiency to the stream remains challenging due to a lack of long-term and stable investigation and monitoring methods. The establishment and operation of runoff plots and sedimentation basins may help offer a solution to this challenge. (4) Both biological and engineering measures have proven effective in reducing and limiting sediment erosion and transport. However, the costs and economic benefits associated with these regulation measures require further investigation. This review provides a comprehensive summary of relevant research on sediment erosion and transport processes on unpaved forest roads, enhancing our understanding of sediment yield in watersheds and offering valuable insights for reducing sediment production and transport to streams.

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“…The extent of “passability”—a term that commonly incorporates both the species and lifestages under consideration and the range of streamflows that allow their passage—is an important issue in frameworks for prioritizing passage projects (Kemp and O’Hanley 2010). Upstream movement by juvenile fishes has received considerable attention (e.g., Forty et al 2016) and many prioritization schemes simply use passability ranging from 0 to 1 as a multiplier in quantitative methods of prioritization (e.g., Lin et al 2020). However, alternative approaches seek to link degrees of passability to their population‐ and community‐level consequences (Kemp and O’Hanley 2010).…”

Section: Introductionmentioning

confidence: 99%

All Fish, All the Time: A Good General Objective for Fish Passage Projects?

Harvey

Railsback

2021

Fisheries

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Better understanding of the degree of “passability” needed to sustain robust sub‐populations upstream of barriers could help address and perhaps eliminate perceived trade‐offs between fish passage and other resource management goals. We used spatially explicit, individual‐based modeling to explore the population‐level consequences of various levels of upstream passability by (1) adult resident trout, and (2) juvenile salmon. In simulations of a stream network with widespread barriers, adult trout allowed to move upstream during only the highest 4% of streamflows sustained the distribution and abundance of the population to the same extent as in a no‐barrier scenario. In simulations of salmon production in a reach fully accessible to spawning adults, the number of barriers to upstream movement by juvenile salmon did not affect the production of large outmigrants. Passage objectives less ambitious than “all the fish, all the time” may sometimes suffice to maintain populations of resident trout and anadromous salmon.

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Trade‐offs among road–stream crossing upgrade prioritizations based on connectivity restoration and erosion risk control

Cited by 6 publications

References 24 publications

Response of Sediment Connectivity to Altered Convergence Processes Induced by Forest Roads in Mountainous Watershed

Response of Sediment Connectivity to Altered Convergence Processes Induced by Forest Roads in Mountainous Watershed

A Review of the Sediment Production and Transport Processes of Forest Road Erosion

All Fish, All the Time: A Good General Objective for Fish Passage Projects?

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