Scale‐Dependent Influence of Permafrost on Riverbank Erosion Rates

Rowland, J. C.; Schwenk, Jon; Shelef, Eitan; Muss, J. D.; Ahrens, Daniel; Stauffer, Sophie; Piliouras, Anastasia; Crosby, B. T.; Chadwick, A. J.; Douglas, Madison; Kemeny, Preston C.; Lamb, Michael P.; Li, Gen K.; Vulis, Lawrence

doi:10.1029/2023jf007101

Cited by 14 publications

(6 citation statements)

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“…Importantly, bank erosion rates in the buffered regime are sensitive to water temperature because warmer water temperatures cause the thawed layer to thicken and fail more rapidly, while entrainment‐limited banks are insensitive to water temperature. Therefore, our mathematical description of the buffered regime can reconcile theoretical predictions that permafrost bank thaw rates should exceed sediment entrainment rates for much of the summer with field observations of riverbanks with exposed or thinly covered permafrost in late summer (Fuchs et al., 2020; Kanevskiy et al., 2016) and remote sensing observations of slow migration for permafrost rivers (Rowland et al., 2019; Rowland, Crosby, et al., 2023; Rowland, Schwenk, et al., 2023).…”

Section: Discussionsupporting

confidence: 57%

“…Developing a 2D or 3D model requires considering the heterogeneities in bank ice distribution and their potential as failure planes (Barnhart et al., 2014; Kanevskiy et al., 2016), allowing for variable locations bank failure (Zhang et al., 2021; Zhao et al., 2021, 2022), and tracking the erosion of sediment following mass failure (e.g., Asahi et al., 2013; Parker et al., 2011). This includes constraining forces resulting from hydrologic connectivity between the river and its banks (Kurylyk et al., 2016; Zhao et al., 2020) as well as a more detailed investigation of interactions between riverbank pore water flow and heat transfer (Rowland, Crosby, et al., 2023; Rowland, Schwenk, et al., 2023). Extending our model to riverbanks that are exposed subaerially or experience periodic inundation will also require considering heat fluxes due to insolation and air temperature (Walker et al., 1987; Walvoord & Kurylyk, 2016).…”

Section: Discussionmentioning

confidence: 99%

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A Model for Thaw and Erosion of Permafrost Riverbanks

Douglas,

Lamb

2024

JGR Earth Surface

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How will bank erosion rates in Arctic rivers respond to a warming climate? Existing physical models predict that bank erosion rates should increase with water temperature as permafrost thaws more rapidly. However, the same theory predicts much faster erosion than is typically observed. We propose that these models are missing a key component: a layer of thawed sediment on the bank that buffers heat transfer and slows erosion. We developed a 1D model for this thawed layer, which reveals three regimes for permafrost riverbank erosion. Thaw‐limited erosion occurs in the absence of a thawed layer, such that rapid pore‐ice melting sets the pace of erosion, consistent with existing models. Entrainment‐limited erosion occurs when pore‐ice melting outpaces bank erosion, resulting in a thawed layer, and the relatively slow entrainment of sediment sets the pace of erosion similar to non‐permafrost rivers. Third, the intermediate regime occurs when the thawed layer goes through cycles of thickening and failure, leading to a transient thermal buffer that slows thaw rates. Distinguishing between these regimes is important because thaw‐limited erosion is highly sensitive to water temperature, whereas entrainment‐limited erosion is not. Interestingly, the buffered regime produces a thawed layer and relatively slow erosion rates like the entrainment‐limited regime, but erosion rates are temperature sensitive like the thaw‐limited regime. The results suggest the potential for accelerating erosion in a warming Arctic where bank erosion is presently thaw‐limited or buffered. Moreover, rivers can experience all regimes annually and transition between regimes with warming, altering their sensitivity to climate change.

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Section: Discussionsupporting

confidence: 57%

Section: Discussionmentioning

confidence: 99%

A Model for Thaw and Erosion of Permafrost Riverbanks

Douglas,

Lamb

2024

JGR Earth Surface

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“…Remarkably, the lowest displacement ( d ext and d tot < 0.3) was characteristic of most of the boreal belt, especially across northern North America, Europe, and the vast majority of Russia. Local inundation dynamics were well captured at the landscape level with an approximate concentric expansion and retraction dynamic, possibly explained by the temperature‐dominated (as opposed to precipitation‐dominated) timing of floods (Kireeva et al., 2020; Papa et al., 2008; Torre Zaffaroni, Baldi, et al., 2023), the glacial processes that have shaped the topography of these landscapes in the past (i.e., a currently inactive geomorphological agent), and the role of permafrost in channeling water (Blöschl et al., 2020; Buttle et al., 2016; Rowland et al., 2023). It is crucial to note that these regions, due to the observed and potential effects of climate change on permafrost stocks (Holgerson & Raymond, 2016; Schuur et al., 2015; Smith et al., 2022), may face increased rates of displacement and geomorphological alterations, putting at risk local and downstream communities and ecosystems (Lafrenière & Lamoureux, 2019).…”

Section: Resultsmentioning

confidence: 99%

Space‐Time Inconsistencies in the Dynamics of Water Coverage: Tracking Walking Floods

Torre Zaffaroni,

Houspanossian,

Di Bella

et al. 2023

Geophysical Research Letters

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Floods in ideal landscapes follow a coherent pattern where single water‐covered areas expand and afterward recede following the inverse sequence, but deviate in real landscapes due to natural or human factors resulting in water coverage shifts. Using remote sensing, we introduced two indices to describe the discrepancies between spatially integrated versus pixel‐level frequency distributions under maximum inundated conditions (dext) and throughout all flooding conditions (dtot), expressed as the relative weight of shifts on each landscape's maximum registered coverage, theoretically ranging between no displacement (<20%) to maximum displacement (≪inf). Globally, over 36 years inundations exhibited redistributions representing, on average, 25% and 45% of their peak extents revealing previously unnoticed extra engaged areas and rotational movements within events, rising up to 500% in meandering rivers (South America) and irrigated croplands (Central Asia). We also assessed the influence of natural and human variables and discussed the indices' potential for advancing flood research.

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“…The sensitivity of connectivity to water level indicates that predicted future changes to the northern Mackenzie River hydrologic cycle, such as increasing winter and spring streamflow at the expense of summer streamflow (Scheepers et al., 2018) and increasingly frequent and intense future precipitation events (Kuo et al., 2020), are cause for future monitoring. Additionally, permafrost thaw (Lantz & Kokelj, 2008) and resulting increased erosion rates (Rowland et al., 2023), and subsidence (Forbes et al., 2022) are predicted to influence the Mackenzie River Delta region going forward. Each of these projected changes may influence functional and structural lake‐to‐channel connectivity in different ways; with changes to streamflow resulting in higher and earlier springtime connectivity but decreased summertime connectivity, increased erosion leading to higher TSS and therefore higher functional connectivity, and increased subsidence leading to shifting lake sill elevations and functional connectivity elevation thresholds.…”

Section: Discussionmentioning

confidence: 99%

Remote Sensing of Multitemporal Functional Lake‐To‐Channel Connectivity and Implications for Water Movement Through the Mackenzie River Delta, Canada

Dolan,

Pavelsky,

Piliouras

2024

Water Resources Research

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The Mackenzie River Delta in Canada is a mediator of hydrological transport between the expansive Mackenzie River watershed and the Beaufort Sea. Within the delta, lakes frequently act as water and sediment traps, limiting or delaying the movement of material to the coastal ocean. The degree to which this filtering takes place depends on the ease with which sediment‐laden water is transported from distributary channels into deltaic lakes, referred to as functional lake‐to‐channel connectivity, which varies both spatially and temporally. Tracking of connectivity has previously been limited to either small regions of the delta or has focused on a snapshot of connectivity at a single instance in time. Here we describe an algorithm that uses Landsat imagery to track summertime functional lake‐to‐channel connectivity of 10,362 lakes between 1984 and 2022 on an image‐by‐image basis. We calculate a total average connected lake area of 1400.7 km2 during the 2 weeks after peak discharge, 763.6 km2 higher than previous estimates, suggesting a larger influence of connected lakes on water movement through the delta than previously estimated. We also identify water level thresholds that lead to the initiation of high sediment river water movement into 5,989 lakes (908 lakes with uncertainty ≤±0.5 m), and identify an additional 2899 lakes whose connectivity does not vary at all. As the Arctic hydrological cycle responds to climate change, this work lays a foundation for tracking the movement of water, and the matter it carries, from the Mackenzie River watershed to the Beaufort Sea.

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Scale‐Dependent Influence of Permafrost on Riverbank Erosion Rates

Cited by 14 publications

References 142 publications

A Model for Thaw and Erosion of Permafrost Riverbanks

A Model for Thaw and Erosion of Permafrost Riverbanks

Space‐Time Inconsistencies in the Dynamics of Water Coverage: Tracking Walking Floods

Remote Sensing of Multitemporal Functional Lake‐To‐Channel Connectivity and Implications for Water Movement Through the Mackenzie River Delta, Canada

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